Next Article in Journal
Transition Metals in Freshwater Crustaceans, Tilapia, and Inland Water: Hazardous to the Population of the Small Island Province
Previous Article in Journal
Participant Experiences in a Human Biomonitoring Study: Follow-Up Interviews with Participants of the Flemish Environment and Health Study
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Toxics
Volume 9
Issue 4
10.3390/toxics9040070
toxics-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Transcriptional Analyses of Acute Exposure to Methylmercury on Erythrocytes of Loggerhead Sea Turtle

by
Javier Hernández-Fernández
1,2,*,
Andrés Pinzón-Velasco
3,
Ellie Anne López
4,
Pilar Rodríguez-Becerra
1 and
Leonardo Mariño-Ramírez
5
1
Department of Natural and Environmental Science, Marine Biology Program, Faculty of Science and Engineering, Genetics, Molecular Biology and Bioinformatic Research Group–GENBIMOL, Jorge Tadeo Lozano University, Cra. 4 No 22-61, Bogotá 110311, Colombia
2
Faculty of Sciences, Department of Biology, Pontificia Universidad Javeriana, Calle 45, Cra. 7, Bogotá 110231, Colombia
3
Bioinformática y Biología de Sistemas, Universidad Nacional de Colombia, Calle 45, Cra. 30, Bogotá 111321, Colombia
4
IDEASA Research Group-Environment and Sustainability, Institute of Environmental Studies and Services, Sergio Arboleda University, Bogotá 111711, Colombia
5
NCBI, NLM, NIH Computational Biology Branch, Building 38A, Room 6S614M 8600 Rockville Pike, MSC 6075, Bethesda, MD 20894-6075, USA
*
Author to whom correspondence should be addressed.
Toxics 2021, 9(4), 70; https://0-doi-org.brum.beds.ac.uk/10.3390/toxics9040070
Submission received: 13 January 2021 / Revised: 11 March 2021 / Accepted: 17 March 2021 / Published: 29 March 2021
(This article belongs to the Section Ecotoxicology)
Browse Figures
Versions Notes

Abstract

:
To understand changes in enzyme activity and gene expression as biomarkers of exposure to methylmercury, we exposed loggerhead turtle erythrocytes (RBCs) to concentrations of 0, 1, and 5 mg L−1 of MeHg and de novo transcriptome were assembled using RNA-seq. The analysis of differentially expressed genes (DEGs) indicated that 79 unique genes were dysregulated (39 upregulated and 44 downregulated genes). The results showed that MeHg altered gene expression patterns as a response to the cellular stress produced, reflected in cell cycle regulation, lysosomal activity, autophagy, calcium regulation, mitochondrial regulation, apoptosis, and regulation of transcription and translation. The analysis of DEGs showed a low response of the antioxidant machinery to MeHg, evidenced by the fact that genes of early response to oxidative stress were not dysregulated. The RBCs maintained a constitutive expression of proteins that represented a good part of the defense against reactive oxygen species (ROS) induced by MeHg.

Graphical Abstract

1. Introduction

Mercury (Hg) represents one of the most serious environmental threats to wildlife well-being [1,2]. It is among the most toxic and persistent pollutants released into marine ecosystems [3]. Furthermore, it represents a greater problem in aquatic systems, where inorganic Hg is transformed into organic Hg (methylmercury, MeHg), which is biomagnified in the trophic chain [1,2,4].
In the sea, MeHg is a molecule of great concern to marine populations as it bioaccumulates and biomagnifies in tissues, causing health damage [5]. MeHg makes up 75–99% of the total mercury (Hg-T) detected in living organisms [6], and is much more toxic than inorganic mercury [7].
MeHg is a weak electrophile with a strong affinity for sulfhydryl groups (-SH) and selenoles (-SeH), which are functional in proteins containing cysteines and selenocysteines respectively, with consequences such as (i) inactivation of molecules related to electrophilic forms, (ii) decrease in Se availability and, therefore, selenoprotein synthesis, and (iii) increase in intracellular MeHg concentration [8,9].
Exposure to MeHg has been extensively studied and is well documented in mammals, birds, and fish and includes neurotoxicity, impaired growth and development, reduced reproductive success, liver and kidney damage, and immunomodulation [2,10,11,12,13,14]. Among other changes associated with exposure to MeHg are gene expression levels linked to oxidative stress, microtubule disruption, mitochondrial dysfunction, endoplasmic reticulum stress, disruption of intracellular calcium levels, programmed cell death, dysregulation of transcription and translation, expression of heat shock proteins, and production of reactive oxygen species (ROS) [2,14,15,16,17]. However, the effects on reptiles remain poorly understood [7,18,19,20,21]. Studying these early stages of mercury damage is the basis for identifying metabolic pathways that are activated in response to mercury contamination.
Advances in next-generation sequencing technologies, such as massive RNA sequencing (RNA-seq), allow for the characterization of molecular responses to stimuli with impressive sensitivity for non-model organisms, such as the loggerhead turtle [22,23,24]. The comparison of genes that are differentially expressed in erythrocytes (RBCs) exposed to a xenobiotic, such as methylmercury, allows for the identification of biomarkers for stress and adaptive response [25]. It is very important to perform differential expression analysis at very low levels of MeHg to identify possible “expression signatures”. These expression signatures could be used as early markers of exposure to MeHg, before detecting physiological or biochemical changes (Oliveira et al., 2020). Exposure of RBCs to low doses of MeHg (1–5 ppm) for a short time (a few hours) provides the opportunity to detect a possible compensatory hormonal mechanism, which can be interpreted as molecular responses that result in cellular protection [26].
Studies carried out on the toxicity of MeHg in wild animals and humans using next-generation sequencing (RNA-seq) have generated knowledge about the molecular mechanisms of this compound produced in different tissues [26,27,28,29,30,31]. The cellular and molecular mechanisms that produce MeHg-mediated toxicity are not yet fully understood, and there are species for which very little is known (i.e., sea turtles) [4]. However, these types of studies have not been performed in loggerhead turtles. These reptiles are long-lived and carry out extensive migrations, characteristics that allow them to accumulate Hg for a long time. For these reasons, they are sentinel species: bioindicators of pollution in the marine environment [32]. These marine chelonians are in population decline due to anthropic and environmental influences, appearing on the red list of threatened species of the International Union for Conservation of Nature (IUCN, 2019-2) as critically endangered (www.iucnredlist.org, accessed on 13 January 2021). For this reason, it is important to propose alternative study methodologies that do not compromise the life of these animals that are instrumental for the health of marine ecosystems [32]. Recently, cell cultures of different tissues of sea turtles have been established to allow research in toxicology [33]. These cells are being used in in vitro tests, producing a frame of reference on the initial response, with the effects of different xenobiotics evaluated [33,34,35,36,37]. The nucleated RBCs of sea turtles represent a model for in vivo ecotoxicology research to reveal the effects of Hg and other heavy metals and environmental pollutants [32].
In previous studies, we demonstrated that an increase in the enzymatic activity of Glutathione S transferase and superoxide dismutase, as well as the production of malonaldehyde, was revealed when loggerhead turtle RBCs were exposed to 0, 1, and 5 mg L−1 of MeHg for 12 h. The observed response shows the increase in reactive oxygen species in RBCs [32]. In this study, we set out to perform an analysis of the global transcriptional profiles in RBCs of the loggerhead turtle, Caretta caretta, to identify cellular pathways or biological processes affected by MeHg while preliminarily elucidating the molecular mechanisms of toxicity used by this xenobiotic against this marine turtle.

2. Materials and Methods

2.1. Permits to Collect Samples

The samples and methods used in this study followed the ethical standards of Colombian legislation and those of the ethics committee of the Jorge Tadeo Lozano University (UJTL) (Project 340-07-10). The project had a permit to collect samples of Colombian biodiversity, granted to the UJTL by the Ministry of the Environment (Resolution 1271 of 23 October 2014, IDB040I).

2.2. Study Area and Sample Collection

Peripheral blood was collected from five captive, pre-juvenile loggerhead turtles at the El Rodadero Aquarium in Santa Marta (11°1301.09″ N, 74°14013.75″ W). The details of blood sample collection and RBC isolation have been described previously [32]. In brief, blood samples were extracted from the dorsal region of the cervical sinus. For the collection of peripheral blood, we used 4 mL sterile syringes and 2 mL tubes with RNAlater (Ambion Inc., Austin, TX, USA). The samples were transported on dry ice to the Molecular Biology laboratory at the Jorge Tadeo Lozano University, Bogotá.

2.3. Experimental Design

Aliquots of 2 × 106 RBCs/ml from five peripheral blood samples were isolated by centrifugation and then resuspended in 1.5 mL Eppendorf tubes in MEM-S medium [32]. We exposed the RBCs to doses of 0, 1, and 5 mg L−1 of methylmercury II chloride (CH3HgCl) (Merck KGaA, Darmstadt, Germany) for 12 h at 30 °C. Each of the five samples was exposed to the three concentrations of CH3HgCl (MeHg), thus producing 15 samples altogether. As a control, we used RBCs in a culture medium with sterile saline solution (used to dilute the MeHgCl) (Figure 1).

2.4. RNA Extraction, Library Construction and Sequencing

At 12 h of incubation, the RBCs exposed to MeHg were washed twice with 0.9% sterile saline solution (Baxter Healthcare Corporation, Deerfield, IL, USA), then centrifuged at 2500 rpm at 22 °C, resuspended in 15 volumes of RNAlater® (Ambion, Inc., Austin, TX, USA), and stored at 4 °C for one week.
Before extraction, the RNAlater was removed and the RBCs were washed with 1 volume of 0.9% sterile saline solution (4 °C), then centrifuged at 5000× g for 10 min at 22 °C. We extracted total RNA from each of the samples (~25 µL RBCs/mL) using RNeasy® Mini Extraction Kit, following the instructions of the manufacturer (Quiagen, Hilden, Germany). The extracted RNAs were treated with DNase according to the instructions of the manufacturer (RNase-Free DNase Set, Cat No / ID: 79254) (Quiagen, Hiden, Germany) and diluted in RNAsa-free MilliQ water. RNA was stored at −80 °C for subsequent evaluations.
The RNA was quantified and its quality analyzed by spectrophotometry, using a Nanodrop-1000 (Thermo Scientific, Wilmington, DE, USA). The RNA was evaluated by electrophoresis in 1% agarose gels (100 V, 30 min). Each of the total RNA preparations was individually assessed for RNA quality based on the 28S/18S ratio and the RNA integrity number (RIN) was measured by 4200 TapeStation capillary electrophoreses (Agilent Technologies, Waldbronn, Germany) at the Research Center of the Colombian Agricultural Research Corporation in Tibaitatá, Cundinamarca (Agrosavia, Bogotá, Colombia). Samples with RIN > 8.5 were selected for further analysis (Figure S1). The Beijing Genomics Institute (BGI, Shenzhen, China) carried out the fragmentation of mRNA, cDNA libraries construction, and sequencing using the BGISEQ-500 platform, following the previously published methodology [38].

2.5. Assembly of the Transcriptome

We evaluated the raw sequencing data using the FastQC tool [39]. Then, the adapters and the low-quality reads were filtered with Trimomatic [40]. We used the Trinity pipeline v2.0.6 to assemble each of the individual samples, the three experimental groups (0 = control; 1 mg L−1 = Gs1 and 5 mg L−1 = Gs5), and the union of all samples, using default parameters [41]. We evaluated the assembled transcripts for their integrity and quality with the Dogma v-3.4 program (Domain-Based General Measure for Transcriptome and Proteome Quality Assessment) [42], comparing them to the conserved protein domains and domain arrangements of eukaryotes and vertebrates.

2.6. Unigenes Prediction and Functional Annotation

We grouped the obtained transcripts in pairs according to the similarity of the sequences to produce longer and more complete consensus sequences using the TGICL v2.0.6 program (a software system for fast clustering of large EST datasets) [43]. The resulting sequences (unigenes) were classified into two groups: clusters (CL, transcript groups with a similarity higher than 70%), and singletons. Clusters and singletons were annotated with BlastN and BlastX v2.2.23 against the Nt, Nr, KOG, and KEGG databases with default parameters, except for the E-value (modified to 1e−5) [44]. Later, the unigenes were annotated to the GO database using SwissProt and the Blast2GO v2.5.0 program with default parameters [45]. We used WEGO software v2.0 [46] to determine the GO functional classifications and evaluate the distribution of functions of unigenes. Lastly, we used InterProScan5 v5.11-51.0 with default parameters to predict protein families, domains, and functional sites [47]. Unigenes were also used to predict the coding regions (CDS) and open reading frames (ORFs) using the Transdecoder v3.0.1 program with default parameters [48].

2.7. Identification and Annotation of Differentially Expressed Genes

We mapped the clean reads to the unigenes obtained previously using Bowtie2 v2.2.5 [49] and calculated the expression level of each of the genes using RSEM v1.2.12 [50]. The expression levels of the unigenes were measured in fragments per kilobase of exon per million reads mapped (FPKM), which normalizes the paired transcript and reads counts both for their length and for the total number of reads mapped in the sample [51]. We identified differentially expressed genes using the DEseq2 program [52] (significant DEGs: log2 fold change ≥ 1 or log2 fold change ≤ −1, and Adjusted p value ≤ 0.05), which normalizes the data taking into account the differences in the total number of reads per library. Further, we used PossionDis (significant DEGs: fold change ≥ 1 or fold change ≤ −1, a FDR ≤ 0.001).
The DEGs were identified by comparing the control group (Gc) with each of the groups exposed to MeHg (Gs1 and Gs5), and comparing the two exposed groups with each other (Gs1 versus Gs5). Subsequently, the distribution of the expressed genes was graphed using heat maps and MA plots with the heatmap and ggmaplot (DEseq2) functions, respectively. In the heat maps, we divided the expression levels of the DEGs into orange and blue regions that indicated high and low levels of relative expression, respectively. We compared the set of differentially expressed genes shared between the different treatments with Venn diagrams using the Venny 2.0 program [53].
Differentially expressed genes were mapped to GO terms and the KEGG database to perform functional enrichment and metabolic pathway analyses, respectively. We then calculated the false discovery rate for each p-value. Terms whose FDR was less than 0.01 were defined as having significant enrichment.

