Abstract
BackgroundAmino acid transporters (AATs) plays an essential roles in growth and development of plants, including amino acids long-range transport, seed germination, quality formation, responsiveness to pathogenic bacteria and abiotic stress by modulating the transmembrane transfer of amino acids. In this study, we performed a genome-wide screening to analyze the AAT genes in foxtail millet (Setaria italica L.), especially those associated with quality formation and abiotic stresses response.ResultsA total number of 94 AAT genes were identified and divided into 12 subfamilies by their sequence characteristics and phylogenetic relationship. A large number (58/94, 62%) of AAT genes in foxtail millet were expanded via gene duplication, involving 13 tandem and 12 segmental duplication events. Tandemly duplicated genes had a significant impact on their functional differentiation via sequence variation, structural variation and expression variation. Further comparison in multiple species showed that in addition to paralogous genes, the expression variations of the orthologous AAT genes also contributed to their functional differentiation. The transcriptomic comparison of two millet cultivars verified the direct contribution of the AAT genes such as SiAAP1, SiAAP8, and SiAUX2 in the formation of grain quality. In addition, the qRT-PCR analysis suggested that several AAT genes continuously responded to diverse abiotic stresses, such as SiATLb1, SiANT1. Finally, combined with the previous studies and analysis on sequence characteristics and expression patterns of AAT genes, the possible functions of the foxtail millet AAT genes were predicted.ConclusionThis study for the first time reported the evolutionary features, functional differentiation, roles in the quality formation and response to abiotic stresses of foxtail millet AAT gene family, thus providing a framework for further functional analysis of SiAAT genes, and also contributing to the applications of AAT genes in improving the quality and resistance to abiotic stresses of foxtail millet, and other cereal crops.
Highlights
Amino acid transporters (AATs) plays an essential roles in growth and development of plants, including amino acids long-range transport, seed germination, quality formation, responsiveness to pathogenic bacteria and abiotic stress by modulating the transmembrane transfer of amino acids
Different subfamilies of AAT genes showed abundant diversity in subcellular localization, with the subfamily members of Amino acid permease (AAP), Lysine and histidine transporter (LHT), γ- aminobutyric acid transporter (GAT), Auxin transporter (AUX) and Proline transporter (ProT) all located on plasma membrane, while those of Tyrosine-specific transporter (TTP), Amino acid/choline transporter (ACT), Aromatic and neutral amino acid transporter (ANT) and ATLb all located on vacuole membrane
Some members of the same subfamily showed different subcellular localization, such as, different genes of the ATLa subfamily located on both membranes of plasma and vacuole, while that of the Cationic amino acid transporter (CAT) and Polyamine H+-symporter (PHS) subfamilies located on the three membranes of the plasma, vacuole and chloroplast
Summary
Amino acid transporters (AATs) plays an essential roles in growth and development of plants, including amino acids long-range transport, seed germination, quality formation, responsiveness to pathogenic bacteria and abiotic stress by modulating the transmembrane transfer of amino acids. Through the transmembrane transport of amino acids, amino acid transporters play essential roles in plant growth and development, including seed germination [3, 4], long-distance transport of amino acids [5], quality formation [6, 7], and response to pathogenic bacteria [8] and abiotic stress [9]. The AAT gene family in plants belongs to APC transporter superfamily, that comprises of two main families of amino acid/auxin permease (AAAP) family and amino acid-polyamine-choline (APC) transporter family. The APC family comprises cationic amino acid transporters (CATs), amino acid/choline transporters (ACTs), polyamine H+ − symporters (PHSs), and tyrosine-specific transporters (TTPs) subfamilies [10, 16]
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