The Rice Annotation Project Database (RAP-DB): 2008 update.

The Rice Annotation Project Database (RAP-DB) was created to provide the genome sequence assembly of the International Rice Genome Sequencing Project (IRGSP), manually curated annotation of the sequence, and other genomics information that could be useful for comprehensive understanding of the rice biology. Since the last publication of the RAP-DB, the IRGSP genome has been revised and reassembled. In addition, a large number of rice-expressed sequence tags have been released, and functional genomics resources have been produced worldwide. Thus, we have thoroughly updated our genome annotation by manual curation of all the functional descriptions of rice genes. The latest version of the RAP-DB contains a variety of annotation data as follows: clone positions, structures and functions of 31 439 genes validated by cDNAs, RNA genes detected by massively parallel signature sequencing (MPSS) technology and sequence similarity, flanking sequences of mutant lines, transposable elements, etc. Other annotation data such as Gnomon can be displayed along with those of RAP for comparison. We have also developed a new keyword search system to allow the user to access useful information. The RAP-DB is available at: http://rapdb.dna.affrc.go.jp/ and http://rapdb.lab.nig.ac.jp/.

The H-Invitational Database (H-InvDB), a comprehensive annotation resource for human genes and transcripts.

Here we report the new features and improvements in our latest release of the H-Invitational Database (H-InvDB; http://www.h-invitational.jp/), a comprehensive annotation resource for human genes and transcripts. H-InvDB, originally developed as an integrated database of the human transcriptome based on extensive annotation of large sets of full-length cDNA (FLcDNA) clones, now provides annotation for 120 558 human mRNAs extracted from the International Nucleotide Sequence Databases (INSD), in addition to 54 978 human FLcDNAs, in the latest release H-InvDB_4.6. We mapped those human transcripts onto the human genome sequences (NCBI build 36.1) and determined 34 699 human gene clusters, which could define 34 057 (98.1%) protein-coding and 642 (1.9%) non-protein-coding loci; 858 (2.5%) transcribed loci overlapped with predicted pseudogenes. For all these transcripts and genes, we provide comprehensive annotation including gene structures, gene functions, alternative splicing variants, functional non-protein-coding RNAs, functional domains, predicted sub cellular localizations, metabolic pathways, predictions of protein 3D structure, mapping of SNPs and microsatellite repeat motifs, co-localization with orphan diseases, gene expression profiles, orthologous genes, protein-protein interactions (PPI) and annotation for gene families. The current H-InvDB annotation resources consist of two main views: Transcript view and Locus view and eight sub-databases: the DiseaseInfo Viewer, H-ANGEL, the Clustering Viewer, G-integra, the TOPO Viewer, Evola, the PPI view and the Gene family/group.

N-terminal mutational analysis of the interaction between growth-blocking peptide (GBP) and receptor of insect immune cells.

GBP, a small insect cytokine isolated from lepidopterans, has a variety of functions. We constructed a series of mutants focusing on the unstructured N-terminal residues of GBP by acetylation, deletion, and elongation in order to investigate the interaction between GBP and its receptor in plasmatocytes. The 1H NMR spectra showed no significant changes in the tertiary structures of these peptides, which indicated that all the mutants maintained their core beta-sheet structures. The deletion and acetylated mutants, 2-25GBP, Ac2-25GBP, and AcGBP, lost their activity. 2-25GBP was the strongest antagonist, while Ac2-25GBP and AcGBP were moderate. In contrast, the elongated mutants, (-1R)GBP, (-1A)GBP, and (-2G,-1R)GBP maintained their plasmatocyte-spreading activity. These results demonstrate the importance of the GBP N-terminal charged amine and length of N-terminal GBP-peptide backbone for plasmatocyte-spreading activity. Next, we analyzed other mutant peptides, 1-25(N2A)GBP and 2-25(N2A)GBP, focusing on Asn2. Surprisingly, 2-25(N2A)GBP had slight plasmatocyte-spreading activity, whereas 2-25GBP lost its activity. Finally, substituted mutant, F3AGBP, had neither plasmatocyte-spreading activity nor antagonistic activity. These results demonstrate the function of each N-terminal residue in the interaction between GBP and its receptor in plasmatocytes.