2.8. Statistical Analysis of the Correlation between the Relative Expression (FPKM) of the Genes GST, Cu/Zinc-SOD, Mn-SOD, and Tbxas1 with the Enzymatic Activity of GST and SOD, and the Amount of MDA (µM) Produced by Lipid Peroxidation

In a previous experiment, we used the same RBC samples [32] as in this study to determine the activities of the Cu/Zinc-SOD, Mn-SOD, GST enzymes, and the amount of MDA produced. To verify the correlation between the relative expression (FPKM) of the GST, Cu/Zinc-SOD, Mn-SOD, and Tbxas1 genes and the enzymatic activities [32], we used Pearson’s multiple correlation analysis using the StatR v.1.8 statistical packages designed for Rwizard v.4.3 [54] The mapped read count measures the relative expression level of the genes and statistical methods are then applied to test the significance of the differences between groups [55]. This approach of using FPKM as a measure of relative expression has been used previously [29,56,57,58].
As dependent variables in each of the analyses, the following were selected: GST activity, Cu/Zinc-SOD activity, Mn-SOD, and MDA concentration (µM), respectively. As independent variables, the following were selected: relative expression (GST, SOD/Cu/Zinc, Mn-SOD, and Tbxas1 (FPKM)), the initial total concentration of MeHg, and concentration of MeHg added to each individual. The Tbxas1 gene was correlated with the concentration of MDA because this gene participates in the isomerization of the PGH2 prostaglandin, transforming it into 12-hydroxy-5, 8, 10-heptatrienic acid (12-HHT), and malondialdehyde (MDA).

2.9. Data Availability

All data are available at NCBI under project accession number PRJNA575050. The raw sequences data of RNA-seq in FASTQ format were deposited at the NCBI in the Sequence Read Archive Database (SRA) under the accession numbers: SRR10412101, SRR10412100, SRR10412099, SRR10412098, SRR10412097, SRR10412096, SRR10412095, SRR10412094, SRR10412093, SRR10412092, SRR1041209, and SRR10412090.

3. Results

3.1. Sequencing, Filtering of Readings, and Assembly

The sequences of the 12 libraries presented high quality according to the FASTQC analysis (three samples, T13, T14, and T15 were removed as they presented a RIN less than 7,5). However, sequencing reads containing adapter contamination, and unknown bases (N), were removed (they represented 1.8% of the total readings) (Table S1). We assembled all individual transcripts (T1 to T12). Then, we assembled the transcriptomes of Gc (T1, T4, T7, and T10), Gs1 (T2, T5, T8, and T11), and Gs5 (T3, T6, T9, and T12). Lastly, we assembled the composite transcriptome, which included the readings of all 12 individuals. The metrics for each of the assemblies are presented in Table 1.
The de novo assembly of the twelve individuals produced a composite transcriptome with 121,933 unigenes, with an average length of 1444 bp, N50 of 3520, and a GC percentage of 46.98% (Table 2). The size of the unigenes ranged between 300 and 3000 bp (Figure S2). The 12 samples had on average 72.2% of their transcripts matching with the composite transcriptome, while the partial transcriptomes of Gc, Gs1, and Gs5 showed 99.8% of transcripts matching with the composite transcriptome (Table 1). We used the DOGMA web server to evaluate the level of integrity of the transcriptome. We identified 76.6% and 96.8% of the central assemblages of vertebrates and eukaryotes, respectively. These results support the high quality and integrity of our composite loggerhead transcriptome. Furthermore, these results are in agreement with those published in previous studies [59,60,61].

3.2. Functional Annotation

We generated unigenes for each of the assembled transcriptomes. The composite transcriptome annotation produced 72,700 (59.62%) unigenes with significant agreement against at least one of the analyzed databases (Table 2). A total of 11,693 (9.6%) and 32,467 (44.8%) unigenes were annotated to 7 and 5 databases respectively (Table 2, Figure 2). Our composite transcriptome was also scored against Testudines proteomes (Chelonia mydas, Pelodiscus sinensis, and Chrysemys picta belli), and against a previously published Caretta caretta transcriptome (Genbank PRJNA560561), obtaining significant agreement against 97,546 proteins (80.5%) and 110,846 unigenes (90.9%), respectively.

3.3. Differential Gene Expression

To evaluate the expression characteristics of the mRNA, we estimated the relative expression levels (FPKM) of each of the samples for each transcript (Figure 3). We classified the expression of genes into three categories: (i) genes that presented low relative expression levels (FPKM < 1), which represented the majority of genes (72%); (ii) genes that presented medium relative expression levels (FPKM between 1–10), which represented a quarter of the genes (24%); and (iii) genes that presented high levels of relative expression (FPKM > 10), which represented a minority of the genes (4%).
On average, each of the 12 samples expressed 80,453 genes. No significant differences were found between the number of genes expressed between Gc, Gs1, and Gs5 (Kruskal–Wallis, p > 0.05). It is important to note that when Gs1 was compared to Gs5, it showed a marked reduction in gene expression (5274, 3352, and 348 fewer genes respectively expressed in categories i, ii, and iii described above) in all three categories (Figure 3). On the contrary, when Gc was compared with Gs5, it presented smaller differences in the expression of genes in the first two categories (2287 and 118 fewer genes than Gs5, respectively), and in the third category, Gc expressed more genes than Gs5 (33 genes) (Figure 3). The results appear to show that low concentrations of MeHg (1 mg L−1) generally decrease gene expression while higher concentrations increase it (5 mg L−1).
The evaluation of dysregulation caused by MeHg to the RBCs showed that 83 genes produced significant differential gene expression (log2 fold change ≥ 1, or log2 fold chance ≤ −1, Padj ≤ 0.05 and FDR ≤ 0.001) between the Gc–Gs1, Gc–Gs5, and Gs1–Gs5 treatments. The group of upregulated genes under MeHg stress produced 39 matches and the downregulated genes produced 44 matches. These differentially expressed genes were annotated to the databases as follows: Nt (79 genes, 95.2%), Nr (80 genes, 96.3%), SwissProt (78 genes, 94%), KEGG (74 genes, 89.1%), KOG (69 genes, 83.1%), InterPro (73 genes, 87.9%) and GO (27 genes, 32.5%). In summary, only 80 genes produced significant matches and were annotated to at least one database. The other three genes had no matches and could not be annotated (NC). Of the 83 dysregulated genes, four genes were in more than one comparison. This means we identified a total of 79 unique DEGs (Figure 4 and Figure 5).
When the gene expression of the Gc and Gs1 treatments were compared, we found 16 upregulated genes (between 1 and 7 fold) and 24 downregulated genes (between −1.7 and −5 fold) (Figure 4A,B) (Table S2). The comparison between the Gs1 and Gs5 treatments showed 15 upregulated genes (a fold change between one and more than five) and 15 downregulated genes (a fold change between −1.7 and more than −6) (Figure 4C,D) (Table S3). Lastly, between Gc and Gs5 we found eight upregulated (between 1 and 5 fold) and five downregulated (between −3 and −5 fold) genes (Figure 4E,F; Figure S3A–C, Table S4).
We found that none of the upregulated and downregulated genes were common to all three established relationships (Figure 5). Of the 39 upregulated genes, 1 gene was common between the Gc–Gs5 and Gs1–Gs5 comparisons. A total of 16, 14, and 7 genes were unique in the Gc–Gs1, Gs1–Gs5, and Gc–Gs5 comparisons, respectively (Figure 5). Of the 44 downregulated genes, two genes were common: one between the Gc–Gs1 and Gc–Gs5 comparisons, and one between the Gs1–Gs5 and Gc–Gs5 comparisons. A total of 23, 14, and 3 unigenes were unique among the comparisons Gc–Gs1, Gs1–Gs5 and Gc–Gs5, respectively (Figure 5).

3.4. Functional Enrichment Analysis with GO Terms of Differentially Expressed Genes

The enrichment of GO terms of DEGs was carried out to identify the related biological processes and the functions affected by MeHg in the RBCs. The GOs were assigned to the three gene ontologies: biological processes, cellular components, and molecular function. Of the 79 DEGs, only 27 were annotated against the GO database (11 upregulated genes and 16 downregulated genes). When Gc was compared with Gs1, 113 unigenes were classified into 28 GO functional group categories (14 in biological processes, 10 in cellular components, and 4 in molecular function). When comparing Gs1 with Gs5, 103 unigenes were classified into 27 GO functional group categories (13 in biological processes, 10 in cellular components and 4 in molecular function), and finally, when comparing Gc with Gs5, 17 unigenes were classified into 17 GO functional group categories (eight in biological processes, six in cellular components and three in molecular function) (Figure 6).
To acquire an understanding of what may be happening at the cellular level between Gc, Gs1, and Gs5, the annotation was completed manually using the Uniprot and Gene Ontology databases. The differentially expressed unigenes in the three comparisons were classified according to molecular function in the following categories: oxidative stress, regulation of the cell cycle, signaling, regulation of transcription and translation, binding to metal ions, autophagy, apoptotic processes, metabolic processes, membrane transport, DNA repair, mitochondria, and miscellaneous. The results of the top 25 annotations are presented in Table 3 (all annotation results are presented in Table S5).
The DEGs between Gc and Gs1 presented 40 dysregulated unigenes which were grouped into 11 GO categories according to their function. The most representative categories were: regulation of transcription (two upregulated and ten downregulated genes), signaling (one upregulated and seven downregulated genes), oxidative stress (three upregulated and three downregulated genes), metabolic processes (three upregulated and two downregulated genes), and binding to metal ions (four upregulated genes) (Table S2). The DEGs between Gs1 and Gs5 presented 30 dysregulated unigenes which were grouped into 11 GO categories according to their function. The most representative categories were: regulation of transcription (three upregulated and four downregulated genes), signaling (three upregulated and three downregulated genes), oxidative stress (three upregulated and one downregulated gene(s)), transmembrane transport activity (two upregulated and two downregulated genes), and binding to metal ions (three upregulated genes) (Table S3). The DEGs between Gc and Gs5 presented 13 dysregulated unigenes, which were grouped into six GO categories according to their function. The two most representative categories were: regulation of transcription (three upregulated genes) and binding to metal ions (three downregulated genes) (Table S4).

3.5. Analysis of Functional Enrichment of KEGG Pathways of Differentially Expressed Genes

The enrichment analysis of KEGG pathways carried out on differentially expressed genes showed that, when comparing Gc to Gs1 (Figure 7A), Gs1 to Gs5 (Figure 7B), and Gc to Gs5 (Figure 7C), the genes were associated with 20, 17, and 16 pathways, respectively. In the comparison between Gc–Gs1 and Gs1–Gs5, we found that the pathways with the highest enrichment were the lysosome (four genes) and the Jak-STAT (three genes) pathways, pathways that participate in the regulation of the response to oxidative stress mediated by MeHg [62,63]. In the comparison between Gc–Gs1, Gs1–Gs5, and Gc–Gs5, genes that participate in sphingolipid metabolism, autophagy, apoptosis, the HIF signaling pathway, mTOR, and PI3K-Akt were also enriched, which have been reported to be upregulated or downregulated by MeHg [64,65,66,67] (Figure 7).

3.6. Correlation between the Relative Expression (FPKM) of the GST, SOD, and Tbxas1 Genes (RNA-seq Data) with the Enzymatic Activity of GST, SOD, and the Amount of MDA (μM) Produced

We found, based on the multiple correlation analyses carried out on the Cu/Zinc-SOD, Mn-SOD, and GST activities and the concentration of MDA, that in the three cases the activity of these enzymes (SOD and GST) and the concentration of MDA were directly correlated with the relative expression of the Cu/Zinc-SOD, Mn-SOD, GST, and Tbxas1 genes (R = 0.92, 0.75, 0.94 and 0.89, respectively) (p < 0.001) (Figure 8A–D). Additionally, we observed that the activity of the Mn-SOD enzyme and its relative expression were correlated with the concentration of added MeHg, R = 0.75 (p = 0.005) and R = 0.67 (p = 0.016), respectively (Figure S4A–D).

4. Discussion

The results of our study provide information on the differential expression of genes in loggerhead sea turtle RBCs exposed to MeHg. It should be noted that the information available on non-model organisms is scarce and, therefore, requires development. We highlight that only 59% of the unigenes were annotated in at least one of the seven databases used, and of the 79 unique DEGs identified, only 27 were annotated against GO. This result shows the knowledge gap on the subject. Furthermore, several genes that were matched against databases were genes with unknown functions, and few studies have been conducted using transcriptomics to evaluate gene dysregulation caused by MeHg. Clearly, the lack of functional annotation of transcriptomes from non-model organisms is limiting the development of the mechanistic understanding of complex traits [67]. However, the proteomes of three turtles (Chelonia mydas, Pelodiscus sinensis, and Chrysemys Picta belli) have already been published, and there are 37 turtle genomes in the process of assembly, 10 of which also have been published, representing important progress for the understanding of these chelonians.
For these reasons, our study represents an important advance of DEGs analysis in the understanding of the toxicity mechanisms by which MeHg affects cellular homeostasis and of the adaptive response of loggerhead sea turtle RBCs. Adaptive responses to MeHg toxicity appear to involve complex polygenic processes. Our findings were consistent with this and reveal that several functionally distinct genes were dysregulated in response to stress produced by MeHg.
In the comparisons made to determine the differential expression of genes between Gc–Gs1, Gs1–Gs5, and Gc–Gs5, the greatest dysregulation occurred in downregulated genes (44 genes) related to the response to cellular stress, signaling, transcription, calcium metabolism, and transport across the membrane, and in upregulated genes (39 genes) involved in the response to stress, lysosomes, mitochondria, regulation of the cell cycle, metabolic processes, and transcription and translation (Table S5).
These results demonstrate that RBCs in Gs1 generally expressed fewer genes, but their response to MeHg was more pronounced (40 dysregulated genes) than RBCs in Gs5 (12 dysregulated genes). The identification of changes in gene transcription can contribute to the identification of molecular events that are in the process of initiation or to the identification of the sequence of molecular events that can lead to cellular dysfunctions, as well as the identification of toxicity markers [29,68]. Studies are needed at lower and higher MeHg concentrations and longer and shorter exposure times.

