Small auxin upregulated RNA （SAUR） gene family in maize： Identification,evolution, and its phylogenetic comparison with Arabidopsis,rice, and sorghum

Small auxin-up RNAs （.SAURs） are the early auxin- responsive genes represented by a large multigene family in plants. Here, we identified 79 SAUR gene family members from maize （Zea mays subsp, mays） by a reiterative database search and manual annotation. Phylogenetic analysis indicated that the SAUR proteins from Arabidopsis, rice, sorghum, and maize had divided into 16 groups. These genes were non-randomly distributed across the maize chromosomes, and segmental duplication and tandem duplication contributed to the expansion of the maize .SAUR gene family. Synteny analysis established ortholos~J relationships and functional linkages between SAUR genes in maize and sorghum genomes. We also found that the auxin-responsive elements were conserved in the upstream sequences of maize SAUR members. Selection analyses identified some significant site-specific constraints acted on most SAUR paralogs. Expression profiles based on microarray data have provided insights into the possible functional divergence among members of the .SAUR gene family. Quantitative real-time PCR analysis indicated that some of the 10 randomly selected ZmSAUR genes could be induced at least in maize shoot or root tissue tested. The results reveal a comprehensive overview of the maize .SAUR gene family and may pave the way for deciphering their function during pJant development.     

Small auxin upregulated RNA (SAUR) gene family in maize: Identification,evolution, and its phylogenetic comparison with Arabidopsis,rice, and sorghum

Small auxin-up RNAs(SAURs)are the early auxin-responsive genes represented by a large multigene family in plants.Here,we identified 79 SAUR gene family members from maize(Zea mays subsp.mays)by a reiterative database search and manual annotation.Phylogenetic analysis indicated that the SAUR proteins from Arabidopsis,rice,sorghum,and maize had divided into 16 groups.These genes were non-randomly distributed across the maize chromosomes,and segmental duplication and tandem duplication contributed to the expansion of the maize SAUR gene family.Synteny analysis established orthology relationships and functional linkages between SAUR genes in maize and sorghum genomes.We also found that the auxin-responsive elements were conserved in the upstream sequences of maize SAUR members.Selection analyses identified some significant site-specific constraints acted on most SAUR paralogs.Expression profiles based on microarray data have provided insights into the possible functional divergence among members of the SAUR gene family.Quantitative real-time PCR analysis indicated that some of the 10 randomly selected ZmSAUR genes could be induced at least in maize shoot or root tissue tested.The results reveal a comprehensive overview of the maize SAUR gene family and may pave the way for deciphering their function during plant development.     

The SAUR19 subfamily of SMALL AUXIN UP RNA genes promote cell expansion

The plant hormone auxin controls numerous aspects of plant growth and development by regulating the expression of hundreds of genes. SMALL AUXIN UP RNA (SAUR) genes comprise the largest family of auxin-responsive genes, but their function is unknown. Although prior studies have correlated the expression of some SAUR genes with auxin-mediated cell expansion, genetic evidence implicating SAURs in cell expansion has not been reported. The Arabidopsis SAUR19, SAUR20, SAUR21, SAUR22, SAUR23, and SAUR24 (SAUR19-24) genes encode a subgroup of closely related SAUR proteins. We demonstrate that these SAUR proteins are highly unstable in Arabidopsis. However, the addition of an N-terminal GFP or epitope tag dramatically increases the stability of SAUR proteins. Expression of these stabilized SAUR fusion proteins in Arabidopsis confers numerous auxin-related phenotypes indicative of increased and/or unregulated cell expansion, including increased hypocotyl and leaf size, defective apical hook maintenance, and altered tropic responses. Furthermore, seedlings expressing an artificial microRNA targeting multiple members of the SAUR19-24 subfamily exhibit short hypocotyls and reduced leaf size. Together, these findings demonstrate that SAUR19-24 function as positive effectors of cell expansion. This regulation may be achieved through the modulation of auxin transport, as SAUR gain-of-function and loss-of-function seedlings exhibit increased and reduced basipetal indole-3-acetic acid transport, respectively. Consistent with this possibility, SAUR19-24 proteins predominantly localize to the plasma membrane.     

Arabidopsis SMALL AUXIN UP RNA63 promotes hypocotyl and stamen filament elongation

Auxin regulates plant growth and development in part by activating gene expression. Arabidopsis thaliana SMALL AUXIN UP RNAs (SAURs) are a family of early auxin-responsive genes with unknown functionality. Here, we show that transgenic plant lines expressing artificial microRNA constructs (aMIR-SAUR-A or -B) that target a SAUR subfamily (SAUR61-SAUR68 and SAUR75) had slightly reduced hypocotyl and stamen filament elongation. In contrast, transgenic plants expressing SAUR63:GFP or SAUR63:GUS fusions had long hypocotyls, petals and stamen filaments, suggesting that these protein fusions caused a gain of function. SAUR63:GFP and SAUR63:GUS seedlings also accumulated a higher level of basipetally transported auxin in the hypocotyl than did wild-type seedlings, and had wavy hypocotyls and twisted inflorescence stems. Mutations in auxin efflux carriers could partially suppress some SAUR63:GUS phenotypes. In contrast, SAUR63:HA plants had wild-type elongation and auxin transport. SAUR63:GFP protein had a longer half-life than SAUR63:HA. Fluorescence imaging and microsomal fractionation studies revealed that SAUR63:GFP was localized mainly in the plasma membrane, whereas SAUR63:HA was present in both soluble and membrane fractions. Low light conditions increased SAUR63:HA protein turnover rate. These results indicate that membrane-associated Arabidopsis SAUR63 promotes auxin-stimulated organ elongation.     

