Abstract
Coding sequences of the CLC family genes SaCLCd, SaCLCf, and SaCLCg, the putative orthologs of Arabidopsis thaliana AtCLCd, AtCLCf, and AtCLCg genes, were cloned from the euhalophyte Suaeda altissima (L.) Pall. The key conserved motifs and glutamates inherent in proteins of the CLC family were identified in SaCLCd, SaCLCf, and SaCLCg amino acid sequences. SaCLCd and SaCLCg were characterized by higher homology to eukaryotic (human) CLCs, while SaCLCf was closer to prokaryotic CLCs. Ion specificities of the SaCLC proteins were studied in complementation assays by heterologous expression of the SaCLC genes in the Saccharomyces cerevisiae GEF1 disrupted strain Δgef1. GEF1 encoded the only CLC family protein, the Cl− transporter Gef1p, in undisrupted strains of this organism. Expression of SaCLCd in Δgef1 cells restored their ability to grow on selective media. The complementation test and the presence of both the “gating” and “proton” conservative glutamates in SaCLCd amino acid sequence and serine specific for Cl− in its selectivity filter suggest that this protein operates as a Cl−/H+ antiporter. By contrast, expression of SaCLCf and SaCLCg did not complement the growth defect phenotype of Δgef1 cells. The selectivity filters of SaCLCf and SaCLCg also contained serine. However, SaCLCf included only the “gating” glutamate, while SaCLCg contained the “proton” glutamate, suggesting that SaCLCf and SaCLCg proteins act as Cl− channels. The SaCLCd, SaCLCf, and SaCLCg genes were shown to be expressed in the roots and leaves of S. altissima. In response to addition of NaCl to the growth medium, the relative transcript abundances of all three genes of S. altissima increased in the leaves but did not change significantly in the roots. The increase in expression of SaCLCd, SaCLCf, and SaCLCg in the leaves in response to increasing salinity was in line with Cl− accumulation in the leaf cells, indicating the possible participation of SaCLCd, SaCLCf, and SaCLCg proteins in Cl− sequestration in cell organelles. Generally, these results suggest the involvement of SaCLC proteins in the response of S. altissima plants to increasing salinity and possible participation in mechanisms underlying salt tolerance.
Highlights
Soil salinization is a significant problem in agriculture
We describe the cloning of other genes of the CLC family from S. altissima, namely SaCLCd, SaCLCf, and SaCLCg, the putative orthologs of AtCLCd, AtCLCf, and AtCLCg, and investigate anion selectivity of the encoded proteins
As a result of in silico searches of sequences related to the CLC family in the de novo assembled transcriptome of S. fruticosa [51,56], the contigs containing the partial coding regions of three sequences homologous to the
Summary
Soil salinization is a significant problem in agriculture. The decrease in yield caused by salinity is due to the fact that the vast majority of agricultural crops are salt-sensitive plants, known as glycophytes [5,6,7,8]. Halophytes are plants of saline habitats that have evolved mechanisms to adequately regulate Na+ and Cl− concentrations in cytoplasm and acquire nutrients, in particular nitrate, under soil salinization [12,13,14]. Despite the fact that anion flow into cells is hindered by the plasma membrane electric potential, negative from the cytoplasmic side, Cl− ions at high external concentrations may passively enter the cells and accumulate in the cytoplasm [9,22,23]
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