Plant GARDEN: a portal website for cross-searching between different types of genomic and genetic resources in a wide variety of plant species.

BACKGROUND: Plant genome information is fundamental to plant research and development. Along with the increase in the number of published plant genomes, there is a need for an efficient system to retrieve various kinds of genome-related information from many plant species across plant kingdoms. Various plant databases have been developed, but no public database covers both genomic and genetic resources over a wide range of plant species. MAIN BODY: We have developed a plant genome portal site, Plant GARDEN (Genome And Resource Database Entry: https://plantgarden.jp/en/index ), to provide diverse information related to plant genomics and genetics in divergent plant species. Elasticsearch is used as a search engine, and cross-keyword search across species is available. Web-based user interfaces (WUI) for PCs and tablet computers were independently developed to make data searches more convenient. Several types of data are stored in Plant GARDEN: reference genomes, gene sequences, PCR-based DNA markers, trait-linked DNA markers identified in genetic studies, SNPs, and in/dels on publicly available sequence read archives (SRAs). The data registered in Plant GARDEN as of March 2023 included 304 assembled genome sequences, 11,331,614 gene sequences, 419,132 DNA markers, 8,225 QTLs, and 5,934 SNP lists (gvcf files). In addition, we have re-annotated all the genes registered in Plant GARDEN by using a functional annotation tool, Hayai-Annotation, to compare the orthologous relationships among genes. CONCLUSION: The aim of Plant GARDEN is to provide plant genome information for use in the fields of plant science as well as for plant-based industries, education, and other relevant areas. Therefore, we have designed a WUI that allows a diverse range of users to access such information in an easy-to-understand manner. Plant GARDEN will eventually include a wide range of plant species for which genome sequences are assembled, and thus the number of plant species in the database will continue to expand. We anticipate that Plant GARDEN will promote the understanding of genomes and gene diversity by facilitating comparisons of the registered sequences.

Plant Genome DataBase Japan (PGDBj): a portal website for the integration of plant genome-related databases.

The Plant Genome DataBase Japan (PGDBj, http://pgdbj.jp/?ln=en) is a portal website that aims to integrate plant genome-related information from databases (DBs) and the literature. The PGDBj is comprised of three component DBs and a cross-search engine, which provides a seamless search over the contents of the DBs. The three DBs are as follows. (i) The Ortholog DB, providing gene cluster information based on the amino acid sequence similarity. Over 500,000 amino acid sequences of 20 Viridiplantae species were subjected to reciprocal BLAST searches and clustered. Sequences from plant genome DBs (e.g. TAIR10 and RAP-DB) were also included in the cluster with a direct link to the original DB. (ii) The Plant Resource DB, integrating the SABRE DB, which provides cDNA and genome sequence resources accumulated and maintained in the RIKEN BioResource Center and National BioResource Projects. (iii) The DNA Marker DB, providing manually or automatically curated information of DNA markers, quantitative trait loci and related linkage maps, from the literature and external DBs. As the PGDBj targets various plant species, including model plants, algae, and crops important as food, fodder and biofuel, researchers in the field of basic biology as well as a wide range of agronomic fields are encouraged to perform searches using DNA sequences, gene names, traits and phenotypes of interest. The PGDBj will return the search results from the component DBs and various types of linked external DBs.

Structure of SixA, a histidine protein phosphatase of the ArcB histidine-containing phosphotransfer domain in Escherichia coli.

