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Article

Comprehensive Analysis of the Cadmium Tolerance of Abscisic Acid-, Stress- and Ripening-Induced Proteins (ASRs) in Maize

National Key Laboratory of Crop Genetics and Germplasm Enhancement, College of Life Sciences, Nanjing Agricultural University, Nanjing 210095, China
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Int. J. Mol. Sci. 2019, 20(1), 133; https://0-doi-org.brum.beds.ac.uk/10.3390/ijms20010133
Submission received: 8 December 2018 / Revised: 21 December 2018 / Accepted: 25 December 2018 / Published: 1 January 2019
(This article belongs to the Special Issue Ion Transporters and Abiotic Stress Tolerance in Plants)

Abstract

:
In plants, abscisic acid-, stress-, and ripening-induced (ASR) proteins have been shown to impart tolerance to multiple abiotic stresses such as drought and salinity. However, their roles in metal stress tolerance are poorly understood. To screen plant Cd-tolerance genes, the yeast-based gene hunting method which aimed to screen Cd-tolerance colonies from maize leaf cDNA library hosted in yeast was carried out. Here, maize ZmASR1 was identified to be putative Cd-tolerant through this survival screening strategy. In silico analysis of the functional domain organization, phylogenetic classification and tissue-specific expression patterns revealed that maize ASR1 to ASR5 are typical ASRs with considerable expression in leaves. Further, four of them were cloned for testifying Cd tolerance using yeast complementation assay. The results indicated that they all confer Cd tolerance in Cd-sensitive yeast. Then they were transiently expressed in tobacco leaves for subcellular localization analysis and for Cd-challenged lesion assay, continuously. The results demonstrated that all 4 maize ASRs tested are localized to the cell nucleus and cytoplasm in tobacco leaves. Moreover, they were confirmed to be Cd-tolerance genes in planta through lesion analysis in Cd-infiltrated leaves transiently expressing them. Taken together, our results demonstrate that maize ASRs play important roles in Cd tolerance, and they could be used as promising candidate genes for further functional studies toward improving the Cd tolerance in plants.