4.1. Differential Expression of Oxidative Stress Indicator Genes

Oxidative stress produced by an increase in reactive oxygen species is one of the earliest responses of RBCs to MeHg toxicity [32]. In this study, when comparing the DEGs between Gc–Gs1, Gs1–Gs5, and Gc–Gs5, the dysregulation of 12 oxidative stress indicator genes was observed: eight upregulated genes (Sgk1, GDP1, HEX_A, ATG5, MKNK1, ZDHHC16, CEP250, and ITGAX) and four downregulated genes (BRD1, DCUN1D2, KPNA6, and SAMD9) (Table 3). These 12 DEGs demonstrate oxidative stress.
The Sgk1 and MkNk1 (Table 3) genes were upregulated. The proteins that these genes encode are linked to various cellular processes, including survival and the response to cellular stress. These proteins carry signals from the cell membrane to the nucleus and are activated in response to environmental, osmotic, or oxidative stress and DNA damage [69]. Everything indicates that these genes in the RBCs are upregulated as a response to stress produced by MeHg to counteract or minimize the toxicity. Overexpression of the Sgk1 gene has been reported to regulate nitric oxide production, protect cells against ROS, and inhibit apoptosis [70]. Although the expression of Sgk1 was not high, its presence denotes the appearance of ROS and, apparently, cellular damage. The significant overexpression of the Atg5 gene supports our hypothesis, as this gene exerts a cytoprotective role in various animal species, making the autophagy process more efficient and reducing oxidative stress during exposure to MeHg [71].
In this study, we found that the expression of Atg5 shows that there is cellular damage in RBCs and its overexpression produces compensation. In mice, the silencing of Atg5 in cells exposed to acute oxidative stress has produced the overexpression of cytokines, which generate inflammation and cellular apoptosis [72]. These findings support the important role this gene plays in RBCs homeostasis. To counteract oxidative stress, the overexpression of other anti-apoptotic genes has been identified, such as Sgk1 and ZDHHC16 (Table 3). The ZDHHC16 gene responds to the stress generated by DNA damage and participates in palmitoylation, a post-translational modification of histone proteins in which the ZDHHC16 enzyme adds a palmitate moiety to specific cysteine residues in RBCs. Palmitoylation affects chromatin remodeling, the structure of DNA, and eventually triggers the activation of regulatory genes that contribute to DNA repair and, therefore, prevent its apoptosis [73,74].
Likewise, we identified the overexpression of the GPD1 gene. The enzyme encoded by this gene reduces dihydroxy-acetone phosphate to glycerol-3-phosphate (G-3-P), reducing in turn one mole of NAD to NADH [75]. Shen et al. [75] described how GDP1 deficiency, under stress conditions, produces the loss of the ability to achieve NADH/NAD balance and, therefore, a constitutively increased level of ROS. However, it is known that GPD1 is involved in a mitochondrial redox shuttle, which serves as a link between the cytosol and the mitochondria, and that a balanced cellular redox state is obtained due to this gene [76]. The overexpression of the GPD1 gene in RBCs is caused by high external osmolarity (MeHg solute), which causes increased synthesis and intracellular accumulation of glycerol [77]. The GPD1 enzyme translocates G-3-P to the inner mitochondrial membrane, which serves as a redox valve to eliminate excess reducing power. In this way, a high NADH/NAD balance remains [76,78]. This response is fundamental for the cell, not only for the control of the redox balance of metabolism, but also, and very importantly, for the preventive management of oxidative stress [75].
Another downregulated gene in the RBCs that is also related to oxidative stress is KPNA6, which is a transport adapter between the nucleus and the cytoplasm and is related to the regulation of cytokine production involved in the inflammatory response to stress [79]. Dysregulation of the KPNA6 gene has been reported to be closely related to nuclear erythroid factor 2 (Nrf2), a skillful regulator of cellular redox homeostasis that regulates the expression of more than 200 genes involved in antioxidant defense [80,81] and, with the Keap1 signaling pathway, promotes the transcription of a large number of genes encoding antioxidant enzymes, detoxification, and xenobiotic transporters as an adaptive response to oxidative stress [79,80].
Nrf2 activation is negatively regulated by Keap1, which exports the Nrf2 transcription factor from the nucleus to the cytoplasm [79,82]. The upregulation of KPNA6 generates the nuclear entry of Keap1 and this neutralizes the signaling of Nrf2 transcription, while the downregulation of the KPNA6 gene decreases the entry of Keap1 to the nucleus and, in this way, Nrf2 triggers adaptive transcription of genes that control oxidative stress [79,83]. We found that the KPNA6 gene is downregulated in loggerhead turtle RBCs and, therefore, Nrf2 activates the expression of the antioxidant enzymes of the cascade of the antioxidant response element (ARE) [83]. This was observed when analyzing the relative expression of the genes (in FPKM). The transcription factor Nrf2 presented a basal expression in all three treatments (FPKM: Gc = 19.7, Gs1 = 18.2, and Gs5 = 17.6). These findings support the idea that KPNA6-mediated nuclear import of Keap1 plays an essential role in modulating the Nrf2/Keap1 pathway and maintaining cellular redox homeostasis [83].
The antioxidant defense systems are essential to neutralize high levels of ROS, which can cause irreversible damage to cells. In this way, cells have antioxidant molecules and detoxifying enzymes that can control free radicals. GSH is the most abundant antioxidant small molecule. Detoxifying enzymes include SOD, GPx, glutathione-S-transferases (GSTs), CAT, glutathione reductase, glutamate-cysteine ligase (GCL), NAD (P) H: quinone oxidoreductase (NQO1), heme oxygenase-1 (HO-1), and other phase II detoxifying enzymes [2,13]. These molecules were not dysregulated, as they did not change in their expression levels. However, the relative expression levels (FPKM) of these genes were much lower than those presented by the HSP70 and ferritin genes (Gc: 10,421 and 5221, Gs1: 10,513 and 5151, and Gs5: 8047 and 5281, respectively).
Heat shock proteins serve many functions as molecular chaperones and folding guide proteins and by preventing protein build-up. During events such as oxidative stress, the expression of heat shock proteins is known to increase considerably [84]. In general, heat shock proteins are activated to stimulate a pro-survival response during oxidative damage [85]. For its part, ferritin acts as a cytoprotective agent that inhibits oxidant-mediated cytolysis in direct relation to its intracellular concentration [86,87]. This idea is crucial to understanding the loggerheads’ response, as we will discuss later.

4.2. Lysosomes and Regulation of Autophagy

Low concentrations of MeHg induce autophagy [88], which is mainly due to the association of Atg5 and p53 [89]. In addition to the dysregulation of Atg5 that was already discussed above, in the lysosome and autophagy pathway we found five dysregulated genes: HEX_A, MANB, AP-4, GALNS, and SLC38A9 (Table 3).
We identified the following upregulated genes: HEX_A, which catalyzes the degradation of GM2 gangliosides to GM3 gangliosides in lysosomes [90], molecules which are found in the plasma membrane [91]; MANB, a glycosyl hydrolase that degrades polysaccharides [92]; GALNS, another lysosomal hydrolase that degrades proteins such as glycosaminoglycans, keratan sulfate, and chondroitin-6-sulfate [93]; and AP4B1, which is involved in the generation of vesicles and, in the charge selection, controls the vesicular transport of proteins in different traffic pathways and contributes to the spatial control of autophagy [94]. Apparently, the erythrocyte membrane generates lipids and carbohydrates as a result of ROS-triggered events, such as lipid peroxidation. The dysregulation of the HEX_A and MANB genes could be present in the RBCs, as these two hydrolases execute their task of recycling these molecules through the lysosomal pathway. For their part, the GALNS and AP4B1 genes are downregulated in RBCs and are not part of the response against oxidative stress generated by MeHg.
We found that the SLC38A9 gene, which plays a role as an amino acid sensor upstream of mTORC1 for asparagine, arginine, glutamine, histidine, and lysine, was downregulated [95]. SLC38A9 regulates the activity of mTORC1, an integrator of environmental and hormonal signals, detecting the availability of amino acids, glucose, and cholesterol to initiate growth. Nonetheless, its action mechanism is not clear [95]. Interestingly, SLC38A9 allows the activation of mTORC1 by cholesterol through the recruitment of the NPC1 protein, which is an inhibitor of mTORC1 in cholesterol deficiency [96]. When SLC38A9 fails to activate mTORC1, the anabolic metabolism is suppressed and autophagy is activated [96].
It is clear that the RBCs in the culture medium in which the bioassay was carried out did not have the necessary environmental and hormonal signals for growth. Thus, the activity of the SLC38A9 gene was decreased and its signaling mechanism remained inactive; therefore, RBCs did not reproduce, nor did mTORC1 activation occur [97]. It is important to understand how the SLC38A9 protein identifies and transports amino acids, how it activates or deactivates mTORC1, and how it detects other environmental signals. This topic represents an important area for future research.

4.3. Cytoskeletal Stability and Cell Cycle

The cytoskeleton is involved in cell movement and division and is one of the primary targets of MeHg inside the cell. Specifically, it fragments microtubules, disrupting networks that are necessary to perform important biological functions [98]. Vogel et al. [98] assembled in vitro microtubules from the bovine brain and used raw microtubules from the brain of rats. They found similar results in both models: at concentrations of 1 × 10−5 M of MeHg, the depolymerization of the microtubules began, reaching the total inhibition of polymerization at a concentration of 3 × 10−5 M MeHg. They also observed that 15 MeHg molecules had been attached to the 15 sulfhydryl groups that tubulin (proteins that makeup microtubules) has. This response is what determines the fragmentation of microtubules [98].
The stability of the cytoskeleton of cells is dependent on spectrins and RhoGTpases [99,100]. Spectrins are important proteins of the cytoskeleton because they help to maintain the integrity of the membrane and its morphology, and they participate in the transport of organelles, as well as in the establishment of polarity in RBCs [100]. RhoGTPases are important regulators of the organization of the actin cytoskeleton and their activation is necessary to maintain strong focal and cellular adhesion between cells [99].
We evidenced the upregulation of the spectrin SPTAN1 and the ARHGAP20 RhoGTPase genes. It is highly probable that, as a primary toxicity effect, MeHg initiated an attack on the cytoskeleton of the RBCs. This fact affects important functions, such as the mobilization of secretion and excretion vesicles, displacement of organelles, and intracellular transport of substances, as well as cell division (mitosis and meiosis) [101,102,103]. As an adaptive response, the increased expression of the SPTAN1 and ARHGAP20 genes inhibits microtubule fragmentation and stabilizes the plasma membrane of RBCs [104].
Other genes that regulate the cell cycle were also upregulated in the RBCs. This was the case with CEP250, UHRF2, and CTBP1 (Table 3). The CEP250 gene is related to the positive regulation of the G2/M transition of the mitotic cell cycle and participates in the biogenesis of the centriole and its duplication, the assembly of the spindle-kinetochore, the cell polarity, and the signaling mechanisms of the cell cycle checkpoint [105]. UHRF2, an ubiquitin involved in epigenetics, is closely related to several cell cycle proteins, such as cyclins (A2, B1, D1, and E1), CDK2, and pRb. Furthermore, UHRF2 is involved in the ubiquitination of the cyclins D1 and E1 [106]. UHRF2 is involved in epigenetic regulation by associating with DNMT, G9a, HDAC1, H3K9me2/3, and hemimethylated DNA. The protein encoded by the CTBP1 gene promotes cell cycle progression and has antiapoptotic activity given by the regulation of p53 activity [106,107,108]. Both UHRF2 and CTBP1, as well as Atg5, associate with p53 (tumor suppressor protein), but it is UHRF2 that produces the ubiquitination of p53 in vivo and in vitro [106].
Given that UHRF2-CTBP1 and p53 are all involved in cell cycle regulation, the hypothesis that this is a new signaling pathway in the cell must be studied [109,110]. Possible adaptive reactions to MeHg toxicity in the RBCs can be deducted from the activities of UHRF2 and CTBP1, such as changes in DNA (epigenetic methylation), and from damage to specific proteins of the cell cycle for which the final objective would be apoptosis. However, the upregulation of UHRF2 and CTBP1 involves, on the one hand, protecting the cell from errors in the folding of guide proteins and, on the other, preventing the accumulation of proteins and apoptosis [109,110]. The ubiquitination of proteins for their recycling is an important cellular adaptive response to regain homeostasis during the stress created by ROS produced by MeHg.
Regarding the CEP250 gene, it showed a relatively low upregulation in the RBCs. Probably, this was due to the fact that the RBCs did not have conditions for their reproduction in our bioassay. This adaptive response against MeHg demonstrates cellular damage at this level.

4.4. Alteration of Calcium Homeostasis and Mitochondria

One of the most widely documented effects produced by MeHg is related to glutamate-facilitated excitotoxicity, a mechanism that causes excess intracellular Ca2+ [111]. The cytoplasmic Ca2+ concentration is regulated in RBCs because calcium is a very important element in metabolic and intracellular signaling regulation [111]. In primary cultures of rat astrocytes exposed to concentrations of 1.5 and 10 μM, MeHg produced an increase in the permeability of the mitochondrial membrane, alterations in the glutamine/glutamate cycle, and increased ROS formation [112]. Atchison and Hare [113] reported that MeHg induced the disruption of intracellular Ca2+ regulation, blocking of voltage-dependent Ca2+ and Na+ channels in the plasma membrane, ultrastructural changes, and accumulation of MeHg within mitochondria. At the in vitro level, MeHg inhibits several mitochondrial enzymes and depolarizes the mitochondrial membrane, subsequently reducing ATP production [113].
It has been established that in vitro cell exposure to MeHg generates a Ca2+ overload in the cytoplasm, mediated by excitatory amino acid receptors (N-methyl D-aspartate (NMDA) and non-NMDA types) and by Ca2+ channels [114,115]. The excess of intracellular Ca2+ is distributed between the mitochondria and the smooth endoplasmic reticulum (ER). Mitochondria show low affinity and high capacity to transport Ca2+, while the ER has high affinity and low capacity to transport Ca2+ [116,117].
The RBCs presented three dysregulated genes: MFF, ATP13A1, and MSTO1. MFF regulates the fission of mitochondria in association with Drp1 [118]. Everything seems to indicate that the intracellular transport of Ca2+, when there is an imbalance increasing its intracellular concentration, initially produces pressure for the ER and the mitochondria to absorb part of the Ca2+ and avoid apoptosis. However, this triggers the fragmentation of the mitochondria via fission by MFF and the exit of cytochrome C from the mitochondria, which generates greater fission and apoptosis [118]. On the other hand, ATP13A1 is downregulated. Although little is known about its physiological function and properties, it is located in the ER and its function has been linked to calcium homeostasis [119].
The MSTO1 gene is also poorly studied. A mitochondrial location is suggested where mitochondrial morphology (via fusion) and distribution are regulated [120,121]. Fission should cause mitochondrial fusion almost immediately [121]. It is possible to hypothesize that the poor transcription of the MSTO1 gene does not stabilize the mitochondria, so fusion, which would eventually restore mitochondrial form and functions, does not occur. Mitochondrial fission and fusion appear to be regulated by complex molecular processes [120,121].

