Toshifumi Nagata

Rice Expression Atlas In Reproductive Development

Gene expression throughout the reproductive process in rice (Oryza sativa) beginning with primordia development through pollination/fertilization to zygote formation was analyzed. We analyzed 25 stages/organs of rice reproductive development including early microsporogenesis stages with 57,381 probe sets, and identified around 26,000 expressed probe sets in each stage. Fine dissection of 25 reproductive stages/organs combined with detailed microarray profiling revealed dramatic, coordinated and finely tuned changes in gene expression. A decrease in expressed genes in the pollen maturation process was observed in a similar way with Arabidopsis and maize. An almost equal number of ab initio predicted genes and cloned genes which appeared or disappeared coordinated with developmental stage progression. A large number of organ-/stage-specific genes were identified; notably 2,593 probe sets for developing anther, including 932 probe sets corresponding to ab initio predicted genes. Analysis of cell cycle-related genes revealed that several cyclin-dependent kinases (CDKs), cyclins and components of SCF E3 ubiquitin ligase complexes were expressed specifically in reproductive organs. Cell wall biosynthesis or degradation protein genes and transcription factor genes expressed specifically in reproductive stages were also newly identified. Rice genes homologous to reproduction-related genes in other plants showed expression profiles both consistent and inconsistent with their predicted functions. The rice reproductive expression atlas is likely to be the most extensive and most comprehensive data set available, indispensable for unraveling functions of many specific genes in plant reproductive processes that have not yet been thoroughly analyzed.

Levels of active oxygen species are controlled by ascorbic acid and anthocyanin in Arabidopsis.

Stabilization of the levels of active oxygen species (AOS) is important to the survival of organisms. To clarify the system controlling levels of AOS in plants, this study used an electron spin resonance (ESR) method to directly measure superoxide radical (O(2)(.-)) scavenging activities in the wild-type Arabidopsis thaliana (Col and Ler ecotypes), two anthocyanin mutants (tt3 and ttg1), and an ascorbic acid mutant (vtc1). Under ordinary growth conditions, Arabidopsis contained superoxide-scavenging activity (SOSA) of approximately 300-500 SOD units/g of fresh weight. The ESR pattern indicated that most (40-50%) of this activity was due to ascorbic acid. For the analysis of SOSA under conditions of oxidative stress, synthesis of AOS was induced by gamma-irradiation. The radical scavenging activity in irradiated plants increased approximately 10-fold following an associated increase in the accumulation of ascorbic acid and anthocyanin. The accumulation of ascorbic acid and anthocyanin was suppressed by treatment with an antioxidant before irradiation and was induced by treatment with a radical-generating reagent. The contributions of ascorbic acid and anthocyanin to the total superoxide radical scavenging activity differed among ecotypes. In the Ler ecotype, ascorbic acid accumulated at twice the level of that in the Col ecotype, and induction of anthocyanin was half that in Col. To confirm the activity of ascorbic acid and anthocyanin against AOS stress, the viability of the wild type and mutants (tt2, tt3,tt5, ttg1, and vtc1) was examined after gamma-irradiation. Only the plants in which ascorbic acid and anthocyanin were induced had the ability to grow and flower.

Comparative molecular biological analysis of membrane transport genes in organisms

Comparative analyses of membrane transport genes revealed many differences in the features of transport homeostasis in eight diverse organisms, ranging from bacteria to animals and plants. In bacteria, membrane-transport systems depend mainly on single genes encoding proteins involved in an ATP-dependent pump and secondary transport proteins that use H+ as a co-transport molecule. Animals are especially divergent in their channel genes, and plants have larger numbers of P-type ATPase and secondary active transporters than do other organisms. The secondary transporter genes have diverged evolutionarily in both animals and plants for different co-transporter molecules. Animals use Na+ ions for the formation of concentration gradients across plasma membranes, dependent on secondary active transporters and on membrane voltages that in turn are dependent on ion transport regulation systems. Plants use H+ ions pooled in vacuoles and the apoplast to transport various substances; these proton gradients are also dependent on secondary active transporters. We also compared the numbers of membrane transporter genes in Arabidopsis and rice. Although many transporter genes are similar in these plants, Arabidopsis has a more diverse array of genes for multi-efflux transport and for response to stress signals, and rice has more secondary transporter genes for carbohydrate and nutrient transport.