1. Introduction

Cadmium (Cd) not only negatively affects plant growth and development, but also for the human health hazards as the toxic elements usually accumulate in the consumable parts of crop plants [1,2,3,4]. Being a nonessential metal, Cd interferes with many cellular functions leading to retardation of plant growth, leaf chlorosis and a decrease in photosynthesis rate, resulting in the diminished water and nutrient uptake [5].
The mechanisms for plants to alleviate Cd stress vary from exclusion, compartmentation, and the synthesis of stress-related proteins [3,6]. Although some progresses have been made in exploring the genes associated with Cd detoxification and tolerance, the underlying molecular mechanisms of Cd tolerance in crops require further elucidation through analysis of novel candidate genes.
The plant-specific ABA-stress-ripening (ASR) gene family is well established for its response to ABA and multiple abiotic stresses, including drought, salinity as well as Al exposure [7,8,9]. ASR proteins are exclusive to the plant kingdom (albeit absent in Arabidopsis), and they play crucial roles in abiotic stress tolerance in most plants, as observed for OsASR1, ZmASR1, and TaASR1 [10,11,12,13].
A plethora of studies on the heterologous and homologous expression of ASR genes in plant species were reported for functional characterization of the positive roles of plant ASRs in adaption to abiotic stresses. Overexpression of rice ASRs (OsASR1 and OsASR3) and OsASR2 in rice enhanced drought/salt tolerance and disease resistance/drought tolerance, respectively [14,15]. Heterologous expression of wheat TaASR1, foxtail millet (Setaria italica) SiASR1 and SiASR4, confer drought tolerance in transgenic plants through regulating the antioxidant system [16,17,18], as was the case for overexpression of Brachypodium distachyon BdASR1 in tobacco [19]. Akin to the performance of aforementioned cereal ASRs, overexpression of banana ASR (MaASR) in Arabidopsis, Salicornia brachiata SbASR1 in groundnut, and soybean ASR in hairy roots enhanced drought and/or salt tolerance [20,21,22]. Tomato plants overexpressing ASR1 displayed tolerance to water stress, whereas ASR1-antisense plants sensitive to water stress [23]. Plantain (Musa paradisiaca) MpASR protein may act as an osmoprotectant and water-retaining molecule to help cell adjustment to osmotic stress in transgenic Arabidopsis [24]. Similarly, lily ASR may act as an osmoprotectant as well as a transcription factor to confer the enhanced resistance against cold and freezing in transgenic Arabidopsis plants [25].
ASRs are dual target proteins that participate as chaperones in the cytoplasm and as transcription factors in the nucleus [11]. In maize, ZmASR1 acts both as a transcriptional regulator and as a chaperone-like protein [13]. Rice transcription factor ASR5, the ZmASR1 ortholog, plays multiple roles in response to drought stress by regulating ABA biosynthesis, promoting stomatal closure, as well as acting as chaperone-like protein that possibly prevents drought stress-related proteins from inactivation [7].
It has been well established that some ASR proteins are known to be modulated by binding to metal ions [16]. Most ASR proteins have been shown to possess a zinc-binding domain [17,26]. Tomato ASR1 affects plant metabolism by its dual activity as a chaperone-like protein in the cytosol and as a transcription factor in the nucleus after acquiring its quaternary structure upon addition of Zn2+ [27,28,29], and similar results of Zn-induced structural transition were observed for HvASR1 and TtASR1 [30]. Intriguingly, soybean GmASR protects against oxidation damage by buffering metal ions, thus alleviating metal toxicity in plant cells under stressed conditions [16]. Rice ASR1 and ASR5, co-localized in nuclei and cytoplasm, are complementary transcription factors regulating Al-responsive genes to provide Al tolerance in rice [11,23,24,31].
Although these studies have unraveled the roles of ASRs in abiotic stress tolerance in plants, very limited information is available on ASRs that regulate the heavy metal detoxification and tolerance. Most ASR proteins have been shown to possess a zinc-binding domain [17,26], and plant ASRs can buffer metal ions [16,32]. Cd exhibits high chemical similarity with Zn and its uptake occurs through transporters engaged in the uptake of Zn [33]. Therefore, it is of particular interest to characterize ASRs in Cd tolerance. In the current study, based on the preliminary identification of Cd-tolerance related ZmASR1 through survival screening of yeast cDNA expression library clones, four maize ASR members were cloned and testified for Cd tolerance using yeast complementation assay. Then they are transiently expressed in tobacco leaves for subcellular localization assay and Cd challenged tobacco lesion analysis, continuously. Comprehensive elucidation of these ASR genes associated with Cd tolerance in maize will pave the way for future studies aimed at unveiling the molecular mechanisms involved in regulating Cd tolerance.

2. Results

2.1. Candidate Cd Tolerance Gene ZmASR1 Isolated from the Maize cDNA Library

Yeast-based functional gene hunting is a powerful tool for identifying genes associated with stress tolerance [34]. Particularly, Cd tolerant genes can be identified through rescue assay by expressing cDNA library in Cd-sensitive yeast mutant Δycf1 [35,36,37].
To identify novel plant genes that confer Cd tolerance, a maize leaf cDNA library used for yeast two-hybrid assay was utilized directly for screening. Approximately 104 yeast colonies were screened, and a series of colonies survived in the presence of 100 μM CdCl2 and the respective inserts in the library vector were sequenced. Among the putative Cd-tolerance genes output by this shotgun approach, a transcript of particular interest displayed a high homology to GRMZM2G136910, which is annotated to be stress-responsive ZmASR1 (Abscisic Acid, Stress and Ripening protein). Further sequence analysis showed that this Cd-tolerant clone contained the complete CDS of ZmASR1 (Supplementary File 1), implying that this cDNA library is suitable to screen the Cd-tolerant ZmASR1 with full-length CDS.

2.2. Sequence Analysis of Maize ZmASR Genes

Nine ZmASR genes were identified in the maize genome previously, based on the presence of abscisic acid (ABA)/water deficit stress (WDS) signature [13], and they were named aasr1 through aasr9 in the latest version of maizeGDB [38] (https://maizegdb.org). In addition, GRMZM2G009792 encoding ABA/WDS domain protein with peptide evidence [38,39] (https://maizegdb.org) was designated as asr10 in the current study. Multiple amino acid sequence alignment and phylogenetic relationships of the maize ASRs and their homologs indicated that ASR1, ASR3, ASR4, and ASR2, were related to rice OsASR5, OsASR4, OsASR6, and barley HvASR1, respectively, while ASR5 and ASR6 showed high homologous to rice OsASR3 (Figure 1A).
ZmASR1 to ZmASR3 protein contained conserved ABA/WDS domains and bipartite nuclear localization signals. With the exception of ZmASR3, ZmASR4 and asr10, all of the maize ASRs contained a small N-terminal consensus containing a stretch of six His residues which was typical for Zn-binding [12,17,26] (Figure 1B).