Escherichia coli protein SixA was the first identified histidine protein phosphatase that dephosphorylates the histidine-containing phosphotransfer (HPt) domain of histidine kinase ArcB. The crystal structures of the free and tungstate-bound forms of SixA revealed an alpha/beta architecture with a fold unlike those previously described in eukaryotic protein phosphatases, but related to a family of phosphatases containing the arginine-histidine-glycine (RHG) motif at their active sites. Compared with these RHG phosphatases, SixA lacks an extra alpha-helical subdomain that forms a lid over the active site, thereby forming a relatively shallow groove important for accommodating the kidney-shaped four-helix bundle of the HPt domain. Sequence database searches revealed that a single SixA homolog was found in a variety of bacteria, where two homologs were found in some bacteria while no homolog was found in others. No SixA homologs were found in the majority of firmicutes and euryarchaea. Structure-based examination and multiple alignment of sequences revealed SixA active residues from loop beta1-H2, which might assist in the identification of SixA homologs among RHG phosphatases even with poor amino acid identity.

Preparation and preliminary X-ray diffraction analysis of crystals of bacterial flagellar sigma factor sigma 28 in complex with the sigma 28-binding region of its antisigma factor, FlgM.

The sigma 28 kDa (sigma28) factor is a transcription factor specific for the expression of bacterial flagellar and chemotaxis genes. Its antisigma factor, FlgM, binds sigma28 factor and inhibits its activity as a transcription factor. In this study, crystals of the complex between Escherichia coli sigma28 and the C-terminal sigma28-binding region of FlgM were obtained. The crystals belong to space group P3(1)21 or P3(2)21, with unit-cell parameters a = b = 106.7 (2), c = 51.74 (3) A, containing one complex in the crystallographic asymmetric unit. An X-ray intensity data set was collected to a resolution of 2.7 A.

Plant Genome DataBase Japan (PGDBj).

A portal website that integrates a variety of information related to genomes of model and crop plants from databases (DBs) and the literature was generated. This website, named the Plant Genome DataBase Japan (PGDBj, http://pgdbj. jp/en/ ), is comprised of three component DBs and a cross-search engine which provides a seamless search over their contents. One of the three component DBs is the Ortholog DB, which provides gene cluster information based on the amino acid sequence similarity. Over 1,000,000 amino acid sequences of 40 Viridiplantae species were collected from the public DNA DBs, and plant genome DBs such as TAIR and RAP-DB were subjected to reciprocal BLAST searches for clustering. Another component DB is the Plant Resource DB for genomic- and bio-resources. This DB also integrates the SABRE DB, which provides cDNA and genome sequence resources maintained in the RIKEN BioResource Center and National BioResource Projects Japan. The third component DB of PGDBj is the DNA Marker DB, which manually or automatically collects curated information on DNA markers, quantitative trait loci (QTL), and related genetic linkage maps, from the literature and external DBs. By combining these component DBs and a cross-search engine, PGDBj serves as a useful platform to study genetic systems for both fundamental and applied researches for a wide range of plant species.

How does a topological inversion change the evolutionary constraints on membrane proteins?

The members of the aquaporin family and those of the ClC chloride ion channel family consist of two-fold tandem repeats. The orientation of the N-terminal domain against membrane is opposite to that of the C-terminal domain. Several lines of evidence suggest that the extracellular and the cytoplasmic environments impose different evolutionary constraints on proteins (e.g. positive-inside rule). Therefore, the different constraints would affect the corresponding regions of the two domains, which are exposed to the different environments. To examine this hypothesis, the N- and the C-terminal domains were aligned and the difference in residue composition or conservation pattern between the two domains was calculated at each alignment site by several methods. Then, the residues corresponding to the sites exhibiting significant difference were mapped onto the tertiary structure. In spite of the difference in the methods, the mapped residues clustered on the pore surface of the channel; in contrast, the number of the residues mapped on the extracellular or cytoplasmic sides of the proteins was small. A minor modification of the methods improved the sensitivity to detect sites related to the positive-inside rule. The results support our hypothesis about the relationship between the topological inversion and the different constraints.

Positive selection in the ComC-ComD system of Streptococcal Species.

Competence-stimulating peptide (CSP) and ComD of the streptococcal species are a pheromone and its receptor, respectively, involved in the regulation of competence for natural genetic transformation. We show here that these molecules have undergone positive selection. This study is the first report of positive selection due to competition among bacterial populations.