4.5. Regulation of Transcription

MeHg can cause DNA damage by oxidation and by its affinity with macromolecules [122]. Some studies have observed that MeHg produces DNA strand breakage, chromosomal aberrations, micronuclei, and decreased DNA repair [123,124]. However, these consequences are dose-dependent. It is important to note that mitochondrial DNA can also be affected, accentuating the appearance of damage [125].
In an interesting study, Wyatt et al. [125] exposed the C. elegans genome to low concentrations of MeHg and HgCl2 (1 mM), observing minor DNA damage; suddenly, however, a higher concentration of MeHg (5 mM) decreased the damage compared to controls. This result is in agreement with our findings in this study, where Gs1 expressed 11% fewer genes than Gs5. In the same way, we found evidence of the dysregulation of a good number of genes related to transcription and translation (22 and 4 genes respectively), with the downregulated genes being of greater quantity than the upregulated genes (15 and 11 genes respectively). It is important to note that the highest number of dysregulated genes was present in the Gc–Gs1 comparison (14 genes) and the lowest in the Gc–Gs5 comparison (three genes, less damage at higher concentration). Between Gs1 and Gs5, an intermediate number of genes (11 genes) were dysregulated.
Four dysregulated genes related to the regulation of transcription and gene silencing were detected [126]. Three of them were downregulated: the ZNF280D, PHF20L1, and ZC3H7A genes. ZC3H7A has functions related to post-transcriptional regulation, which could explain the decrease in gene expression [127]. MeHg has been found to induce repression of the chromatin structure in the promoter region of genes by inhibiting its expression [127], so the downregulation of these three genes, which also regulate the expression of other genes, is not strange. ZNF280D, PHF20L1, and ZC3H7A genes are downregulated at low concentrations of MeHg (Gs1) and, as observed at this concentration, there was a significant reduction in gene expression (11% lower than in Gs5). This could explain the decrease in the general expression of genes of Gs1.
In contrast, the PIAS2 gene was upregulated. The enzyme that encodes the PIAS2 gene contains two structural motifs (finger ring and SUMO binding) and one domain (SAP domain) that activate or repress the Elk-1 transcription factor, which depends on the MAPK pathway [128,129,130]. The Elk-1 transcription factor has been shown to bind to the promoters of almost 1000 genes, including IE genes (genes for rapid response to growth factors and other stimuli), genes encoding the basal transcription machinery, spliceosome components, and ribosomal proteins [129]. PIAS2 is a transcriptional co-regulator that activates or represses the transcription of at least 60 proteins. Among the transcription factors that regulate PIAS2 are Jak/STAT and NF-kB [131,132]. The expression of PIAS2, as is clear from this information, is tremendously important in the response to oxidative stress. While in Gs1 the PIAS2 gene was downregulated, and therefore the genes of the Elk-1, Jak/STAT, and NF-kB pathways were not expressed, in Gs5 the PIAS2 gene was upregulated and the pathways were activated. This finding could explain, in part, the reduction in gene expression in Gs1 compared to Gs5 and the difference between Gc and Gs5.
At the same time, the transcription factor gene SOX6 participates in pre-mRNA splicing [132], stimulates cell proliferation, and facilitates the maturation of RBCs [133]. Repression of this transcription factor has been reported to increase globin levels [134,135]. The dysregulation of the SOX6 gene may explain why the RBCs of Gs1, where this gene was downregulated, presented higher levels of alpha hemoglobins, compared to Gc and Gs5 (FPKM: 18.4, 13.6, and 15.1, respectively), as well as of beta hemoglobin (FPKM: 43.4, 14.2, and 29.5, respectively). However, they did not present differential expression or significant differences (Kruskal-Wallis Hb alpha p = 0.29 and Hb beta p = 0.24).
Ancora et al. [136] showed that Hg binds preferentially to the thiol groups of hemoglobin. Working with dolphins, they exposed blood samples to 0.1 mM MeHg. After a few minutes, 98.1% of the MeHg was in the RBCs, 1.3% in the plasma, and 0.6% in the plasma membrane. It is important to highlight that hemoglobin (Hb) interacts with the carbonic anhydrase-1 protein, the alpha hemoglobin stabilizing protein (AHSP), and Prdx2, with which it forms high-molecular-weight complexes, attenuating the formation of ROS and, in this way, protecting RBCs from oxidative stress [137]. Furthermore, the rate of thiols per hemoglobin tetramer in turtles is as low as in humans (5.6 and 5.8 respectively) compared to crocodiles (16), chondrichthyans (10), birds (9.2), and amphibians (7.2). Therefore, we hypothesize that, as loggerhead turtle hemoglobins are not very reactive, destabilization of their structure by mercuric ions is less possible.
We infer that, in Gs1, MeHg alters the expression of the alpha hemoglobin in the RBCs due to the downregulation of the SOX6 gene, triggering the upregulation of the alpha and beta hemoglobin, resulting in a greater production of ROS and, thus, reducing the overall expression of genes. It is not clear why the SOX6 gene is upregulated in Gs5 and downregulated in Gs1 yet, the only difference between the two groups was the concentration of MeHg.

4.6. Analysis of the Relative Expression (FPKM) of the Cysteines and Methionines, Glutathione, Selenocompounds, and Peroxyredoxins Metabolic Pathways

MeHg is an electrophile that regularly attacks nucleophilic groups (thiols and selenoles) [5]. Selenoproteins are the main target for mercury in thioredoxin, peroxiredoxin, glutathione-glutaredoxin, and other selenoprotein (P, K, and T) systems [2]. Mercury binds to selenocysteines in these proteins, inhibiting their function and altering their cellular redox environment, resulting in glutathione excitotoxicity, alteration of calcium homeostasis, damage to mitochondria, lipid peroxidation, deterioration in protein repair, and apoptosis [2,138]. Furthermore, mercury has high affinity for Se, which leads to the depletion of its reserves and, therefore, to the inhibition of selenoprotein synthesis [138].
The analysis of DEGs carried out in this study found that the enzymes that represent the first line of the antioxidant machinery in response to MeHg were not dysregulated. We did not find dysregulation in genes that encode selenoproteins or thiol-proteins. However, to find out which genes were being expressed, we analyzed metabolic pathways, and we detected 397 metabolic pathways in which all unigenes participate. Among these, we found the metabolisms of cysteines and methionines, glutathione, selenocompounds, and peroxiredoxins. Figure 9 shows the relative expression (FPKM) of the enzymes that are part of the metabolism of cysteines and methionines (Figure 9A). In this pathway, 30 genes were expressed, within which spermine synthase (SMS) was the only gene that presented significant differences (p < 0.05) between Gc and Gs1, showing higher relative expression in Gc than in Gs5 and Gs1. SMS is a polyamine with antioxidant and anti-inflammatory properties that have been reported to significantly inhibit the production of nitric oxide (NO), prostaglandins, and cytosines [139], and reduce intracellular MDA levels. This indicates that the RBCs have a constitutive expression of SMS, speD, and E3.3.1.1, all expressed in the pathway of cysteines and methionines, that would play a role in the initial response to oxidative stress generated by MeHg.
In glutathione metabolism (Figure 9B), the relative expression of 26 genes was identified, with high expressions (FPKM = between 100- and 300-fold) of PRDX6, GPX, GSTP, and GST, important enzymes in the response to oxidative stress. However, no significant differences were identified. In all these genes, the expression was always higher in Gs1 (Figure 9 B, green bar). A constitutive expression of these enzymes appears to be present here as well. Reischl [140] found that the glutathione concentration in RBCs of the tortoise Prynops hilarii was 1.9 ± 0.2 mM. This result provides grounds to think that the high content of -SH groups must be part of a redox buffer, an output antioxidant to counteract ROS and oxidative stress.
In the metabolism of selenocompounds (Figure 9C), the relative expression of ten genes was identified, without presenting significant differences. The MARS and SCLY genes showed higher relative constitutive expressions (FPKM = between 8 and 10) than the other enzymes of this pathway. Finally, we analyzed the relative expression of peroxiredoxins (Figure 9D), in which only the PRDX2 gene showed significant differences between Gc (FPKM = 694.1) and Gs1 (FPKM = 938.2) (p < 0.05). Among the group of peroxiredoxins, PRDX2 is the most efficient enzyme in the elimination of ROS and H2O2, and the second most abundant protein in the RBCs after hemoglobin [119,120], where it plays a fundamental role in the maintenance of the redox balance and its survival [141,142]. We found that Gs5 produced an intermediate relative expression (FPKM = 741.2). It seems that higher concentrations of MeHg do not encourage the expression of PRDX2 but, on the contrary, slow it down. In general, the genes that code for selenoproteins and that participate in the metabolism of selenocompounds, cysteine, methionine, and glutathione were not affected by in vitro exposure to MeHg. Dysregulation of these genes was not observed, as expected. However, these metabolic pathways show genes with constitutive expressions at high levels, as if turtles are always alert to the appearance of oxidative stress and, in this way, respond adaptively to counteract the harmful effects of toxicity. Krivoruchko and Storey [143], working with adult Trachemys scripta elegans turtles and Chrysemys picta marginata hatchlings, identified genes that are constitutively upregulated in different organs of these turtles, including: mitochondrial genes encoding electron transport chain proteins, iron storage proteins, serine protease inhibitors, transmembrane solute carriers, receptor proteins of transport and neurotransmission, chaperone proteins, and, most importantly, antioxidant enzymes. These authors proposed “the maintenance of constitutive protection mechanisms”. Turtles maintain a constitutive expression of many proteins that represent the defense against oxidative stress, anoxia, aging, and disease. While expensive in terms of energy consumption, it is very important to provide immediate protection against any metabolic attack.

4.7. Correlation between Level of Gene Expression and Enzyme Activity

We found a high statistical correlation between these variables (Figure 8). These analyses have been previously described in other works in which different toxic substances were evaluated in animal species.
In polychaetes (Perinereis nuntia), a correlation has been found between the GST gene relative expression levels and GST activity after exposure to a 50 µg L−1 dose of copper (Pearson’s correlation, r = 0.59–0.85, p = 0.001), which was given by the different GST isoforms (GST-omega and GST-sigma) [144,145]. Another study [146] used Perinereis nuntia individuals exposed to doses of 50 μg L−1 of Cd and found a high correlation between the relative expression levels of the GST-sigma and GST-omega isoforms and the total GST activity (Pearson correlation: r = 0.96, p < 0.01 and r = 0.93, p < 0.05, respectively).
Franco et al. [146] studied the effect of oxidative challenges in the relative expression of genes encoding the antioxidant enzymes, Cu/Zn-SOD, Mn-SOD GPx, and CAT, in in vitro muscle cells. They found that the treatment with pro-oxidant paraquat resulted in increases in transcriptional levels of these enzymes and activities. The level of transcription of GPx and CAT increased four- to fivefold and the activities of the enzymes increased two- to threefold. A similar response was presented in the enzymes Cu/Zn-SOD and Mn-SOD. More recently, Zhang et al. [147], working with planarians (Dugesia japonica), exposed them to glyphosate and found a correlation between total SOD activity and the relative expression levels of the enzyme Cu/Zn-SOD (Pearson r = 0.62).
The results obtained in this correlation show a high relationship between the activity measurements made with classical biochemistry and the relative expression of the genes measured in FPKM. It is important to note that the comparison of more genes could give more robustness to this analysis.

5. Conclusions

The toxicology of sea turtles is a relatively new field of research, yet the inclusion of RNAseq, together with bioinformatics and biochemical analyzes, represents a field of study for the present and future of toxicological research for these threatened and endangered animals. The threats posed by contamination by MeHg and other xenobiotics are imminent, and the rigorous study of their action mechanisms is imperative.
We have identified DEGs that affected biological processes in loggerhead turtle RBCs by exposure to MeHg. The downregulated genes were related to cell stress response, signaling, transcription, calcium metabolism, and membrane transport. On the other hand, the upregulated genes were involved in response to stress, lysosomes, mitochondria, regulation of the cell cycle, metabolic processes, transcription, and translation.
At low MeHg concentrations, in Gs1, gene dysregulation was higher compared to Gs5, producing a greater number of down- and upregulated genes. Furthermore, the total number of genes expressed in Gs1 was also lower (−11%) compared to RBCs exposed to a higher concentration of MeHg (Gs5). Everything seems to indicate that low concentrations of MeHg produce greater dysregulation. This hypothesis must be studied in depth to be corroborated.
We found that the RBCs in Gs1 evidenced a greater expression of alpha and beta hemoglobin, which could be related to ROS generation at a higher rate than in Gs5, a fact that could also explain greater dysregulation and lower total gene expression.
According to the analysis of DEGs, a low response of the antioxidant machinery of the early reaction to the toxicity of MeHg can be noted, evidenced by the fact that these genes were not dysregulated. Nonetheless, the expression analysis of the metabolism of cysteines and methionines, glutathione, selenocompounds, and peroxiredoxin enzymes showed a constitutive expression that could be related to “preparation for oxidative stress”, a theory proposed by the biochemist Evaldo Reischl [148], who argued that turtles and other animals have an early response strategy against oxidative stress.
The DEGs identified in this study provide a baseline for further studies on the impacts of MeHg oxidative stress on loggerhead turtle RBCs. We analyzed metabolic pathways using all identified unigenes and detected 397 metabolic pathways in which unigenes participate. This type of analysis has not been widely explored in Hg studies. Transcriptomics and the great advance of bioinformatics support the development of studies in ecotoxicogenomics, providing answers on the molecular mechanisms of toxicity used by MeHg against this sea turtle. There are no previous in vitro or in vivo studies on differential gene expression in RBCs or other tissues in loggerhead turtles. Therefore, it is important to develop additional studies to elucidate the transcriptomic responses of RBCs and other tissues of this turtle when exposed to MeHg.

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/article/10.3390/toxics9040070/s1, Figure S1: title, Table S1. Clean reads quality metrics. Table S2. Functional annotation of genes differentially expressed between Gc and Gs1 groups. Table S3. Functional annotation of genes differentially expressed between Gs1 and Gs5 groups. Table S4. Functional annotation of differentially expressed genes between Gc and Gs5 groups. Table S5. Gene ontology of differentially expressed genes in loggerhead turtle erythrocytes exposed between Gc–Gs1, Gs1–Gs5, Gc–Gs5 for 12 hours. Upregulated genes (≥1 time) and downregulated genes (≤−1 time, p-value < 0.01). Figure S1. Electrophoretic profile showing the integrity of the extracted RNA. RIN of the 15 samples evaluated. Figure S2. Length of unigenes. Figure S3. Differentially expressed unigenes. Figure S4A–D. Sperman’s multiple correlation analysis performed between the variables.

Author Contributions

Conceptualization, J.H.-F.; methodology, J.H.-F., P.R.-B. and A.P.-V.; software, J.H.-F., P.R.-B. and A.P.-V.; validation, J.H.-F., P.R.-B., L.M.-R., A.P.-V. and E.A.L.; formal analysis, J.H.-F.; A.P.-V. and L.M.-R.; investigation, J.H.-F. and P.R.-B.; resources, J.H.-F. and P.R.-B.; data curation, J.H.-F., P.R.-B., L.M.-R., A.P.-V. and E.A.L.; writing—original draft preparation, J.H.-F. writing—review and editing, J.H.-F., P.R.-B., L.M.-R., A.P.-V. and E.A.L.; supervision, E.A.L., L.M.-R., and A.P.-V.; project administration, J.H.-F.; funding acquisition, J.H.-F. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Office of Research, Creation, and Innovation of the Universidad Jorge Tadeo Lozano (340-07-10). This research was supported in part by the Intramural Research Program of the United States National Institutes of Health (NIH), National Library of Medicine (NLM), National Center for Biotechnology Information (NCBI) ZIA LM082713–06.