2.3. Expression Patterns of ZmASR Genes

To investigate the potential functions of the ZmASR genes, the expression profiles of the ZmASR family members were generated using RNAseq data of three tissues (root, stem, and leaf) from maize gene expression omnibus (http://qteller.com) (Figure 2A, Supplementary Table S1). Basically, ZmASR genes can be categorized into two groups according to their expression patterns in different tissues.
The highest expression of ZmASR6 to ZmASR9 was less than 50 FPKM (fragments per kilobase transcript per million reads mapped), and asr10 < 100 FPKM, whereas those of ZmASR1 to ZmASR4 were more than 500 FPKM in the investigated tissues (Figure 2A, Supplementary Table S1). Consistent with this, proteomic analysis through 2-DE condition allowed the identification of these 5 maize ASRs [13]. However, a close examination of the genomic structure of ZmASR3 revealed the presence of cis-NAT (cis-natural antisense transcript) GRMZM5G806182 transcribed from the opposite strand [38] (https://maizegdb.org), implying the complexity of ZmASR3 locus. Therefore, four ASR members (ZmASR1 to ZmASR5 except ZmASR3) were selected for further analysis.
To gain insight into the functional significance of these 4 ASRs in Cd stress acclimation, we further explored the expression pattern of them after Cd treatment in maize leaves using qRT-PCR. A significant increase in the expression of ASRs was observed after 3 h of Cd treatment, and their expression was kept at a relatively high level in comparison with the untreated plants during the 12 h of Cd stress (Figure 2B).

2.4. Confirmation That Maize ASRs Confer Cd Tolerance in Cd-Sensitive Yeast Mutant

To avoid the Cd-tolerance achieved from co-transformation with multiple different genes in yeast during the library screening mentioned above, we reconstructed the CDS sequence of ZmASR1 into the yeast expression vector pYES2 and retransformed to Cd-sensitive yeast Δycf1 cells to test whether ZmASR1 can complement Δycf1 phenotype, thus confirming its functionality of Cd-tolerance identified by gene-hunting method. To investigate whether other ASRs hold the similar function, ZmASR2 to ZmASR5 except the neglected ZmASR3 were cloned and evaluated their functionality of Cd-tolerance in yeast.
The results showed that both Δycf1 strains expressing the ZmASRs and the pYES2 empty vector (EV) grew well under non-stressed conditions. However, the dilution spot tests showed that Δycf1 cells expressing ZmASRs exhibited dramatically enhanced growth when they were compared with Δycf1 cells transformed with EV on half-strength SG agar medium supplemented with 100 μM CdCl2. The growth of Δycf1 cells expressing ZmASRs were even better than that of wild-type yeast cells transformed with EV under Cd stress. Moreover, the Δycf1 mutant transformed with ZmASRs constructs were able to survive at different dilutions whereas the growth of control was arrested (Figure 3). These data indicated that ZmASR1 to ZmASR5 except ZmASR3 confer Cd-tolerance in yeast, though ASR5 exhibited weak Cd-tolerance in yeast.

2.5. Transient Expression of Maize ASRs Conferred Cd Tolerance in Tobacco

ZmASR1 to ZmASR3 harbored bipartite nuclear localization signal [13], and they were predicted to be localized to nucleus by Protcomp-PL (http://www.softberry.com/cgi-bin/programs/proloc/protcomppl.pl). To further study the functions of the maize ASR genes in response to Cd stress in planta, we currently focused on the characterization of ZmASR1 to ZmASR5 except ZmASR3, and a transient expression assay was performed with the ZmASR-GFP fusion protein in tobacco leaves. The results indicated that these four ASR-GFP fusion proteins were broadly distributed in the nucleus and cytoplasm (Figure 4A).
To further assess the functional relevance of these 4 maize ASRs in planta against Cd stress, tobacco leaves transiently expressing them were treated by infiltrating Cd solution, and the leaf regions transiently expressing empty vector (EV) were used as control. The EV transformed control regions showed obvious chlorosis and lesions 4 d after Cd treatment, indicative of a symptom of Cd toxicity. However, lesions on leaves transiently expressing ZmASR were significantly smaller than those on leaves expressing EV post Cd inoculation (Figure 4B). Therefore, these results suggested that transient expression of maize ASR also conferred Cd tolerance in tobacco cells.