葡萄SAUR基因家族鉴定与生物信息学分析

为了研究葡萄早期应答生长素基因SAUR(Small auxin-up RNA)家族,本研究利用全基因组信息鉴定了葡萄64个SAUR家族成员,并对SAUR家族成员的基因结构、氨基酸特性、染色体定位、基因进化、基因功能以及组织表达进行分析。结果表明,葡萄全基因组上64个SAUR家族成员在19条染色体中的8条染色体上呈现簇状分布,主要分布在3、4号染色体上,其中3号染色体上数量最多为37个;葡萄SAUR家族基因长度较短,有59个基因是无内含子基因;蛋白理化特征分析显示,多数SAUR蛋白呈碱性,结构稳定性较差,蛋白脂溶指数高,呈亲水性;基因功能预测结果表明,葡萄SAUR基因主要担当生长因子、结构蛋白、转录、转录调控以及响应胁迫应答和免疫应答6种功能,其中更多参与生长调节功能;根据系统进化分析将其分为10个分支,另外不同组织表达谱的分析结果表明SAUR基因家族成员具有不同的组织表达模式,对于非生物胁迫具有一定的调节作用。这些信息为葡萄SAUR基因家族功能分析奠定了一定的工作基础。     

SAUR Inhibition of PP2C-D Phosphatases Activates Plasma Membrane H+-ATPases to Promote Cell Expansion in Arabidopsis

The plant hormone auxin promotes cell expansion. Forty years ago, the acid growth theory was proposed, whereby auxin promotes proton efflux to acidify the apoplast and facilitate the uptake of solutes and water to drive plant cell expansion. However, the underlying molecular and genetic bases of this process remain unclear. We have previously shown that the SAUR19-24 subfamily of auxin-induced SMALL AUXIN UP-RNA (SAUR) genes promotes cell expansion. Here, we demonstrate that SAUR proteins provide a mechanistic link between auxin and plasma membrane H⁺-ATPases (PM H⁺-ATPases) in Arabidopsis thaliana. Plants overexpressing stabilized SAUR19 fusion proteins exhibit increased PM H⁺-ATPase activity, and the increased growth phenotypes conferred by SAUR19 overexpression are dependent upon normal PM H⁺-ATPase function. We find that SAUR19 stimulates PM H⁺-ATPase activity by promoting phosphorylation of the C-terminal autoinhibitory domain. Additionally, we identify a regulatory mechanism by which SAUR19 modulates PM H⁺-ATPase phosphorylation status. SAUR19 as well as additional SAUR proteins interact with the PP2C-D subfamily of type 2C protein phosphatases. We demonstrate that these phosphatases are inhibited upon SAUR binding, act antagonistically to SAURs in vivo, can physically interact with PM H⁺-ATPases, and negatively regulate PM H⁺-ATPase activity. Our findings provide a molecular framework for elucidating auxin-mediated control of plant cell expansion.     

Molecular evolution and functional divergence of HAK potassium transporter gene family in rice （Oryza sativa L.）

The high-affinity K＋ （HAK） transporter gene family is the largest family in plant that functions as potassium transporter and is important for various aspects of plant life. In the present study, we identified 27 members of this family in rice genome. The phylogenetic tree divided the land plant HAK transporter proteins into 6 distinct groups. Although the main characteristic of this family was established before the origin of seed plants, they also showed some differences between the members of non-seed and seed plants. The HAK genes in rice were found to have expanded in lineage-specific manner after the split of monocots and dicots, and both segmental duplication events and tandem duplication events contributed to the expansion of this family. Functional divergence analysis for this family provided statistical evidence for shifted evolutionary rate after gene duplication. Further analysis indicated that both point mutant with positive selection and gene conversion events contributed to the evolution of this family in rice.     

