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.     

KT/HAK/KUP potassium transporters gene family and their whole-life cycle expression profile in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis>)

KT/HAK/KUP potassium transporter protein-encoding genes constitute a large family in the plant kingdom. The KT/HAK/KUP family is important for various physiological processes of plant life. In this study, we identified 27 potential KT/HAK/KUP family genes in rice (Oryza sativa) by database searching. Analysis of these KT/HAK/KUP family members identified three conserved motifs with unknown functions, and 11-15 trans-membrane segments, most of which are conserved. A total of 144 putative cis-elements were found in the 2 kb upstream region of these genes, of which a Ca2+-responsive cis-element, two light-responsive cis-elements, and a circadian-regulated cis-element were identified in the majority of the members, suggesting regulation of these genes by these signals. A comprehensive expression analysis of these genes was performed using data from microarrays hybridized with RNA samples of 27 tissues covering the entire life cycle from three rice genotypes, Minghui 63, Zhenshan 97, and Shanyou 63. We identified preferential expression of two OsHAK genes in stamen at 1 day before flowering compared with all the other tissues. OsHAK genes were also found to be differentially upregulated or downregulated in rice seedlings subjected to treatments with three hormones. These results would be very useful for elucidating the roles of these genes in growth, development, and stress response of the rice plant.     

Identification and expression profile analysis of the protein kinase gene superfamily in maize development

Eukaryotic protein kinases (ePKs) evolved as a family of highly dynamic molecular switches that serve to orchestrate the activity of almost all cellular processes. Some of the functionally characterized ePKs from plants have been found to be components of signaling networks, such as those for the perception of biotic agents, light quality and quantity, plant hormones, and various adverse environmental conditions. To date, only a tiny fraction of plant ePKs have been functionally identified, and even fewer have been identified in maize [Zea mays (Zm)]. In this study, we have identified 1,241 PK-encoding genes in the maize genome. Phylogenetic analyses identified eight gene groups with considerable conservation among groups, and each group could be further divided into multiple families and/or subfamilies. Similar intron/exon structural patterns were observed in the same families/subfamilies, strongly supporting their close evolutionary relationship. Chromosome distribution and genetic analysis revealed that tandem duplications and segmental/whole-genome duplications might represent two of the major mechanisms contributing to the expansion of the PK superfamily in maize. The dynamic expression patterns of ZmPK genes across the 60 different developmental stages of 11 organs showed that some members of this superfamily exhibit tissue-specific expression, whereas others are more ubiquitously expressed, indicative of their important roles in performing diverse developmental and physiological functions during the maize life cycle. Furthermore, RNA-sequence-based gene expression profiling of PKs along a leaf developmental gradient and in mature bundle sheath and mesophyll cells indicated that ZmPK genes are involved in various physiological processes, such as cell-fate decisions, photosynthetic differentiation, and regulation of stomatal development. Our results provide new insights into the function and evolution of maize PKs and will be useful in studies aimed at revealing the global regulatory network of maize development, thereby contributing to the maize molecular breeding with enhanced quality traits.     

Genome-Wide Identification and Analysis of Expression Profiles of Maize Mitogen-Activated Protein Kinase Kinase Kinase

Mitogen-activated protein kinase (MAPK) cascades are highly conserved signal transduction model in animals, yeast and plants. Plant MAPK cascades have been implicated in development and stress responses. Although MAPKKKs have been investigated in several plant species including Arabidopsis and rice, no systematic analysis has been conducted in maize. In this study, we performed a bioinformatics analysis of the entire maize genome and identified 74 MAPKKK genes. Phylogenetic analyses of MAPKKKs from maize, rice and Arabidopsis have classified them into three subgroups, which included Raf, ZIK and MEKK. Evolutionary relationships within subfamilies were also supported by exon-intron organizations and the conserved protein motifs. Further expression analysis of the MAPKKKs in microarray databases revealed that MAPKKKs were involved in important signaling pathways in maize different organs and developmental stages. Our genomics analysis of maize MAPKKK genes provides important information for evolutionary and functional characterization of this family in maize.     