3. Discussion

3.1. Maize ASRs Function in Cd-Tolerance

Some poaceae ASR members, including maize ASR1 and rice OsASR5, are the most prevalent ASR proteins in major plant tissues, and large-scale quantitative proteomics studies only revealed ASR1 to ASR5 in maize leaves [42,43]. Interestingly, maize ASR1, encoded by one of the most highly expressed ZmASR genes, was the most abundant detected ASR protein in maize leaves [13]. In the current research, among the 10 ASR isoforms, only ASR1 was easily identified to be Cd tolerant through survival screening of the maize leaf cDNA library hosted in yeast (Supplementary File 1). Moreover, the ectopic expression of maize ASRs including ASR1 enhanced Cd tolerance in both tobacco leaves and yeast (Figure 3 and Figure 4). Several studies on the heterologous and homologous expression of ASR genes in plant species have suggested that ASRs increase abiotic stress tolerance, as observed for OsASR1, ZmASR1, TaASR1 and SiASR4 [1,12,13,17]. These together strengthened the positive roles of plant ASRs in adaption to abiotic stresses.
However, the study on ASRs that respond to ions or regulate the heavy metal detoxification and tolerance is in its infancy. It was speculated that the expression of GmASR might be upregulated to buffer the concentration of Zn2+, thus alleviating metal toxicity in plant cells under stressed conditions [16]. These implicated that the functions of some ASR proteins are known to be modulated by binding to metal ions [16].
In the current study, ZmASR1 was identified to be putative Cd-tolerant by yeast based-gene hunting approach. Then the maize paralogs of ASR1 were cloned and subjected to Cd-tolerance investigation, and the results showed that the ectopic expression of maize ZmASR2 to ZmASR5 except ZmASR3 enhanced Cd tolerance in yeast (Figure 3). Moreover, the selected 4 maize ASR members of ASR1 through ASR5 conferred Cd-tolerance in tobacco via transient expression assay (Figure 4B).
This is reminiscent of soybean GmASR alleviating metal toxicity [16] and rice ASR1 (Os02g33820) together with ASR5 (Os11g06720) regulating Al responsive genes [11]. GmASR protects against oxidation damage by buffering metal ions, thus alleviating metal toxicity in plant cells under stressed conditions [16], while rice transcription factors ASR1 and ASR5 act in concert and complementarily to regulate Al responsive genes, and participate as chaperones in the cytoplasm by virtue of dual target proteins [11]. Notably, the Cd-tolerant ZmASR1 and ZmASR5 were closely related to the coupled rice ASR5 and ASR1 involving in Al-tolerance, respectively (Figure 1A), raising the interesting possibility that ZmASR1 and ZmASR5 act synergistically to facilitate the Cd-tolerance. A better understanding of the coordinated roles of these maize ASR genes in stress acclimation will require more exhaustive exploration of their targets and their chaperone-like activities using the genetic engineering plants subjected to metal pressure.
Interestingly, rice ASR (Os11g06720, the above-mentioned ASR5) with reactive oxygen species (ROS) scavenging and chaperone-like activities enhances acquired tolerance to abiotic stresses through induction of various cell rescue proteins in yeast cells [44]. In the present study, the Cd-tolerant ZmASR1 identified via yeast rescue screening displayed high identity to the aforementioned dual-function rice ASR5 (Os11g06720) (Figure 1A). Analogously, a very likely explanation is that ZmASR1 acts as a transcription regulator modulating gene expression and a protective molecule under Cd stress. Further assays by means of physiological characterizing its transgenic plants might help to elucidate this point.