Institutional Review Board Statement

The samples were obtained under a research permit that was granted by the Ministry of Environment and Territorial Development (#24 of 22 June 2012) and Contract for Access to Genetic Resources (#64 of 23 April 2013). We also have a permit for the collection of samples of Colombian biodiversity, issued to the Jorge Tadeo Lozano University (Resolution 1271 of 23 October 2014, IDB040I File). The samples and methods used in this study are in accordance with the ethical standards of Colombian legislation and the authorization and supervision of Directorate of Research, Creation and Extension of the Jorge Tadeo Lozano University (UJTL) (Project 340-July-2010).

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Acknowledgments

We are grateful to Rodadero Aquarium in Santa Marta for their collaboration in obtaining and providing samples of loggerhead sea turtles for the development of this study. Samples were obtained under permit for the collection of samples of Colombian biodiversity, issued to the Jorge Tadeo Lozano University (Resolution 1715 of 23 October 2015, IDB040I File).

Conflicts of Interest

The authors declare that they have no known competing financial interests or personal relationships that could have influenced the results reported in this paper.

References

  1. Facemire, C.; Augspurger, T.; Bateman, D.; Brim, M.; Conzelmann, P.; Delchamps, S.; Masson, G. Impacts of mercury contamination in the southeastern United States. In Mercury as a Global Pollutant; Springer: Dordrech, The Netherlands, 1995; pp. 923–926. [Google Scholar]
  2. Ajsuvakova, O.P.; Tinkov, A.A.; Aschner, M.; Rocha, J.B.; Michalke, B.; Skalnaya, M.G.; Aaseth, J. Sulfhydryl groups as targets of mercury toxicity. Coord. Chem. Rev. 2020, 417, 213–343. [Google Scholar] [CrossRef] [PubMed]
  3. Fernández, A.; Singh, A.; Jaffé, R. A literature review on trace metals and organic compounds of anthropogenic origin in the Wider Caribbean Region. Mar. Pollute. Bull. 2007, 54, 1681–1691. [Google Scholar] [CrossRef]
  4. dos Santos, A.; Ferrer, B.; Marques Gonçalves, F.; Tsatsakis, A.M.; Renieri, E.; Skalny, A.; Aschner, M.A. Oxidative stress in methylmercury-induced cell toxicity. Toxics 2018, 6, 47. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  5. Burger, J.; Gochfeld, M. Mercury in canned tuna: White versus light and temporal variation. Environ. Res. 2004, 96, 239–249. [Google Scholar] [CrossRef]
  6. Henny, C.J.; Hill, E.F.; Hoffman, D.J.; Spalding, M.G.; Grove, R.A. Nineteenth century mercury: Hazard to wading birds and cormorants of the Carson River, Nevada. Ecotoxicology 2002, 11, 213–231. [Google Scholar] [CrossRef] [PubMed]
  7. Bridges, C.C.; Zalups, R.K. Mechanisms involved in the transport of mercuric ions in target tissues. Arch. Toxicol. 2017, 91, 63–81. [Google Scholar] [CrossRef] [Green Version]
  8. Oliveira, C.S.; Piccoli, B.C.; Aschner, M.; Rocha, J.B.T. Chemical speciation of selenium and mercury as determinant of their neurotoxicity in Neurotoxicity of Metals. In Neurotoxicity of Metals. Advances in Neurobiology, 1st ed.; Springer: Cham, Switzerland, 2017; pp. 53–83. [Google Scholar]
  9. Wiener, J.G.; Krabbenhoft, D.P.; Heinz, G.H.; Scheuhammer, A.M. Ecotoxicology of Mercury. In Handbook of Ecotoxicology, 2nd ed.; Hoffman, D.J., Rattner, B.A., Burton, G.A., Cairns, J., Jr., Eds.; CRC Press: Boca Raton, FL, USA, 2003; pp. 409–463. [Google Scholar]
  10. Storelli, M.M.; Storelli, A.; D’Addabbo, R.; Marano, C.; Bruno, R.; Marcotrigiano, G.O. Trace elements in loggerhead turtles (Caretta caretta) from the eastern Mediterranean Sea: Overview and evaluation. Environ. Pollut. 2005, 135, 163–170. [Google Scholar] [CrossRef]
  11. Yipel, M.; Tekeli, İ.O.; İşler, C.T.; Altuğ, M.E. Heavy metal distribution in blood, liver and kidneys of Loggerhead (Caretta caretta) and Green (Chelonia mydas) sea turtles from the Northeast Mediterranean Sea. Mar. Pollut. Bull. 2017, 125, 487–491. [Google Scholar] [CrossRef]
  12. Ley-Quiñónez, C.; Zavala-Norzagaray, A.A.; Espinosa-Carreon, T.L.; Peckham, H.; Marquez-Herrera, C.; Campos-Villegas, L.; Aguirre, A.A. Baseline heavy metals and metalloid values in blood of loggerhead turtles (Caretta caretta) from Baja California Sur, Mexico. Mar. Pollut. Bull. 2011, 62, 1979–1983. [Google Scholar] [CrossRef]
  13. Yang, L.; Zhang, Y.; Wang, F.; Luo, Z.; Guo, S.; Strähle, U. Toxicity of mercury: Molecular evidence. Chemosphere 2020, 245, 125586. [Google Scholar] [CrossRef] [PubMed]
  14. Wilke, R.A.; Kolbert, C.P.; Rahimi, R.A.; Windebank, A.J. Methylmercury induces apoptosis in cultured rat dorsal root ganglion neurons. Neurotoxicology 2003, 24, 369–378. [Google Scholar] [CrossRef]
  15. Parran, D.K.; Barone Jr, S.; Mundy, W.R. Methylmercury inhibits TrkA signaling through the ERK1/2 cascade after NGF stimulation of PC12 cells. Brain. Res. 2004, 149, 53–61. [Google Scholar] [CrossRef]
  16. Rand, M.D.; Bland, C.E.; Bond, J. Methylmercury activates enhancer-of-split and bearded complex genes independent of the notch receptor. Toxicol. Sci. 2008, 104, 163–176. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  17. Wolfe, M.F.; Schwarzbach, S.; Sulaiman, R.A. Effects of mercury on wildlife: A comprehensive review. Environ. Toxicol. Chem. 1998, 17, 146–160. [Google Scholar] [CrossRef]
  18. Gardner, S.C. Introduction to reptilian toxicology. In Toxicology of Reptiles; Gardner, S.C., Oberdörster, E., Eds.; CRC Press: Boca Raton, FL, USA, 2006; pp. 1–8. [Google Scholar]
  19. Grillitsch, B.; Schiesari, L. The Ecotoxicology of Metals in Reptiles. In Ecotoxicology of Amphibians and Reptiles, 2nd ed.; CRC Press: Boca Raton, FL, USA, 2010; pp. 337–448. [Google Scholar]
  20. Day, R.D.; Segars, A.L.; Arendt, M.D.; Lee, A.M.; Peden-Adams, M.M. Relationship of blood mercury levels to health parameters in the loggerhead sea turtle (Caretta caretta). Environ. Health Perspect. 2007, 115, 1421. [Google Scholar] [CrossRef] [Green Version]
  21. Ungerer, M.C.; Johnson, L.C.; Herman, M.A. Ecological genomics: Understanding gene and genome function in the natural environment. Heredity 2008, 100, 178–183. [Google Scholar] [CrossRef] [Green Version]
  22. Dalziel, A.C.; Rogers, S.M.; Schulte, P.M. Linking genotypes to phenotypes and fitness: How mechanistic biology can inform molecular ecology. Mol. Ecol. 2009, 18, 4997–5017. [Google Scholar] [CrossRef] [PubMed]
  23. Stapley, J.; Reger, J.; Feulner, P.G.; Smadja, C.; Galindo, J.; Ekblom, R.; Slate, J. Adaptation genomics: The next generation. Trends. Ecol. Evol. 2010, 25, 705–712. [Google Scholar] [CrossRef]
  24. Smith-Keune, C.; Dove, S. Gene expression of a green fluorescent protein homolog as a host-specific biomarker of heat stress within a reef-building coral. Mar. Biotechnol. 2008, 10, 166–180. [Google Scholar] [CrossRef]
  25. Oliveira, C.S.; Segatto, A.L.; Nogara, P.A.; Piccoli, B.C.; Loreto, É.L.; Aschner, M.; Rocha, J.B. Transcriptomic and proteomic tools in the study of Hg toxicity: What is missing? Genet 2020, 11, 425. [Google Scholar] [CrossRef]
  26. Theunissen, P.T.; Pennings, J.L.; Robinson, J.F.; Claessen, S.M.; Kleinjans, J.C.; Piersma, A.H. Time-response evaluation by transcriptomics of methylmercury effects on neural differentiation of murine embryonic stem cells. Toxicol. Sci. 2011, 122, 437–447. [Google Scholar] [CrossRef] [Green Version]
  27. Liu, Q.; Basu, N.; Goetz, G.; Jiang, N.; Hutz, R.J.; Tonellato, P.J.; Carvan, M.J. Differential gene expression associated with dietary methylmercury (MeHg) exposure in rainbow trout (Oncorhynchus mykiss) and zebrafish (Danio rerio). Ecotoxicology 2013, 22, 740–751. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  28. Yadetie, F.; Karlsen, O.A.; Lanzén, A.; Berg, K.; Olsvik, P.; Hogstrand, C.; Goksøyr, A. Global transcriptome analysis of Atlantic cod (Gadus morhua) liver after in vivo methylmercury exposure suggests effects on energy metabolism pathways. Aquat. Toxicol. 2013, 126, 314–325. [Google Scholar] [CrossRef]
  29. Piccoli, B.C.; Segatto, A.L.A.; Loreto, É.L.; Moreira, J.C.F.; Ardisson-Araújo, D.M.; Rocha, J.B. Transcriptional analyses of acute per os exposure and co-exposure of 4-vinylcyclohexene and methylmercury-contaminated diet in adults of Drosophila melanogaster. Environ. Pollut. 2020, 114632. [Google Scholar] [CrossRef]
  30. Waldmann, T.; Grinberg, M.; Konig, A.; Rempel, E.; Schildknecht, S.; Henry, M.; Rahnenfuhrer, J. Stem cell transcriptome responses and corresponding biomarkers that indicate the transition from adaptive responses to cytotoxicity. Chem. Res. Toxicol. 2017, 30, 905–922. [Google Scholar] [CrossRef] [PubMed]
  31. Sakai, H.; Saeki, K.; Ichihashi, H.; Kamezaki, N.; Tanabe, S.; Tatsukawa, R. Growth-related changes in heavy metal accumulation in green turtle (Chelonia mydas) from Yaeyama Islands, Okinawa, Japan. Arch. Environ. Contam. Toxicol. 2000, 39, 378–385. [Google Scholar] [CrossRef]
  32. Hernández-Fernández, J.; López-Barrera, E.A.; Mariño-Ramírez, L.; Rodríguez-Becerra, P.; Pinzón-Velasco, A. Oxidative Stress Biomarkers in Erythrocytes of Captive Pre-Juvenile Loggerhead Turtles following Acute Exposure to Methylmercury. Appl. Sci. 2020, 10, 3602. [Google Scholar] [CrossRef]
  33. Finlayson, K.A.; Leusch, F.D.; Van de Merwe, J.P. The current state and future directions of marine turtle toxicology research. Environ. Int. 2016, 94, 113–123. [Google Scholar] [CrossRef]
  34. Webb, S.J.; Zychowski, G.V.; Bauman, S.W.; Higgins, B.M.; Raudsepp, T.; Gollahon, L.S.; Wooten, K.J.; Cole, J.M.; Godard-Codding, C. Establishment, characterization, and toxicological application of loggerhead sea turtle (Caretta caretta) primary skin fibroblast cell cultures. Environ. Sci. Technol. 2014, 48, 14728–14737. [Google Scholar] [CrossRef]
  35. Young, J.L.; Wise, S.S.; Xie, H.; Zhu, C.; Fukuda, T.; Wise, J.P. Comparative cytotoxicity and genotoxicity of soluble and particulate hexavalent chromium in human and hawksbill sea turtle (Eretmochelys imbricata) skin cells. Comp. Biochem. Physiol. Part C Toxicol. Pharmacol. 2015, 178, 145–155. [Google Scholar] [CrossRef] [Green Version]
  36. Finlayson, K.A.; Leusch, F.D.L.; van de Merwe, J.P. Cytotoxicity of organic and inorganic compounds to primary cell cultures established from internal tissues of Chelonia mydas. Sci. Total Environ. 2019, 664, 958–967. [Google Scholar] [CrossRef]
  37. Finlayson, K.A.; Hof, C.A.M.; van de Merwe, J.P. Development and application of species-specific cell-based bioassays to assess toxicity in green sea turtles. Sci. Total. Environ. 2020, 747, 142095. [Google Scholar] [CrossRef]
  38. Zhu, F.Y.; Chen, M.X.; Ye, N.H.; Qiao, W.M.; Gao, B.; Law, W.K.; Tian, Y.; Zhang, D.; Zhang, D.; Liu, T.Y.; et al. Comparative performance of the BGISEQ-500 and Illumina HiSeq4000 sequencing platforms for transcriptome analysis in plants. Plant Methods 2018, 14, 1–14. [Google Scholar] [CrossRef] [Green Version]
  39. Andrews, S. FastQC A Quality control tool for high throughput sequence data. Babraham. Bioinfo. 2018. Available online: http://www.bioinformatics.babraham.ac.uk/projects/fastqc (accessed on 2 February 2020).
  40. Bolger, A.M.; Lohse, M.; Usadel, B. Trimmomatic: A flexible trimmer for Illumina sequence data. Bioinformatics 2014, 30, 2114–2120. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  41. Haas, B.J.; Papanicolaou, A.; Yassour, M.; Grabherr, M.; Blood, P.D.; Bowden, J.; MacManes, M.D. De novo transcript sequence reconstruction from RNA-seq using the Trinity platform for reference generation and analysis. Nat. Protoc. 2013, 8, 1494–1512. [Google Scholar] [CrossRef] [PubMed]
  42. Kemena, C.; Dohmen, E.; Bornberg-Bauer, E. DOGMA: A web server for proteome and transcriptome quality assessment. Nucleic Acids Res. 2019, 47, W507–W510. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  43. Pertea, G.; Huang, X.; Liang, F.; Antonescu, V.; Sultana, R.; Karamycheva, S.; Tsai, J. TIGR Gene Indices clustering tools (TGICL): A software system for fast clustering of large EST datasets. Bioinformatics 2003, 19, 651–652. [Google Scholar] [CrossRef] [Green Version]