Development of a novel data mining tool to find cis-elements in rice gene promoter regions

BackgroundInformation on more than 35 000 full-length Oryza sativa cDNAs, together with associated microarray gene expression data collected under various treatment conditions, has made it feasible to identify motifs that are conserved in gene promoters and may act as cis-regulatory elements with key roles under the various conditions.ResultsWe have developed a novel tool that searches for cis-element candidates in the upstream, downstream, or coding regions of differentially regulated genes. The tool first lists cis-element candidates by motif searching based on the supposition that if there are cis-elements playing important roles in the regulation of a given set of genes, they will be statistically overrepresented and will be conserved. Then it evaluates the likelihood scores of the listed candidate motifs by association rule analysis. This strategy depends on the idea that motifs overrepresented in the promoter region could play specific roles in the regulation of expression of these genes. The tool is designed so that any biological researchers can use it easily at the publicly accessible Internet site http://hpc.irri.cgiar.org/tool/nias/ces. We evaluated the accuracy and utility of the tool by using a dataset of auxin-inducible genes that have well-studied cis-elements. The test showed the effectiveness of the tool in identifying significant relationships between cis-element candidates and related sets of genes.ConclusionThe tool lists possible cis-element motifs corresponding to genes of interest, and it will contribute to the deeper understanding of gene regulatory mechanisms in plants.

Rapid turnover of antimicrobial-type cysteine-rich protein genes in closely related Oryza genomes

Defensive and reproductive protein genes undergo rapid evolution. Small, cysteine-rich secreted peptides (CRPs) act as antimicrobial agents and function in plant intercellular signaling and are over-represented among reproductively expressed proteins. Because of their roles in defense, reproduction and development and their presence in multigene families, CRP variation can have major consequences for plant phenotypic and functional diversification. We surveyed the CRP genes of six closely related Oryza genomes comprising Oryza sativa ssp. japonica and ssp. indica, Oryza glaberrima and three accessions of Oryza rufipogon to observe patterns of evolution in these gene families and the effects of variation on their gene expression. These Oryza genomes, like other plant genomes, have accumulated large reservoirs of CRP sequences, comprising 26 groups totaling between 676 and 843 genes, in contrast to antimicrobial CRPs in animal genomes. Despite the close evolutionary relationships between the genomes, we observed rapid changes in number and structure among CRP gene families. Many CRP sequences are in gene clusters generated by local duplications, have undergone rapid turnover and are more likely to be silent or specifically expressed. By contrast, conserved CRP genes are more likely to be highly and broadly expressed. Variable CRP genes created by repeated duplication, gene modification and inactivation can gain new functions and expression patterns in newly evolved gene copies. For the CRP proteins, the process of gain/loss by deletion or duplication at gene clusters seems to be an important mechanism in evolution of the gene families, which also contributes to their expression evolution.

The Evolutionary Diversification of Genes that Encode Transcription Factor Proteins in Plants

The total number of genes encoding for transcription factors (TFs) varies more widely in plants than in multicellular animals. An analysis of the features of TF DNA-binding structures indicated that zinc (Zn)-coordinating factor genes, or Zn finger proteins, are particularly divergent in animals, whereas in plants, genes containing DNA-binding domains other than Zn finger proteins are more divergent. Genes that encode for TFs in unicellular organisms, invertebrates, vertebrates, ferns, mosses, and seed plants show stage-specific features of evolutionary diversification during the evolutionary process. The emergence of new types of TF genes appeared during evolution from single-celled organisms to multicellular animals and terrestrial plants.