3.2. The Feature of Dual Targeting Determines the Multiple Function of ASRs

Most ASR proteins have been shown to possess a zinc-binding domain at the N-terminal end and a putative nuclear targeting signal at the C-terminal end [17,26]. However, ASRs display different subcellular localizations.
Some ASRs are dual target proteins that participate as chaperones in the cytoplasm and as transcription factors in the nucleus [11]. While some ASR proteins are found exclusively in the nucleus, where they act as transcription factors regulating gene expression during stress response, other ASR proteins are localized in both the nucleus and the cytosol, likely reflecting their diverse functions [17,19,30].
Zinc is an essential cofactor and is bound by proteins through coordination by the amino acids His, Asp, Glu and Cys. Intriguingly, these zinc coordinating residues except Cys appear in high copies in ASRs [45]. Furthermore, the DNA binding of tomato SlASR1 is sequence specific and Zinc-dependent [32]. Wheat TaASR1 contains a N-terminal stretch of six His residues which is responsible for its transcriptional regulation activity, implying that TaASR1 may act as a transcription factor and bind to DNA in a Zn2+-dependent manner [12]. Another typical stretch (PEHAHKHK) with Zn2+-binding capacity was identified in barley HvASR1, durum wheat TtASR1 [30] and tomato SlASR1 [45]. It is noteworthy that these two motifs are also conserved in maize ASR1 and ASR2 (Figure 1B).
It was speculated that plant ASRs could buffer high Zn2+ concentrations that may accumulate in the cytoplasm under abiotic stress, giving time for cation-efflux transporters to restore the Zn2+ balance [32]. Cd exhibits high chemical similarity with functionally active ions situated in active sites of enzymes and signaling components, in particular Zn. Since Cd uptake occurs through transmembrane carriers engaged in the uptake of essential metallic elements (e.g., Ca, Fe, Mg, and Zn), it often induces mineral deficiencies by competing with the uptake of aforementioned essential elements [33]. From this perspective, it is of particular interesting to investigate whether Cd affects the activity of maize ASRs, the potential transcriptional regulator, and how ASRs regulate the divalent transporters responsible for the uptake of essential mineral elements.
Tomato ASR1, an intrinsically disordered protein (IDP), affects plant metabolism by its dual activity as a chaperone-like protein in the cytosol and as a transcription factor in the nucleus after acquiring its quaternary structure upon addition of Zn2+ [27,28,29,32]. Similar results of Zn-induced structural transition were observed for HvASR1 and TtASR1 [30]. In the current study, subcellular analysis indicated that ASR1, ASR2, ASR4 and ASR5 were distributed in cytoplasm and nucleus, which was consistent with the results in aforementioned literature.
The folding behavior determines the function of tomato ASR1 as one chaperone and/or transcription factor, and the binding of Zn2+ promotes its partial folding as an α-helix monomer, a prerequisite to bind its specific DNA sequence [32]. Tomato ASR1 may act as a transcription factor when adopting the adequate α-helix conformation, and its chaperone role is not affected by ASR1 structuring upon addition of Zn2+ [32]. Furthermore, Cd can replace Zn in proteins [2], and cadmium ions can induce the folding and dimerization of a designed metalloprotein [46]. Regarding the 4 dual-targeting maize ASRs, here we hypothesized that they function as transcription factors after the Zn analog Cd-binding promoted α-helix conformation, and as chaperones which behavior persist under Cd stress at micromolar concentrations of Cd ions. Further studies will be required to reveal the functional impact of the structural transitions that these proteins undergo in the presence of Cd, using the structural biological techniques reported previously [27,30,32], thus provide further insight into the precise character of ASR-mediated Cd-tolerance.

4. Materials and Methods

4.1. Isolation of Cd-Tolerance Genes from the Maize Leaf cDNA Library

For the identification of Cd tolerance genes, a maize leaf cDNA library constructed into pDEST22 hosted in Saccharomyces cerevisiae strain MaV203 for yeast two-hybrid assay (Invitrogen) [47] was utilized directly for screening. Colonies that grew on medium containing 100 μM CdCl2 were selected, and the pDEST22 plasmids carrying putative Cd-tolerance genes were isolated from these yeast cells and transformed to TOP10 Escherichia coli cells for sequencing the inserts (Invitrogen). The function annotation of the inserts sequence was performed following the description of the homologous genes output by the BlastX utility.
Then Cd tolerance function of the isolated plasmids was confirmed by repeating the transformation of the Δycf1 cells [37,48].

4.2. Maize Seedlings Cultivation and cDNA Synthesis for Cloning ASR

The seedlings of maize (Zea mays L. inbred line B73) were cultivated in a hydroponic system in a growth chamber and continuously aerated and renewed every 3 days. When the third leaves were fully expanded, the seedlings were transferred into fresh growing solutions containing 100 µM Cd(NO3)2. After 3, 6 and 12 h of Cd treatment, maize seedlings leaves were sampled for RNA isolation.
Total RNA was extracted from leaves using the RNAiso Plus (TaKaRa Bio Inc., Dalian, China) according to the manufacturer’s instructions. Approximately 2 µg of total RNA was reverse transcribed using oligo d(T)16 primer and M-MLV reverse transcriptase (TaKaRa). The synthesized cDNA was used for amplifying the coding sequences (CDS) of ASR.
The expression levels of maize ASRs were measured by qRT-PCR using a DNA Engine Opticon 2 real-time PCR detection system (Bio-Rad) with SYBR Premix Ex Taq (TaKaRa). The expression level of each target gene was normalized against that of ZmActin in maize.