  44. Altschul, S.F.; Madden, T.L.; Schäffer, A.A.; Zhang, J.; Zhang, Z.; Miller, W.; Lipman, D.J. Gapped BLAST and PSI-BLAST: A new generation of protein database search programs. Nucleic Acids Res. 1997, 25, 3389–3402. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  45. Conesa, A.; Götz, S.; García-Gómez, J.M.; Terol, J.; Talón, M.; Robles, M. Blast2GO: A universal tool for annotation, visualization and analysis in functional genomics research. Bioinformatics 2005, 21, 3674–3676. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  46. Ye, J.; Fang, L.; Zheng, H.; Zhang, Y.; Chen, J.; Zhang, Z.; Wang, J. WEGO: A web tool for plotting GO annotations. Nucleic Acids Res. 2006, 34 (Suppl. 2), W293–W297. [Google Scholar] [CrossRef] [PubMed]
  47. Quevillon, E.; Silventoinen, V.; Pillai, S.; Harte, N.; Mulder, N.; Apweiler, R.; Lopez, R. InterProScan: Protein domains identifier. Nucleic Acids Res. 2005, 33 (Suppl. 2), W116–W120. [Google Scholar] [CrossRef] [Green Version]
  48. Haas, B.J.; Papanicolaou, A. TransDecoder 5.5.0. 2019. Available online: https://github.com/TransDecoder/TransDecoder/wiki (accessed on 13 January 2021).
  49. Langmead, B.; Salzberg, S.L. Fast gapped-read alignment with Bowtie 2. Nat. Methods 2012, 9, 357. [Google Scholar] [CrossRef] [Green Version]
  50. Li, B.; Dewey, C.N. RSEM: Accurate transcript quantification from RNA-Seq data with or without a reference genome. BMC Bioinform. 2011, 12, 323. [Google Scholar] [CrossRef] [Green Version]
  51. Mortazavi, A.; Williams, B.A.; McCue, K.; Schaeffer, L.; Wold, B. Mapping and quantifying mammalian transcriptomes by RNA-seq. Nat. Methods 2008, 5, 621–628. [Google Scholar] [CrossRef]
  52. Love, M.; Anders, S.; Huber, W. Differential analysis of count data–the DESeq2 package. Genome Biol. 2014, 15, 10–1186. [Google Scholar]
  53. Oliveros, J.C. Venny. An Interactive Tool for Comparing Lists with Venn’s Diagrams. 2017 (2007–2015). Available online: https://bioinfogp.cnb.csic.es/tools/venny/index.html (accessed on 20 August 2020).
  54. Guisande, C.; Heine, J.; González-DaCosta, J.; García-Roselló, E. RWizard Software; University of Vigo: Vigo, Spain, 2014. [Google Scholar]
  55. Zhang, X.O.; Wang, H.B.; Zhang, Y.; Lu, X.; Chen, L.L.; Yang, L. Complementary sequence-mediated exoncircularization. Cell 2014, 159, 134–147. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. McElwee, M.K.; Ho, L.A.; Chou, J.W. Comparative toxicogenomic responses of mercuric and methyl mercury. BMC Genom. 2013, 14, 698. [Google Scholar] [CrossRef] [Green Version]
  57. Rangan, P.; Furtado, A.; Henry, R. New evidence for grain specific C4 photosynthesis in wheat. Sci. Rep. 2016, 6, 31721. [Google Scholar] [CrossRef] [Green Version]
  58. Zhao, Z.H.; Meng, T.G.; Li, A. RNA-Seq transcriptome reveals different molecular responses during human. and mouse oocyte maturation and fertilization. BMC Genom. 2020, 21, 475. [Google Scholar]
  59. Touma, J.; García, K.K.; Bravo, S.; Leiva, F.; Moya, J.; Vargas-Chacoff, L.; Reyes, A.; Vidal, R. De novo. Assembly and Characterization of Patagonian Toothfish Transcriptome and Develop of EST-SSR Markers for Population Genetics. Front. Mar. Sci. 2019, 6, 720. [Google Scholar] [CrossRef] [Green Version]
  60. Bohn, J.; Halabian, R.; Schrader, L.; Shabardina, V.; Stefffen, R.; Suzuki, Y.; Makalowski, W. High-Quality. Genome Assembly and Annotation of the California Harvester Ant. Pogonomyrmex californicus (Buckley, 1867). G3 Genes|Genomes|Genet. 2021, 11, 1–9. [Google Scholar] [CrossRef]
  61. Dohmen, E.; Klasberg, S.; Bornberg-Bauer, E. The modular nature of protein evolution: Domain rearrangement rates across eukaryotic life. BMC Evol. Biol. 2020, 20, 30. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  62. Daré, E.; Li, W.; Zhivotovsky, B.; Yuan, X.; Ceccatelli, S. Methylmercury and H2O2 provoke lysosomal damage in human astrocytoma D384 cells followed by apoptosis. Free Radic. Biol. Med. 2001, 30, 1347–1356. [Google Scholar] [CrossRef]
  63. Mahapatra, C.T.; Rand, M.D. Methylmercury tolerance is associated with the humoral stress factor gene Turandot A. Neurotoxicol. Teratol. 2012, 34, 387–394. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  64. Chang, S.H.; Lee, H.J.; Kang, B.; Yu, K.N.; Minai-Tehrani, A.; Lee, S.; Cho, M.H. Methylmercury induces caspase-dependent apoptosis and autophagy in human neural stem cells. J. Toxicol. Sci. 2013, 38, 823–831. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  65. Chen, N.; Lin, M.; Liu, N.; Wang, S.; Xiao, X. Methylmercury-induced testis damage is associated with activation of oxidative stress and germ cell autophagy. J. Inorg. Biochem. 2019, 190, 67–74. [Google Scholar] [CrossRef] [PubMed]
  66. Zhu, J.; Wang, C.; Gao, X.; Zhu, J.; Wang, L.; Cao, S.; Li, L. Comparative effects of mercury chloride and methylmercury exposure on early neurodevelopment in zebrafish larvae. RSC Adv. 2019, 9, 10766–10775. [Google Scholar] [CrossRef] [Green Version]
  67. Amin, S.; Prentis, P.J.; Gilding, E.K.; Pavasovic, A. Assembly and annotation of a non-model gastropod (Nerita melanotragus) transcriptome: A comparison of de novo assemblers. BMC Res. Notes 2014, 7, 1–8. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  68. Hartung, T.; FitzGerald, R.E.; Jennings, P.; Mirams, G.R.; Peitsch, M.C.; Rostami-Hodjegan, A.; Sturla, S.J. Systems toxicology: Real world applications and opportunities. Chem. Res. Toxicol. 2017, 30, 870–882. [Google Scholar] [CrossRef] [PubMed]
  69. Gräb, J.; Rybniker, J. The expanding role of p38 mitogen-activated protein kinase in programmed host cell death. Microbiol. Insights 2019, 12, 1178636119864594. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  70. Ferrelli, F.; Pastore, D.; Capuani, B.; Lombardo, M.F.; Blot-Chabaud, M.; Coppola, A.; Caratelli, S. Serum. glucocorticoid inducible kinase (SGK)-1 protects endothelial cells against oxidative stress and apoptosis induced by hyperglycemia. Acta Diabetol. 2015, 52, 55–64. [Google Scholar] [CrossRef]
  71. Takanezawa, Y.; Nakamura, R.; Sone, Y.; Uraguchi, S.; Kiyono, M. Atg5-dependent autophagy plays a protective role against methylmercury-induced cytotoxicity. Toxicol. Lett. 2016, 262, 135–141. [Google Scholar] [CrossRef] [PubMed]
  72. Mukhopadhyay, S.; Panda, P.K.; Sinha, N.; Das, D.N.; Bhutia, S.K. Autophagy and apoptosis: Where do they meet? Apoptosis 2014, 19, 555–566. [Google Scholar] [CrossRef] [PubMed]
  73. Resh, M.D. Palmitoylation of ligands, receptors, and intracellular signaling molecules. Sci. Signal. 2006, 359, re14. [Google Scholar] [CrossRef] [PubMed]
  74. Hsiao, K.Y.; Mizzen, C.A. Histone H4 deacetylation facilitates 53BP1 DNA damage signaling and double strand break repair. J. Mol. Cell Biol. 2013, 5, 157–165. [Google Scholar] [CrossRef]
  75. Shen, W.; Wei, Y.; Dauk, M.; Tan, Y.; Taylor, D.C.; Selvaraj, G.; Zou, J. Involvement of a glycerol-3-phosphate dehydrogenase in modulating the NADH/NAD+ ratio provides evidence of a mitochondrial glycerol-3-phosphate shuttle in Arabidopsis. Plant Cell 2006, 18, 422–441. [Google Scholar] [CrossRef] [Green Version]
  76. Ansell, R.; Granath, K.; Hohmann, S.; Thevelein, J.M.; Adler, L. The two isoenzyme for yeast NAD+-dependent glycerol 3-phosphate dehydrogenase encoded by GPD1 and GPD2 have distinct roles in osmoadaptation and redox regulation. EMBO J. 1997, 16, 2179–2187. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  77. Eriksson, P.; André, L.; Ansell, R.; Blomberg, A.; Adler, L. Clonación molecular de GPD2, un segundo gen que codifica el sn-glicerol3-fosfato deshidrogenasa (NAD) en Saccharomyces cerevisiae, y su comparación con GPD1+. Mol. Microbiol. 1995, 17, 95–107. [Google Scholar] [CrossRef]
  78. Norbeck, J.; Påhlman, A.K.; Akhtar, N.; Blomberg, A.; Adler, L. Purification and characterization of two isoenzymes of DL-glycerol 3-phosphatase from Saccharomyces cerevisiae. Identification of the corresponding GPP1 and GPP2 genes and evidence for osmotic regulation of Gpp2p expression by the osmosensing mitogen-activated protein kinase signal transduction pathway. J. Biol. Chem. 1996, 271, 13875–13881. [Google Scholar]
  79. Sun, Z.; Wu, T.; Zhao, F.; Lau, A.; Birch, C.M.; Zhang, D.D. KPNA6 (Importin α7)-mediated nuclear import of Keap1 represses the Nrf2-dependent antioxidant response. Mol. Cell Biol. 2011, 31, 1800–1811. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  80. Malhotra, D.; Portales-Casamar, E.; Singh, A.; Srivastava, S.; Arenillas, D.; Happel, C.; Biswal, S. Global mapping of binding sites for Nrf2 identifies novel targets in cell survival response through ChIP-Seq profiling and network analysis. Nucleic Acids Res. 2010, 38, 5718–5734. [Google Scholar] [CrossRef] [PubMed]
  81. He, F.; Ru, X.; Wen, T. NRF2, a Transcription Factor for Stress Response and Beyond. Int. J. Mol. Sci. 2020, 21, 4777. [Google Scholar] [CrossRef]
  82. Karapetian, R.N.; Evstafieva, A.G.; Abaeva, I.S.; Chichkova, N.V.; Filonov, G.S.; Rubtsov, Y.P.; Vartapetian, A.B. Nuclear oncoprotein prothymosin α is a partner of Keap1: Implications for expression of oxidative stress-protecting genes. Mol. Cell Biol. 2005, 25, 1089–1099. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  83. Kobayashi, A.; Kang, M.I.; Watai, Y.; Tong, K.I.; Shibata, T.; Uchida, K.; Yamamoto, M. Oxidative and electrophilic stresses activate Nrf2 through inhibition of ubiquitination activity of Keap1. Mol. Cell Biol. 2006, 26, 221–229. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  84. Kalmar, B.; Greensmith, L. Induction of heat shock proteins for protection against oxidative stress. Adv. Drug Deliv. Rev. 2009, 61, 310–318. [Google Scholar] [CrossRef] [PubMed]
  85. Finkel, T.; Holbrook, N.J. Oxidants, oxidative stress and the biology of ageing. Nature 2000, 408, 239–247. [Google Scholar] [CrossRef] [PubMed]
  86. Balla, G.; Jacob, H.S.; Balla, J.; Rosenberg, M.; Nath, K.; Apple, F.; Vercellotti, G.M. Ferritin: A cytoprotective antioxidant strategem of endothelium. J. Biol. Chem. 1992, 267, 18148–18153. [Google Scholar] [CrossRef]
  87. Torti, F.M.; Torti, S.V. Regulación de genes y proteínas de ferritina. Blood, Am. J. Hematol. 2002, 99, 3505–3516. [Google Scholar]
  88. Yuntao, F.; Chenjia, G.; Panpan, Z.; Wenjun, Z.; Suhua, W.; Guangwei, X.; Cai, J. Role of autophagy in methylmercury-induced neurotoxicity in rat primary astrocytes. Arch. Toxicol. 2016, 90, 333–345. [Google Scholar] [CrossRef]
  89. Chatterjee, S.; Ray, A.; Mukherjee, S.; Agarwal, S.; Kundu, R.; Bhattacharya, S. Low concentration of mercury induces autophagic cell death in rat hepatocytes. Toxicol. Ind. Health 2014, 30, 611–620. [Google Scholar] [CrossRef]
  90. Patterson, M.C. Hexosaminidase Deficiency, 2nd ed.; Academic Press: Rochester, MN, USA, 2014; pp. 564–565. [Google Scholar]
  91. Zheng, C.; Huang, R.; Bavaro, T.; Terreni, M.; Sollogoub, M.; Xu, J.; Zhang, Y. Design, synthesis and biological evaluation of new ganglioside GM3 analogues as potential agents for cancer therapy. Eur. J. Med. Chem. 2020, 189, 112065. [Google Scholar] [CrossRef]
  92. Gytz, H.; Liang, J.; Liang, Y.; Gorelik, A.; Illes, K.; Nagar, B. The structure of mammalian β-mannosidase provides insight into β-mannosidosis and nystagmus. FEBS J. 2019, 286, 1319–1331. [Google Scholar] [CrossRef] [PubMed]
  93. Reyes, L.H.; Cardona, C.; Pimentel, L.; Rodríguez-López, A.; Alméciga-Díaz, C.J. Improvement in the production of the human recombinant enzyme N-acetylgalactosamine-6-sulfatase (rhGALNS) in Escherichia coli using synthetic biology approaches. Sci. Rep. 2017, 7, 1–14. [Google Scholar] [CrossRef]
  94. Davies, A.K.; Itzhak, D.N.; Edgar, J.R.; Archuleta, T.L.; Hirst, J.; Jackson, L.P.; Borner, G.H. AP-4 vesicles contribute to spatial control of autophagy via RUSC-dependent peripheral delivery of ATG9A. Nat. Commun. 2018, 9, 1–21. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  95. Jung, J.; Genau, H.M.; Behrends, C. Amino acid-dependent mTORC1 regulation by the lysosomal membrane protein SLC38A9. Mol. Cell boil. 2015, 35, 2479–2494. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  96. Wang, S.; Tsun, Z.Y.; Wolfson, R.L.; Shen, K.; Wyant, G.A.; Plovanich, M.E.; Wang, T. Lysosomal amino acid transporter SLC38A9 signals arginine sufficiency to mTORC1. Science 2015, 347, 188–194. [Google Scholar] [CrossRef] [Green Version]