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.     

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.     

玉米Dof转录因子家族基因的全基因组分析

Dof转录因子家族在植物生长发育和基因表达调控过程中具有重要的作用,本文利用公布的玉米基因组草图数据,利用生物信息学方法对玉米全基因组Dof基因的结构、系统进化关系和保守motif进行了分析。结果表明:玉米中共有18个Dof类型基因,命名为ZmDof1-ZmDof18,其蛋白质长度在211aa至618aa之间,通过系统进化树分析后,18个Dof基因可以明显的分为三类,此外玉米Dof基因的数目远远小于水稻和拟南芥,基因复制现象较少是玉米Dof基因数量较少的原因之一,MEME分析证实了Dof基因含有三个保守的motif。对玉米Dof类型基因的系统分析,将有助于玉米Dof类型基因的克隆和功能的进一步研究。     

Genome-wide identification and expression profiling of DNA methyltransferase gene family in maize

Key message

In this study, we identified eight DNA MTase genes in maize and the diversity of expression patterns of them was presented by EST mining, microarray and semi-quantitative expression profile analyses.

Abstract

DNA methylation plays a pivotal role in promoting genomic stability through diverse biological processes including regulation of gene expression during development and chromatin organization. Although this important biological process is mainly regulated by several conserved Cytosine-5 DNA methyltransferases encoded by a smaller multigene family in plants, investigation of the plant C5-MTase-encoding gene family will serve to elucidate the epigenetic mechanism diversity in plants. Recently, genome-wide identification and evolutionary analyses of the C5-MTase-encoding gene family have been characterized in multiple plant species including Arabidopsis, rice, carrot and wheat. However, little is known regarding the C5-MTase-encoding genes in the entire maize genome. Here, genome-wide identification and expression profile analyses of maize C5-MTase-encoding genes (ZmMETs) were performed from the latest version of the maize (B73) genome. Phylogenetic analysis indicated that the orthologs from the three species (maize, Arabidopsis and rice) were categorized into four classes. Chromosomal location of these genes revealed that they are unevenly distributed on 6 of all 10 chromosomes with three chromosomal/segmental duplication events, suggesting that gene duplication played a key role in expansion of the maize C5-MTase-encoding gene family. Furthermore, EST expression data mining, microarray data and semi-quantitative expression profile analyses detected in the leaves by two different abiotic stress treatments have demonstrated that these genes had temporal and spatial expression pattern and exhibited different expression levels in stress treatments, suggesting that functional diversification of ZmMET genes family. Overall, our study will serve to present signification insights to explore the plant C5-MTase-encoding gene expression and function and also be beneficial for future experimental research to further unravel the mechanisms of epigenetic regulation in plants.     

Genome-wide analysis of primary auxin-responsive Aux/IAA gene family in maize (Zea mays. L.)

The phytohormone auxin is important in various aspects of organism growth and development. Aux/IAA genes encoding short-lived nuclear proteins are responsive primarily to auxin induction. Despite their physiological importance, systematic analysis of Aux/IAA genes in maize have not yet been reported. In this paper, we presented the isolation and characterization of maize Aux/IAA genes in whole-genome scale. A total of 31 maize Aux/IAA genes (ZmIAA1 to ZmIAA31) were identified. ZmIAA genes are distributed in all the maize chromosomes except chromosome 2. Aux/IAA genes expand in the maize genome partly due to tandem and segmental duplication events. Multiple alignment and motif display results revealed major maize Aux/IAA proteins share all the four conserved domains. Phylogenetic analysis indicated Aux/IAA family can be divided into seven subfamilies. Putative cis-acting regulatory DNA elements involved in auxin response, light signaling transduction and abiotic stress adaption were observed in the promoters of ZmIAA genes. Expression data mining suggested maize Aux/IAA genes have temporal and spatial expression pattern. Collectively, these results will provide molecular insights into the auxin metabolism, transport and signaling research.     