4.3. Sequence Alignment and Phylogenetic Analysis

Multiple alignments of ASR protein sequences were carried out with ClustalW utility embedded in MEGA7 software (Tokyo Metropolitan University, Tokyo, Japan) [40]. Phylogenetic trees were constructed by the neighbor-joining (NJ) method using MEGA7 software and the bootstrap tests were performed with 1000 replications.

4.4. In Silico Expression Analysis

We perform in silico experiments using maize transcript profiles from qTeller (http://qteller.com), which hosted about 40 experiments from nine sources, and the data of three tissues (leaf, root and shoot) from five transcriptomic studies (Supplementary Table S1) were retrieved for analysis.

4.5. Yeast and Transient Plant Expression Vector Reconstruction

To avoid the Cd-tolerance achieved from co-transformation with multiple different genes in yeast, we subcloned the coding sequences of ZmASR1, together with other 4 maize ASRs, into the yeast expression vector pYES2 and binary vector pSuper1300-GFP with the primers listed in Table 1.

4.6. Cd Tolerance Complementation Assay in Cd-Sensitive Yeast

The ZmASRs recombinant plasmids and pYES2 empty vector (EV) were then transformed into Cd-sensitive yeast Δycf1 mutant cells using the lithium acetate/PEG transformation method, and the isogenic yeast wild-type BY4741 (MATa; ura3Δ0; leu2Δ0; his3Δ1; met15Δ0) [49] transformed with EV as positive control [50,51,52,53,54,55].
Yeast strains expressing EV or ZmASRs were pre-cultured in SD-Ura liquid medium to an optical density at 600 nm (OD600) of 1.0, and 10-μL of tenfold serial dilutions were spotted onto SD-Ura agar medium with or without 40 μM CdCl2 in the presence of 2% galactose. After incubation at 30 °C for 3 days, the growth of clones transformed with putative Cd-tolerance maize genes was compared with those transformed with the EV on the same plates supplied with Cd [37,52]. All drop-test experiments were independently repeated at least three times.

4.7. Agro-Infiltration and Cd Response in Tobacco Leaves

Agro-infiltration and Cd treatment assay was performed based on previous reports [4,54,55,56,57,58], with minor modifications. Agrobacterium tumefaciens strain GV3101 was transformed with ZmASRs constructs and then grown in Luria-Bertani culture medium supplemented with appropriate antibiotics. After 36–48 h, A. tumefaciens cells were spun down by centrifugation, and re-suspended in Agro-infiltration buffer (10 mM MgCl2 and 10 mM 2-(N-morpholino) ethanesulfonic acid (MES), pH 5.6). The re-suspended A. tumefaciens cells were diluted and mixed with P19 silencing suppressor in a 1:1 to a final OD600 = 0.3 for each construct before infiltrating into the leaves of 3–4 week-old tobacco (Nicotiana benthamiana) plants.
After 3 days of agro-infiltration, tobacco leaves transiently expressing ZmASRs-GFP fusion proteins were analyzed using confocal fluorescence microscopy to monitor transformation. For fluorescence observations, patches were cut from tobacco leaves 3 days after agro-infiltration and used for confocal imaging on a Zeiss LSM 710 confocal laser scanning microscope. RFP-H2A, localized in the nucleus, was used to mark the nuclei [41]. GFP fluorescence was excited by the 488 nm line of an argon laser, and emissions were detected between 500 and 530 nm. Simultaneously, the needle hole in the leaves expressing ZmASRs-GFP were re-infiltrated with 500 μM Cd(NO3)2. The infected leaves were photographed were measured at 4 days post-treatment.
Each experiment was repeated at least three times with a minimum of 10 infected leaves. Leaf regions transiently expressing EV were used as a control.

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/1422-0067/20/1/133/s1, Supplementary File 1 The sequence information of the Cd-tolerance clone isolated from the maize cDNA library. Supplementary Table S1. Expression profiles of maize ZmASR genes in different tissues.