Solution structure of epiregulin and the effect of its C-terminal domain for receptor binding affinity.

Epiregulin (EPR), a novel member of epidermal growth factor (EGF) family, is a ligand for ErbB-1 and ErbB-4 receptors. The binding affinity of EPR for the receptors is lower than those of other EGF-family ligands. The solution structure of EPR was determined using two-dimensional nuclear magnetic resonance spectroscopy. The secondary structure in the C-terminal domain of EPR is different from other EGF-family ligands because of the lack of hydrogen bonds. The structural difference in the C-terminal domain may provide an explanation for the reduced binding affinity of EPR to the ErbB receptors.

Preparation and observation of fresh-frozen sections of the green fluorescent protein transgenic mouse head.

Hard tissue decalcification can cause variation in the constituent protein characteristics. This paper describes a method of preparating of frozen mouse head sections so as to clearly observe the nature of the constituent proteins. Frozen sections of various green fluorescent protein (GFP) transgenic mouse heads were prepared using the film method developed by Kawamoto and Shimizu. This method made specimen dissection without decalcification possible, wherein GFP was clearly observed in an undamaged state. Conversely, using the same method with decalcification made GFP observation in the transgenic mouse head difficult. This new method is suitable for observing GFP marked cells, enabling us to follow the transplanted GFP marked cells within frozen head sections.

Stabilization of protein by replacement of a fluctuating loop: structural analysis of a chimera of bovine alpha-lactalbumin and equine lysozyme.

Equine lysozyme is a calcium-binding lysozyme and an evolutional intermediate between non-calcium binding c-type lysozyme and alpha-lactalbumin. We constructed a chimeric protein by substituting the fluctuating loop of bovine alpha-lactalbumin with the D-helix of equine lysozyme. The substitution affects the protection factors not only in the fluctuating loop but also in the antiparallel beta-sheet, the A- and B-helices, and the loop between the B-helix and the beta-sheet. Amide protons in these regions of the chimera are more protected from exchange than are those of bovine alpha-lactalbumin. We used model-free analysis based on 15N nuclear magnetic resonance relaxation measurements to investigate the dynamics of the main chain of the chimera and showed that the fluctuating loop of the chimera is as rigid as three major helices. When we analyzed the chemical shift deviations and backbone HN-H(alpha) scalar coupling constants, we found that the chimera showed an alpha-helical tendency in residues around the fluctuating loop. Our results suggest that the replacement of a highly fluctuating loop in a protein with a rigid structural element in a homologous one may be useful to stabilize the protein structure.

Roles of aromatic residues in the structure and biological activity of the small cytokine, growth-blocking peptide (GBP).

Growth-blocking peptide (GBP) is a small (25 amino acids) insect cytokine with a variety of functions: controlling the larval development of lepidopteran insects, acting as a mitogen for various types of cultured cells, and stimulating insect blood cells. The aromatic residues of GBP (Phe-3, Tyr-11, and Phe-23) are highly conserved in the ENF peptide family found in lepidopteran insects. We investigated the relationship between the biological activities and structural properties of a series of GBP mutants, in which each of the three aromatic residues is replaced by a different residue. The results of the hemocytes-stimulating assays of GBP mutants indicated that Phe-3 is the key residue in this activity: Ala or Tyr replacement resulted in significant loss of the activity, but Leu replacement did not. The replacements of other aromatic residues hardly affected the activity. On the other hand, NMR analysis of the mutants suggested that Tyr-11 is a key residue for maintaining the core structure of GBP. Surprisingly, the Y11A mutant maintained its biological activity, although its native-like secondary structure was disordered. Detailed analyses of the (15)N-labeled Y11A mutant by heteronuclear NMR spectroscopy showed that the native-like beta-sheet structure of Y11A was induced by the addition of 2,2,2-trifluoroethanol. The results suggest that Y11A has a tendency to form a native-like structure, and this property may give the Y11A mutant native-like activity.