金鱼ABC转运蛋白基因家族成员鉴定及分析

腺苷三磷酸结合盒转运蛋白(ATP-binding cassette transporter,ABC transporter)基因家族在原核生物和真核生物中广泛存在,该家族蛋白能够利用ATP裂解产生的能量将多种底物转运到膜上,参与多种生物过程,如营养摄入、细胞解毒、脂质稳态、信号转导、病毒防御以及抗原呈递等。目前,鱼类中,只在斑马鱼、斑点叉尾鮰和鲤鱼等少数鱼类中对该基因家族进行了系统的研究,关于金鱼ABC转运蛋白基因家族的详细分析,未见报道。本研究中,我们利用三代结合二代测序技术构建的金鱼转录组参考基因集数据,鉴定出55个ABC转运蛋白基因,通过系统进化分析将它们分为8个亚家族(A^H)。即金鱼ABC转运蛋白基因是由10个ABCA、14个ABCB、13个ABCC、5个ABCD、1个ABCE、4个ABCF、7个ABCG和1个ABCH组成。同时,我们将金鱼与斑马鱼、斑点叉尾鮰和鲤鱼等物种ABC转运蛋白基因家族成员的数目进行比较分析,推测硬骨鱼类特异的第3次全基因复制(3R-WGD)和谱系特异的第4次全基因组复制(4R-WGD)对金鱼该基因家族成员数目的影响。本研究结果为金鱼ABC转运蛋白基因功能的研究提供了理论依据。     

In silico analysis of PHB gene family in maize

Prohibitins (PHBs) are highly conserved proteins in species ranging from prokaryotes to eukaryotes. Plant PHBs have been implicated in various cellular processes including development, senescence and stress responses. Although PHBs have been investigated in several plant species including Arabidopsis and tobacco, no systematic gene family analysis has been carried in maize. In the present study, 16 putative PHB genes have been identified. Analysis of the conserved protein motifs and gene structures has revealed high levels of conservation within the phylogenetic subgroups. Published microarray database showed that most maize PHB genes exhibited different expression levels in different tissues and developmental stages. Cis-elements analysis showed that ZmPHB2 and ZmPHB12 may play important roles in plant development. Taken together, we provide a comprehensive bioinformatics analysis of the PHB gene family in maize genome and our data provide an important foundation for further functional study of this gene family in maize.     

Systematic analysis and comparison of nucleotide-binding site disease resistance genes in maize

Nucleotide-binding site (NBS) disease resistance genes play an integral role in defending plants from a range of pathogens and insect pests. Consequently, a number of recent studies have focused on NBS-encoding genes in molecular disease resistance breeding programmes for several important plant species. Little information, however, has been reported with an emphasis on systematic analysis and a comparison of NBS-encoding genes in maize. In the present study, 109 NBS-encoding genes were identified based on the complete genome sequence of maize (Zea mays cv. B73), classified as four different subgroups, and then characterized according to chromosomal locations, gene duplications, structural diversity and conserved protein motifs. Subsequent phylogenetic comparisons indicated that several maize NBS-encoding genes possessed high similarity to function-known NBS-encoding genes, and revealed the evolutionary relationships of NBS-encoding genes in maize comparede to those in other model plants. Analyses of the physical locations and duplications of NBS-encoding genes showed that gene duplication events of disease resistance genes were lower in maize than in other model plants, which may have led to an increase in the functional diversity of the maize NBS-encoding genes. Various expression patterns of maize NBS-encoding genes in different tissues were observed using an expressed-sequence tags database and, alternatively, after southern leaf blight infection or the application of exogenous salicylic acid. The results reported in the present study contribute to an improved understanding of the NBS-encoding gene family in maize.