Author Contributions

X.C., M.J. and M.T. planned and designed the research. J.Z., Q.Z., H.Y., L.L. and G.Z. performed the experiments, X.C., M.J. and M.T. wrote the manuscript and coordinated its revision. J.Z. and Q.Z. helped in sample preparation and data collection. All authors read and provided helpful discussions, and approved the final version.

Funding

This research was funded by the National Natural Science Foundation of China (grant number 31271421) and the Science and Technology Support Program of Jiangsu Province, China (grant number BE2017323).

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Phylogenetic relationships and conserved domains of maize ASRs. (A) Phylogenetic relationships of the maize ASRs and their homologs in grass species. Multiple alignments of ASR protein sequences were carried out with ClustalW utility embedded in MEGA7 software [40]. Phylogenetic trees were constructed by MEGA7 software using the neighbor-joining (NJ) method with 1000 bootstrap replicates, and tomato SlASR1 was used as the outgroup. Maize ASR1 was marked with one red dot, while other three maize ASRs for further experimental investigation were prefixed with triangles, and the left maize ASRs were marked with red diamonds. The ASRs in other plant species are prefixed as follows: Gm for soybean, Glycine max; Hv for barley, Hordium vulgare; Ma for banana, Musa acuminate; Os for rice, Oryza sativa; Sl for Tomato, Solanum lycopersicum; Ta for common wheat, Triticum aestivum; Tt for durum wheat, Triticum turgidum; Vv for grape, Vitis vinifera. (B) Domain organization of ZmASRs. The zinc-binding region, ABA/WDS domain, and the putative nuclear targeting signal were indicated in different color.
Figure 1. Phylogenetic relationships and conserved domains of maize ASRs. (A) Phylogenetic relationships of the maize ASRs and their homologs in grass species. Multiple alignments of ASR protein sequences were carried out with ClustalW utility embedded in MEGA7 software [40]. Phylogenetic trees were constructed by MEGA7 software using the neighbor-joining (NJ) method with 1000 bootstrap replicates, and tomato SlASR1 was used as the outgroup. Maize ASR1 was marked with one red dot, while other three maize ASRs for further experimental investigation were prefixed with triangles, and the left maize ASRs were marked with red diamonds. The ASRs in other plant species are prefixed as follows: Gm for soybean, Glycine max; Hv for barley, Hordium vulgare; Ma for banana, Musa acuminate; Os for rice, Oryza sativa; Sl for Tomato, Solanum lycopersicum; Ta for common wheat, Triticum aestivum; Tt for durum wheat, Triticum turgidum; Vv for grape, Vitis vinifera. (B) Domain organization of ZmASRs. The zinc-binding region, ABA/WDS domain, and the putative nuclear targeting signal were indicated in different color.
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Figure 2. Expression patterns of maize ZmASR genes. (A) In silico analysis of the expression of maize ZmASR genes in different tissues. Maize transcript profiles were retrieved from five transcriptomic studies (Supplementary Table S1) hosted in qTeller (http://qteller.com). Gene expression values were represented by FPKM. (B) Expression analysis of ASRs in leaves of maize plants exposed to Cd treatment. Maize plants were treated with Cd(NO3)2 for various times as indicated. The relative expression levels of genes was analyzed by real-time qRT-PCR. Values are means ± SE of three independent experiments.
Figure 2. Expression patterns of maize ZmASR genes. (A) In silico analysis of the expression of maize ZmASR genes in different tissues. Maize transcript profiles were retrieved from five transcriptomic studies (Supplementary Table S1) hosted in qTeller (http://qteller.com). Gene expression values were represented by FPKM. (B) Expression analysis of ASRs in leaves of maize plants exposed to Cd treatment. Maize plants were treated with Cd(NO3)2 for various times as indicated. The relative expression levels of genes was analyzed by real-time qRT-PCR. Values are means ± SE of three independent experiments.