  97. Lamming, D.W.; Bar-Peled, L. Lysosome: The metabolic signaling hub. Traffic 2019, 20, 27–38. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  98. Vogel, D.G.; Margolis, R.L.; Mottet, N.K. The effects of methyl mercury binding to microtubules. Toxicol. Appl. Pharmacol. 1985, 80, 473–486. [Google Scholar] [CrossRef]
  99. Hall, A. Rho GTPases and the actin cytoskeleton. Science 1998, 279, 509–514. [Google Scholar] [CrossRef] [Green Version]
  100. Liao, E.C.; Paw, B.H.; Peters, L.L.; Zapata, A.; Pratt, S.J.; Do, C.P.; Zon, L.I. Hereditary spherocytosis in zebrafish riesling illustrates evolution of erythroid beta-spectrin structure, and function in red cell morphogenesis and membrane stability. Development 2000, 127, 5123–5132. [Google Scholar]
  101. Ochi, T. Methylmercury, but not inorganic mercury, causes abnormality of centrosome integrity (multiple foci of γ-tubulin), multipolar spindles and multinucleated cells without microtubule disruption in cultured Chinese hamster V79 cells. Toxicology 2002, 175, 111–121. [Google Scholar] [CrossRef]
  102. Bhattacharya, R.; Cabral, F. A ubiquitous β-tubulin disrupts microtubule assembly and inhibits cell proliferation. Mol. Boil. Cell 2004, 15, 3123–3131. [Google Scholar] [CrossRef] [Green Version]
  103. Smith, R.; Bacos, K.; Fedele, V.; Soulet, D.; Walz, H.A.; Obermüller, S.; Brundin, P. Mutant huntingtin interacts with β-tubulin and disrupts vesicular transport and insulin secretion. Hum. Mol. Genet. 2009, 18, 3942–3954. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  104. Ackermann, A.; Brieger, A. The role of nonerythroid spectrin II in cancer. Int. J. Oncol. 2019, 2019, 1–14. [Google Scholar]
  105. Kumar, A.; Rajendran, V.; Sethumadhavan, R.; Purohit, R. CEP proteins: The knights of centrosome dynasty. Protoplasma 2013, 250, 965–983. [Google Scholar] [CrossRef]
  106. Zhao, C.; Shen, Y.; Tao, X.; Xu, J.; Lu, J.; Liu, C.; Zhang, X. Silencing of CtBP1 suppresses the migration in human glioma cells. J. Mol. Histol. 2016, 47, 297–304. [Google Scholar] [CrossRef]
  107. Grooteclaes, M.L.; Frisch, S.M. Evidence for a function of CtBP in epithelial gene regulation and anoikis. Oncogene 2000, 19, 3823–3828. [Google Scholar] [CrossRef] [Green Version]
  108. Zhang, Q.; Yoshimatsu, Y.; Hildebrand, J.; Frisch, S.M.; Goodman, R.H. Homeodomain interacting protein kinase 2 promotes apoptosis by downregulating the transcriptional corepressor CtBP. Cell 2003, 115, 177–186. [Google Scholar] [CrossRef] [Green Version]
  109. Mori, T.; Ikeda, D.D.; Yamaguchi, Y.; Unoki, M. NIRF/UHRF2 occupies a central position in the cell cycle network and allows coupling with the epigenetic landscape. FEBS Lett. 2012, 586, 1570–1583. [Google Scholar] [CrossRef] [Green Version]
  110. Raza, U.; Saatci, Ö.; Uhlmann, S.; Ansari, S.A.; Eyüpoğlu, E.; Yurdusev, E.; Doğan, H.T. The miR-644a/CTBP1/p53 axis suppresses drug resistance by simultaneous inhibition of cell survival and epithelial-mesenchymal transition in breast cancer. Oncotarget 2016, 7, 49859. [Google Scholar] [CrossRef] [Green Version]
  111. Roos, D.; Seeger, R.; Puntel, R.; Vargas-Barbosa, N. Role of calcium and mitochondria in MeHg-mediated cytotoxicity. J. Biomed. Biotechnol. 2012, 2012, 1–15. [Google Scholar] [CrossRef] [Green Version]
  112. Yin, Z.; Milatovic, D.; Aschner, J.L.; Syversen, T.; Rocha, J.B.; Souza, D.O.; Aschner, M. Methylmercury induces oxidative injury, alterations in permeability and glutamine transport in cultured astrocytes. Brain Res. 2007, 1131, 1–10. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  113. Atchison, W.D.; Hare, M.F. Mechanisms of methylmercury-induced neurotoxicity. FASEB J. 1994, 8, 622–629. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  114. Yuan, Y.; Atchison, W.D. Methylmercury-induced increase of intracellular Ca2+ increases spontaneous synaptic current frequency in rat cerebellar slices. Mol. Pharmacol. 2007, 71, 1109–1121. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  115. Ramanathan, G.; Atchison, W.D. Ca2+ entry pathways in mouse spinal motor neurons in culture following in vitro exposure to methylmercury. Neurotoxicology 2011, 32, 742–750. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  116. Somlyo, A.P.; Bond, M.; Somlyo, A.V. Calcium content of mitochondria and endoplasmic reticulum in liver frozen rapidly in vivo. Nature 1985, 314, 622–625. [Google Scholar] [CrossRef]
  117. Wei, A.C.; Liu, T.; Cortassa, S.; Winslow, R.L.; O’Rourke, B. Mitochondrial Ca2+ influx and efflux rates in guinea pig cardiac mitochondria: Low and high affinity effects of cyclosporine A. Biochim. Biophys. Acta 2011, 1813, 1373–1381. [Google Scholar] [CrossRef] [Green Version]
  118. Cherok, E.; Xu, S.; Li, S.; Das, S.; Meltzer, W.A.; Zalzman, M.; Karbowski, M. Novel regulatory roles of MFF and Drp1 in E3 ubiquitin ligase MARCH5–dependent degradation of MiD49 and Mcl1 and control of mitochondrial dynamics. Mol. Biol. Cell 2017, 28, 396–410. [Google Scholar] [CrossRef]
  119. Sørensen, D.M.; Holemans, T.; van Veen, S.; Martin, S.; Arslan, T.; Haagendahl, I.W.; Vangheluwe, P. Parkinson disease related ATP13A2 evolved early in animal evolution. PLoS ONE 2018, 13, e0193228. [Google Scholar] [CrossRef] [Green Version]
  120. Nasca, A.; Scotton, C.; Zaharieva, I.; Neri, M.; Selvatici, R.; Magnusson, O.T.; Pane, M. Recessive mutations in MSTO1 cause mitochondrial dynamics impairment, leading to myopathy and ataxia. Hum. Mutat. 2017, 38, 970–977. [Google Scholar] [CrossRef] [Green Version]
  121. Gal, A.; Balicza, P.; Weaver, D.; Naghdi, S.; Joseph, S.K.; Várnai, P.; Molnar, M.J. MSTO 1 is a cytoplasmic pro-mitochondrial fusion protein, whose mutation induces myopathy and ataxia in humans. EMBO Mol. Med. 2017, 9, 967–984. [Google Scholar] [CrossRef] [PubMed]
  122. Ondovcik, S.L.; Tamblyn, L.; McPherson, J.P.; Wells, P.G. Oxoguanine glycosylase 1 (OGG1) protects cells from DNA double-strand break damage following methylmercury (MeHg) exposure. Toxicol. Sci. 2012, 128, 272–283. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  123. Gadhia, S.R.; Calabro, A.R.; Barile, F.A. Trace metals alter DNA repair and histone modification pathways concurrently in mouse embryonic stem cells. Toxicol. Lett. 2012, 212, 169–179. [Google Scholar] [CrossRef] [PubMed]
  124. Ryu, H.W.; Lee, D.H.; Won, H.R.; Kim, K.H.; Seong, Y.J.; Kwon, S.H. Influence of toxicologically relevant met als on human epigenetic regulation. Toxicol. Res. 2015, 31, 1–9. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  125. Wyatt, L.H.; Luz, A.L.; Cao, X.; Maurer, L.L.; Blawas, A.M.; Aballay, A.; Meyer, J.N. Effects of methyl and inorganic mercury exposure on genome homeostasis and mitochondrial function in Caenorhabditis elegans. DNA Repair 2017, 52, 31–48. [Google Scholar] [CrossRef] [Green Version]
  126. Onishchenko, N.; Karpova, N.; Sabri, F.; Castrén, E.; Ceccatelli, S. Long-lasting depression-like behavior and epigenetic changes of BDNF gene expression induced by perinatal exposure to methylmercury. J. Neurochem. 2008, 106, 1378–1387. [Google Scholar] [CrossRef]
  127. Gaudet, M.; Pietrini, F.; Beritognolo, I.; Iori, V.; Zacchini, M.; Massacci, A.; Sabatti, M. Intraspecific variation of physiological and molecular response to cadmium stress in Populus nigra L. Tree Physiol. 2011, 31, 1309–1318. [Google Scholar] [CrossRef] [Green Version]
  128. Yang, S.H.; Sharrocks, A.D. PIASx acts as an Elk-1 coactivator by facilitating derepression. EMBO J. 2005, 24, 2161–2171. [Google Scholar] [CrossRef] [Green Version]
  129. Chowdhury, D.; Singh, A.; Gupta, A.; Tulsawani, R.; Meena, R.C. Chakrabarti, Ap38 MAPK pathway-dependent SUMOylation of Elk-1 and phosphorylation of PIAS2 correlate with the downregulation of Elk-1 activity in heat-stressed HeLa cells. Cell Stress Chaperones 2019, 24, 393–407. [Google Scholar] [CrossRef]
  130. Hou, Y.; Liu, W.; Yi, X.; Yang, Y.; Su, D.; Huang, W.; Yu, H.; Teng, X.; Yang, Y.; Feng, W.; et al. PHF20L1 as a H3K27me2 reader coordinates with transcriptional repressors to promote breast tumorigenesis. Sci. Adv. 2020, 6, eaaz0356. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  131. Nefedova, Y.; Gabrilovich, D.I. Targeting of Jak/STAT pathway in antigen presenting cells in cancer. Curr. Cancer Drug Targets 2007, 7, 71–77. [Google Scholar] [CrossRef]
  132. Rytinki, M.M.; Kaikkonen, S.; Pehkonen, P.; Jääskeläinen, T.; Palvimo, J.J. PIAS proteins: Pleiotropic interactors associated with SUMO. Cell. Mol. Life Sci. 2009, 66, 3029. [Google Scholar] [CrossRef] [PubMed]
  133. Dumitriu, B.; Patrick, M.R.; Petschek, J.P.; Cherukuri, S.; Klingmuller, U.; Fox, P.L.; Lefebvre, V. Sox6 cell-autonomously stimulates erythroid cell survival, proliferation, and terminal maturation and is thereby an important enhancer of definitive erythropoiesis during mouse development. Blood 2006, 108, 1198–1207. [Google Scholar] [CrossRef] [PubMed]
  134. Wilber, A.; Nienhuis, A.W.; Persons, D.A. Transcriptional regulation of fetal to adult hemoglobin switching: New therapeutic opportunities. Blood 2011, 117, 3945–3953. [Google Scholar] [CrossRef] [Green Version]
  135. Shariati, L.; Rohani, F.; Heidari Hafshejani, N.; Kouhpayeh, S.; Boshtam, M.; Mirian, M.; Khanahmad, H. Disruption of SOX6 gene using CRISPR/Cas9 technology for gamma-globin reactivation: An approach towards gene therapy of β-thalassemia. J. Cell. Biochem. 2018, 119, 9357–9363. [Google Scholar] [CrossRef]
  136. Ancora, S.; Rossi, R.; Simplicio, P. In Vitro Study of Methylmercury in Blood of Bottlenose Dolphins (Tursiops truncatus). Arch. Environ. Contam. Toxicol. 2002, 42, 348–353. [Google Scholar] [CrossRef]
  137. Matte, A.; Bertoldi, M.; Mohandas, N.; An, X.; Bugatti, A.; Brunati, A.M.; Perrotta, S. Membrane association of peroxiredoxin-2 in red cells is mediated by the N-terminal cytoplasmic domain of band 3. Free Radic. Biol. Med. 2013, 55, 27–35. [Google Scholar] [CrossRef]
  138. Spiller, H.A. Rethinking mercury: The role of selenium in the pathophysiology of mercury toxicity. Clin. Toxicol. 2018, 56, 313–326. [Google Scholar] [CrossRef]
  139. Jeong, K.H.; Jung, J.H.; Kim, J.E.; Kang, H. Prostaglandin D2-mediated DP2 and AKT signal regulate the activation of androgen receptors in human dermal papilla cells. Int. J. Mol. Sci. 2018, 19, 556. [Google Scholar] [CrossRef] [Green Version]
  140. Reischl, E.; Dafre, A.L.; Franco, J.L.; Wilhelm-Filho, D. Distribution, adaptation and physiological meaning of thiols from vertebrate hemoglobins. Comp. Biochem. Phys. C 2007, 146, 22–53. [Google Scholar] [CrossRef]
  141. Lee, Y.J. Knockout Mouse Models for Peroxiredoxins. Antioxidants 2020, 9, 182. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  142. Jin, X.; Chen, C.; Li, D.; Su, Q.; Hang, Y.; Zhang, P.; Hu, W. PRDX2 in myocyte hypertrophy and survival is Mediated by TLR4 in Acute Infarcted Myocardium. Sci. Rep. 2017, 7, 6970. [Google Scholar] [CrossRef] [PubMed]
  143. Krivoruchko, A.; Storey, K.B. Forever young: Mechanisms of natural anoxia tolerance and potential links to longevity. Oxid. Med. Cell Longev. 2010, 3, 1–13. [Google Scholar] [CrossRef] [PubMed]
  144. Won, E.J.; Kim, R.O.; Rhee, J.S.; Park, G.S.; Lee, J.; Shin, K.H.; Lee, J.S. Response of glutathione S-transferase (GST) genes to cadmium exposure in the marine pollution indicator worm, Perinereis nuntia. Comp. Biochem. Physiol. Part C Toxicol. Pharmacol. 2011, 154, 82–92. [Google Scholar] [CrossRef] [PubMed]
  145. Won, E.J.; Rhee, J.S.; Kim, R.O.; Ra, K.; Kim, K.T.; Shin, K.H.; Lee, J.S. Susceptibility to oxidative stress and modulated expression of antioxidant genes in the copper-exposed polychaete Perinereis nuntia. Comp. Biochem. Physiol. Part C Toxicol. Pharmacol. 2012, 155, 344–351. [Google Scholar] [CrossRef] [PubMed]
  146. Franco, A.A.; Odom, R.S.; Rando, T.A. Regulation of antioxidant enzyme gene expression in response to oxidative stress and during differentiation of mouse skeletal muscle. Free Radic. Biol. Med. 1999, 27, 1122–1132. [Google Scholar] [CrossRef]
  147. Zhang, H.C.; Yang, Y.J.; Ma, K.X.; Shi, C.Y.; Chen, G.W.; Liu, D.Z. A novel sigma class glutathione S-transferase gene in freshwater planarian Dugesia japonica: Cloning, characterization and protective effects in herbicide glyphosate stress. Ecotoxicology 2020, 29, 295–304. [Google Scholar] [CrossRef]