Duplication and functional diversification of HAP3 genes leading to the origin of the seed-developmental regulatory gene, LEAFY COTYLEDON1 (LEC1), in nonseed plant genomes

The HAP3 gene encodes a subunit of the CCAAT-box-binding factor (CBF), a highly conserved trimeric activator that recognizes and binds the ubiquitous CCAAT promoter element with high affinity. Two types of HAP3 gene have been identified in plant genomes. The LEAFY COTYLEDON1 (LEC1)-type HAP3 genes encode a functionally specialized subunit of CBF, which is expressed specifically in developing seeds. In contrast, most non-LEC1-type HAP3 genes are expressed in various tissues. It has been proposed that the LEC1-type HAP3 genes originated from the duplication and functional divergence of non-LEC1-type HAP3 genes. However, it is not yet known when this duplication event took place or whether the LEC1-type HAP3 genes appeared at the same time as the origin of seed plants. Here we describe a comprehensive comparison of the duplication patterns of HAP3 genes in different plant genomes. We recognize a major expansion of the HAP3 gene family accompanying the origin and early diversification of land plants and postulate that retrotransposition and other mechanisms of gene duplication have been involved in the expansion of the plant HAP3 gene family. We provide evidence that the LEC1-type HAP3 genes originated in nonseed vascular plant genomes and demonstrate that they are inductively expressed under drought stress in nonseed plants. These genes, however, were recruited to a novel regulatory network in the early stages of seed plant evolution and steadily expressed during seed development and maturation.     

Genome-wide analysis of WOX gene family in rice, sorghum, maize, Arabidopsis and poplar

WUSCHEL-related homeobox(WOX)genes form a large gene family specifically expressed in plants.They are known to play important roles in regulating the development of plant tissues and organs by determining cell fate.Recent available whole genome sequences allow us to do more comprehensive phylogenetic analysis of the WOX genes in plants.In the present study,we identified 11 and 21 WOXs from sorghum(Sorghum bicolor)and maize(Zea mays),respectively.The 72 WOX genes from rice(Oryza sativa),sorghum,maize,Arabidopsis(Arabidopsis thaliana)and poplar(Populus trichocarpa)were grouped into three well supported clades with nine subgroups according to the amino acid sequences of their homodomains.Their phylogenetic relationship was also supported by the observation of the motifs outside the homodomain.We observed the variation of duplication events among the nine sub-groups between monocots and eudicots,for instance,more gene duplication events of WOXs within subgroup A for monocots,while,less for dicots in this subgroup.Furthermore,we observed the conserved intron/exon structural patterns of WOX genes in rice,sorghum and Arabidopsis.In addition,WUS(Wuschel)-box and EAR(the ERF-associated amphiphilic repression)-like motif were observed to be conserved among several WOX subgroups in these five plants.Comparative analysis of expression patterns of WOX genes in rice and Arabidopsis suggest that the WOX genes play conserved and various roles in plants.This work provides insights into the evolution of the WOX gene family and is useful for future research.     

拟南芥和水稻SET结构域基因家族全基因组鉴定、分类和表达

ET(Su(var), Enhancer of zeste (E(z)), and Trithorax)结构域基因家族是一组含有保守SET结构域的蛋白的统称, 它们参与蛋白甲基化, 影响染色体结构, 并且调控基因表达, 在植物发育中起着重要的作用。分析拟南芥和水稻中SET结构域基因家族进化关系, 对研究这一基因家族中各成员的功能有着重要的意义。我们系统地鉴定了47个拟南芥(Arabidopsis thaliana)和43个水稻(Orysa sativa japonica cultivar Nipponbare)的SET结构域基因, 染色体定位和基因复制分析表明SET结构域基因扩增是由片段复制和反转录引起的, 根据这些结构域差异和系统发育分析把拟南芥和水稻的SET结构域基因划分成5个亚家族。通过分析SET结构域基因家族在拟南芥和水稻各个发育阶段的表达谱, 发现SET结构域基因绝大部分至少在一个组织中表达; 大部分在花和花粉中高表达; 一些SET结构域基因在某些组织中有特异的表达模式, 表明与组织发育有密切的关系。在拟南芥和水稻中分别找到了4个差异表达基因。拟南芥4个差异基因都在花粉管高表达, 水稻4个差异基因有3个在雄性花蕊中高表达, 另一个在幼穗中高表达。     

Evolutionary analysis of three gibberellin oxidase genes in rice, Arabidopsis, and soybean

GAs are plant hormones that play fundamental roles in plant growth and development. GA2ox, GA3ox, and GA20ox are three key enzymes in GA biosynthesis. These enzymes belong to the 2OG-Fe (II) oxygenase superfamily and are independently encoded by different gene families. To date, genome-wide comparative analyses of GA oxidases in plant species have not been thoroughly carried out. In the present work, 61 GA oxidase family genes from rice (Oryza sativa), Arabidopsis, and soybean (Glycine max) were identified and a full study of these genes including phylogenetic tree construction, gene structure, gene family expansion and analysis of functional motifs was performed. Based on phylogeny, most of the GA oxidases were divided into four subgroups that reflected functional classifications. Intron/intron average length of GA oxidase genes in rice analysis revealed that GA oxidase genes in rice experienced substantial evolutionary divergence. Segmental duplication events were mainly found in soybean genome. However, in rice and Arabidopsis, no single expansion pattern exhibited dominance, indicating that GA oxidase genes from these species might have been subjected to a more complex evolutionary mechanism. In addition, special functional motifs were discovered in GA20ox, GA3ox, and GA2ox, which suggested that different functional motifs are associated with differences in protein function. Taken together our results suggest that GA oxidase family genes have undergone divergent evolutionary routes, especially at the monocot-dicot split, with dynamic evolution occurring in Arabidopsis thaliana and soybean.