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Figure 3. Maize ZmASR genes confer Cd-tolerance in yeast. The survival test of yeast strains transformed with maize ZmASR or pYES2 empty vector (EV) on SG-Ura agar medium supplemented with 40 μM CdCl2 in the presence of 2% galactose. Yeast cells transformed with EV were used as control.
Figure 3. Maize ZmASR genes confer Cd-tolerance in yeast. The survival test of yeast strains transformed with maize ZmASR or pYES2 empty vector (EV) on SG-Ura agar medium supplemented with 40 μM CdCl2 in the presence of 2% galactose. Yeast cells transformed with EV were used as control.
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Figure 4. Subcellular localization and Cd-tolerance assay of GFP-tagged ZmASR fusion proteins in N. benthamiana. (A) Subcellular localization of GFP and the ZmASR-GFP fusion protein in N. benthamiana leaf cells. Epidermal cells of N. benthamiana leaves transiently expressing GFP fusion proteins were observed using confocal microscopy at 4 days post Cd infiltration. RFP-H2A, localized in the nucleus, was used to indicate the nuclei [41]. (B) Lesions were photographed at 4 days post Cd treatment. The EV transformed control region is on the right, while region transient expressing ZmASR is on the left for each leaf. Agro-infiltrated areas are indicated by red circles and Cd-infiltrated areas are circled by the smaller white lines, whereas Cd-caused lesions are indicated by the internal black circles on each leaf.
Figure 4. Subcellular localization and Cd-tolerance assay of GFP-tagged ZmASR fusion proteins in N. benthamiana. (A) Subcellular localization of GFP and the ZmASR-GFP fusion protein in N. benthamiana leaf cells. Epidermal cells of N. benthamiana leaves transiently expressing GFP fusion proteins were observed using confocal microscopy at 4 days post Cd infiltration. RFP-H2A, localized in the nucleus, was used to indicate the nuclei [41]. (B) Lesions were photographed at 4 days post Cd treatment. The EV transformed control region is on the right, while region transient expressing ZmASR is on the left for each leaf. Agro-infiltrated areas are indicated by red circles and Cd-infiltrated areas are circled by the smaller white lines, whereas Cd-caused lesions are indicated by the internal black circles on each leaf.
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Table 1. Primers for construction of ZmASRs in yeast and tobacco transient expression vectors.
Table 1. Primers for construction of ZmASRs in yeast and tobacco transient expression vectors.
GeneGene Model *pYES2-F (5′-3′)pYES2-R (5′-3′)
ZmASR1ZM2G136910AAGCTT-AATTGTCACTTGCTCTCCGGATCC-GCTCGATATCACTCTCAC
ZmASR2ZM5G854138AAGCTT-CCAGCCATCCTACTGTCACAGGTACC-TCAGCCGAAGAGGTGGTGGT
ZmASR4ZM2G168552AAGCTT-TGAGAGCCTGAGACGATGGGGTACC-TTCAGTCGCAGTAGTAGGAGTA
ZmASR5ZM2G052100AAGCTT-GGAGCCATGTCTGAGGAGAAGGGTACC-CGACGATGTGCTGCTGCTT
pSuper-1300-F (5′-3′)pSuper-1300-R (5′-3′)
ZmASR1ZM2G136910TCTAGA-ATGGCGGAGGAGAAGGGTACC-GCCGAAGAAGTGGTG
ZmASR2ZM5G854138AAGCTT-CCAGCCATCCTACTGTCACAGGTACC-GCCGAAGAGGTGGTGGTG
ZmASR4ZM2G168552AAGCTT-TGAGAGCCTGAGACGATGGGGTACC-GTCGCAGTAGTAGGAGT
ZmASR5ZM2G052100AAGCTT-GGAGCCATGTCTGAGGAGAAGGGTACC-GTTGTGGGCGTGCTTCTT
* Gene model is shown in abbreviated form through slicing the prefix GRM.

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Zhang, J.; Zhu, Q.; Yu, H.; Li, L.; Zhang, G.; Chen, X.; Jiang, M.; Tan, M. Comprehensive Analysis of the Cadmium Tolerance of Abscisic Acid-, Stress- and Ripening-Induced Proteins (ASRs) in Maize. Int. J. Mol. Sci. 2019, 20, 133. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms20010133

AMA Style

Zhang J, Zhu Q, Yu H, Li L, Zhang G, Chen X, Jiang M, Tan M. Comprehensive Analysis of the Cadmium Tolerance of Abscisic Acid-, Stress- and Ripening-Induced Proteins (ASRs) in Maize. International Journal of Molecular Sciences. 2019; 20(1):133. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms20010133

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Zhang, Jie, Qiusha Zhu, Haijuan Yu, Liang Li, Guoqiang Zhang, Xi Chen, Mingyi Jiang, and Mingpu Tan. 2019. "Comprehensive Analysis of the Cadmium Tolerance of Abscisic Acid-, Stress- and Ripening-Induced Proteins (ASRs) in Maize" International Journal of Molecular Sciences 20, no. 1: 133. https://0-doi-org.brum.beds.ac.uk/10.3390/ijms20010133

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