  148. Reischl, E. High sulfhydryl content in turtle erythrocytes: Is there a relation with resistance to hypoxia? Comp. Biochem. Physiol. B 1986, 85, 723–726. [Google Scholar] [CrossRef]
Toxics 09 00070 g001 550
Figure 1. Experimental design. Five steps were carried out prior to sequencing by RNA-seq: (1) samples were obtained from five Caretta caretta turtles; (2) erythrocytes were isolated; (3) the bioassay was carried out; (4) RNA was extracted; and (5) samples were selected for sequencing according to the RNA integrity number (RIN).
Figure 1. Experimental design. Five steps were carried out prior to sequencing by RNA-seq: (1) samples were obtained from five Caretta caretta turtles; (2) erythrocytes were isolated; (3) the bioassay was carried out; (4) RNA was extracted; and (5) samples were selected for sequencing according to the RNA integrity number (RIN).
Toxics 09 00070 g001
Toxics 09 00070 g002 550
Figure 2. Venn diagram showing the genes of the loggerhead turtle, Caretta caretta, annotated to the databases Nr, KOG, KEGG, Swissprot, and Interpro.
Figure 2. Venn diagram showing the genes of the loggerhead turtle, Caretta caretta, annotated to the databases Nr, KOG, KEGG, Swissprot, and Interpro.
Toxics 09 00070 g002
Toxics 09 00070 g003 550
Figure 3. Quantification of transcripts of the loggerhead turtle, Caretta caretta, for each of the samples evaluated according to their high (FPKM > 10), medium (FPKM between 1–10), and low (FPKM < 1) abundance.
Figure 3. Quantification of transcripts of the loggerhead turtle, Caretta caretta, for each of the samples evaluated according to their high (FPKM > 10), medium (FPKM between 1–10), and low (FPKM < 1) abundance.
Toxics 09 00070 g003
Toxics 09 00070 g004 550
Figure 4. MA plots and heat maps representing the differentially expressed genes in the transcriptome of the loggerhead turtle, Caretta caretta. (A,B) Gc vs. Gs1, (C,D) Gs1 vs. Gs5, (E,F) Gc vs. Gs5.
Figure 4. MA plots and heat maps representing the differentially expressed genes in the transcriptome of the loggerhead turtle, Caretta caretta. (A,B) Gc vs. Gs1, (C,D) Gs1 vs. Gs5, (E,F) Gc vs. Gs5.
Toxics 09 00070 g004
Toxics 09 00070 g005 550
Figure 5. Venn diagrams indicating the number of genes differentially expressed in the transcriptome of the loggerhead turtle, Caretta caretta. (A) Upregulated genes and (B) downregulated genes in erythrocytes exposed in vitro to doses of 0, (Gc), 1 (Gs1), and 5 (Gs5) mg L−1 of MeHg for 12 h.
Figure 5. Venn diagrams indicating the number of genes differentially expressed in the transcriptome of the loggerhead turtle, Caretta caretta. (A) Upregulated genes and (B) downregulated genes in erythrocytes exposed in vitro to doses of 0, (Gc), 1 (Gs1), and 5 (Gs5) mg L−1 of MeHg for 12 h.
Toxics 09 00070 g005
Toxics 09 00070 g006 550
Figure 6. Distribution by categories of the GO classification of the 83 differentially expressed genes (DEGs). The number of unigenes in each category is shown.
Figure 6. Distribution by categories of the GO classification of the 83 differentially expressed genes (DEGs). The number of unigenes in each category is shown.
Toxics 09 00070 g006
Toxics 09 00070 g007 550
Figure 7. KEGG pathway functional enrichment of DEGs. The x-axis shows the enrichment factor. The y-axis shows pathway name. Point size indicates DEG number (the bigger dots refer to larger amounts); the larger the value, the more significant the enrichment. The color represents the q-value (high: white, low: blue), a lower q-value indicates a more significant enrichment. (A) Comparison between Gc and Gs1, (B) comparison between Gs1 and Gs5, (C) comparison between Gc and Gs5.
Figure 7. KEGG pathway functional enrichment of DEGs. The x-axis shows the enrichment factor. The y-axis shows pathway name. Point size indicates DEG number (the bigger dots refer to larger amounts); the larger the value, the more significant the enrichment. The color represents the q-value (high: white, low: blue), a lower q-value indicates a more significant enrichment. (A) Comparison between Gc and Gs1, (B) comparison between Gs1 and Gs5, (C) comparison between Gc and Gs5.
Toxics 09 00070 g007
Toxics 09 00070 g008 550
Figure 8. Correlation between the enzymatic activity of GST, SOD, and the concentration of MDA (μM) produced by lipid peroxidation with the relative expression (FPKM) of the genes in the loggerhead turtle, exposed to MeHg. (A) TBXAS1 with MDA (µM), (B) GST with GST activity, (C) Cu/Zn-SOD with Cu/Zn-SOD activity, (D) Mn-SOD with Mn-SOD activity.
Figure 8. Correlation between the enzymatic activity of GST, SOD, and the concentration of MDA (μM) produced by lipid peroxidation with the relative expression (FPKM) of the genes in the loggerhead turtle, exposed to MeHg. (A) TBXAS1 with MDA (µM), (B) GST with GST activity, (C) Cu/Zn-SOD with Cu/Zn-SOD activity, (D) Mn-SOD with Mn-SOD activity.
Toxics 09 00070 g008
Toxics 09 00070 g009 550
Figure 9. Relative gene expression (FPKM) in loggerhead turtle RBCs in different metabolic pathways. (A) cysteine-methionine metabolism, (B) metabolism of glutathione, (C) metabolism of selenocompounds, and (D) metabolism of peroxiredoxins.
Figure 9. Relative gene expression (FPKM) in loggerhead turtle RBCs in different metabolic pathways. (A) cysteine-methionine metabolism, (B) metabolism of glutathione, (C) metabolism of selenocompounds, and (D) metabolism of peroxiredoxins.
Toxics 09 00070 g009
Table
Table 1. Metric and quality of each of the individual samples, the three experimental groups (Gc, Gs1, and Gs5), and the complete transcriptomes of the loggerhead sea turtle, Caretta caretta.
Table 1. Metric and quality of each of the individual samples, the three experimental groups (Gc, Gs1, and Gs5), and the complete transcriptomes of the loggerhead sea turtle, Caretta caretta.
Number of SampleTotal ReadsTotal Mapped Reads (%)Total TranscriptsTotal UnigensMean LengthN50GC (%)
T1 (Gc)109,774,60497,540,538 (88.6)81,39358,734994262845.91
T2 (Gs1)110,446,772100,239,446 (90.8)61,22345,142840182846.86
T3 (Gs5)110,594,62699,324,656 (89.8)81,16658,5641007263546.87
T4 (Gc)110,454,33099,989,030 (90.5)72,52552,9711029259547.23
T5 (Gs1)110,371,76099,933,436 (90.5)64,04346,634893199646.81
T6 (Gs5)110,372,54699,562,082 (90.2)77,55356,3421045267646.7
T7 (Gc)95,337,75086,401,432 (90.6)67,86550,433945229946.62
T8 (Gs1)110,614,80099,565,396 (90)78,14775,972873208646.76
T9 (Gs5)110,518,91098,688,182 (89.3)85,83353,625878219447
T10 (Gc)110,441,52496,624,438 (87.4)108,05775,428820211047.03
T11 (Gs1)110,489,32699,737,464 (90.3)73,54358,734883212947.13
T12 (Gs5)110,350,19696,400,760 (87.4)108,08245,142800203547.2
Gc (T1,T4,T7,T10)120,987,09895,049136,90295,2261125262947
Gs1 (T2,T5,T8,T11)115,823,56171,272101,26571,3811025219947
Gs5 (T3,T6,T9,T12)123,812,26399,625148,03299,8091110261647
T. Total (all)165,092,512--------------192,065121,9331444352046.98
Table
Table 2. Statistics of the annotation of the composite transcriptome of the loggerhead turtle, Caretta caretta, with the number of transcripts that have at least one match with one of the evaluated databases. Some transcripts had multiple annotation results.
Table 2. Statistics of the annotation of the composite transcriptome of the loggerhead turtle, Caretta caretta, with the number of transcripts that have at least one match with one of the evaluated databases. Some transcripts had multiple annotation results.
Data BaseNumberPercentage
Nr52,86643.4
Nt69,05056.6
SwissProt43,99436.1
KEGG44,76836.7
KOG39,73332.6
InterPro38,21431.3
GO15,54012.7
In all databases 11,6939.6
In five databases32,46744.8
General72,70059.6
BlastN (Caretta caretta)110,84690.9
BlastX (Testudines)97,54680.5
No annotation information11,0879.1
Match with at least one database110,84690.9
Total121,933100
Table
Table 3. Top 25 annotations for the gene ontology of differentially expressed unigenes in loggerhead turtle erythrocytes from the Gc–Gs1, Gs1–Gs5, and Gc–Gs5 comparisons. Upregulated genes (≥1 fold) and downregulated genes (≤−1 fold, p-value < 0.01) are shown.
Table 3. Top 25 annotations for the gene ontology of differentially expressed unigenes in loggerhead turtle erythrocytes from the Gc–Gs1, Gs1–Gs5, and Gc–Gs5 comparisons. Upregulated genes (≥1 fold) and downregulated genes (≤−1 fold, p-value < 0.01) are shown.
DECellular FunctionsGen IDGc–Gs1ProcessLog2FCp-value
Gc–Gs1Stress response, transcription regulator activity, apoptotic processCL8320.Contig19_AllSGK1Stress response, regulation of DNA binding transcription, apoptosis inhibitor1.665.53 × 10−6
Stress response, autophagyCL2170.Contig3_AllATG5Nitrosative stress response, negative regulation of ROS, autophagic vesicle formation7.179.83 × 10−27
Stress responseCL5255.Contig3_AllGDP1Oxidative stress5.252.54 × 10−12
Metabolic processCL180.Contig4_AllHEX_ADegradation of GM2 gangliosides4.921.72 × 10−11
Metabolic processCL192.Contig4_AllMAMBBeta-mannosidase activity5.571.47 × 10−14
MiscellaneousUnigene13252_AllAP4B1Transport of proteins through vesicles to the golgi apparatus and lysosomes−4.292.44 × 10−8
Metabolic processCL1354.Contig17_AllGALNSProduction of an enzyme called N-acetylgalactosamine 6-sulfatase in lysosomes−5.351.08 × 10−13
Regulation of cell cycleCL860.Contig14_AllUHRF2Positive regulation of cell cycle. Proteins marked for destruction2.043.17 × 10−9
SignalingUnigene60990_AllATP13ACellular calcium homeostasis−4.784.05 × 10−10
Regulation of cell cycleCL2504.Contig1_AllMSTO1Regulation of the assembly of mitotic use1.821.75 × 10−5
Transcription regulator activityCL6965.Contig4_AllZNF280DRNA polymerase II cis-regulatory region sequence-specific DNA binding−4.493.61 × 10−9
Transcription regulator activityCL8179.Contig18_AllPHF20LRegulator of transcription, gene silencing−3.373.08 × 10−6
Transcription regulator activityCL439.Contig33_AllZC3H7APosttranscriptional regulation of gene expression, microRNAs and gene silencing−3.770.00651
Transcription regulator activityCL7143.Contig1_AllPIAS2Gene silencing, transcriptional co-regulation in various cell pathways−5.362.14 × 10−13
Transcription regulator activityCL919.Contig15_AllSOX6Regulatory transcription, related to neurogenesis and chondrogenesis−5.191.61 × 10−11
Gs1–Gs5Stress responseCL2659.Contig5_AllMkNk1Response to environmental stress and cytokines4.341.29 × 10−10
Stress responseCL1021.Contig3_AllZDHHC16Response to stress caused by DNA damage3.417.73 × 10−6
Stress responseCL3160.Contig8_AllKPNA6Positive regulation of cytokine production involved in inflammatory response−3.496.59 × 10−6
Stress responseCL2820.Contig3_AllCEP250Transition from G2/M during mitosis1.123.83 × 10−6
Metal ion bindingCL4894.Contig1_AllSLC38A9Transmembrane amino acid transporter activity−3.451.71 × 10−7
DNA repairUnigene7038_AllSPATAN1DNA repair3.317.75 × 10−6
MitochondriaCL1658.Contig16_AllMFFMitochondrial fission3.719.16 × 10−7
Transcription regulatorCL7143.Contig1_AllPIAS2Gene silencing; transcriptional coregulator in various cellular pathways3.681.59 × 10−6
Gc–Gs5Transcription regulatorCL1836.Contig1_AllCTBP1Regulation of RNA polymerase II, transcription corepressor activity, binding factor3.92.36 × 10−8
Log2FC: log2 fold change, positive values represent upregulated genes; negative values represent downregulated genes.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Hernández-Fernández, J.; Pinzón-Velasco, A.; López, E.A.; Rodríguez-Becerra, P.; Mariño-Ramírez, L. Transcriptional Analyses of Acute Exposure to Methylmercury on Erythrocytes of Loggerhead Sea Turtle. Toxics 2021, 9, 70. https://0-doi-org.brum.beds.ac.uk/10.3390/toxics9040070

AMA Style

Hernández-Fernández J, Pinzón-Velasco A, López EA, Rodríguez-Becerra P, Mariño-Ramírez L. Transcriptional Analyses of Acute Exposure to Methylmercury on Erythrocytes of Loggerhead Sea Turtle. Toxics. 2021; 9(4):70. https://0-doi-org.brum.beds.ac.uk/10.3390/toxics9040070

Chicago/Turabian Style

Hernández-Fernández, Javier, Andrés Pinzón-Velasco, Ellie Anne López, Pilar Rodríguez-Becerra, and Leonardo Mariño-Ramírez. 2021. "Transcriptional Analyses of Acute Exposure to Methylmercury on Erythrocytes of Loggerhead Sea Turtle" Toxics 9, no. 4: 70. https://0-doi-org.brum.beds.ac.uk/10.3390/toxics9040070

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop