We report the latest release (version 3.0) of the CATH protein domain database (). There has been a 20% increase in the number of structural domains classified in CATH, up to 86 151 domains. Release 3.0 comprises 1110 fold groups and 2147 homologous superfamilies. To cope with the increases in diverse structural homologues being determined by the structural genomics initiatives, more sensitive methods have been developed for identifying boundaries in multi-domain proteins and for recognising homologues. The CATH classification update is now being driven by an integrated pipeline that links these automated procedures with validation steps, that have been made easier by the provision of information rich web pages summarising comparison scores and relevant links to external sites for each domain being classified. An analysis of the population of domains in the CATH hierarchy and several domain characteristics are presented for version 3.0. We also report an update of the CATH Dictionary of homologous structures (CATH-DHS) which now contains multiple structural alignments, consensus information and functional annotations for 1459 well populated superfamilies in CATH. CATH is directly linked to the Gene3D database which is a projection of CATH structural data onto ∼2 million sequences in completed genomes and UniProt.
We recently have identified an antigen receptor in sharks called NAR (new or nurse shark antigen receptor) that is secreted by splenocytes but does not associate with Ig light (L) chains. The NAR variable (V) region undergoes high levels of somatic mutation and is equally divergent from both Ig and T cell receptors (TCR). Here we show by electron microscopy that NAR V regions, unlike those of conventional Ig and TCR, do not form dimers but rather are independent, f lexible domains. This unusual feature is analogous to bona fide camelid IgG in which modifications of Ig heavy chain V (V H ) sequences prevent dimer formation with L chains. NAR also displays a uniquely f lexible constant (C) region. Sequence analysis and modeling show that there are only two types of expressed NAR genes, each having different combinations of noncanonical cysteine (Cys) residues in the V domains that likely form disulfide bonds to stabilize the single antigen-recognition unit. In one NAR class, rearrangement events result in mature genes encoding an even number of Cys (two or four) in complementarity-determining region 3 (CDR3), which is analogous to Cys codon expression in an unusual human diversity (D) segment family. The NAR CDR3 Cys generally are encoded by preferred reading frames of rearranging D segments, providing a clear design for use of preferred reading frame in antigen receptor D regions. These unusual characteristics shared by NAR and unconventional mammalian Ig are most likely the result of convergent evolution at the molecular level.At the heart of the adaptive immune system are the antigen receptors, Ig and T cell receptor (TCR), that are generated in anticipation of recognition of pathogens (1). The typical antigen receptor is composed of two polypeptide chains [heavy (H) and light (L) for Igs and ␣ and  or ␥ and ␦ for TCRs]. Each chain, in turn, is composed of a single, variable (V) domain at the N-terminal end followed by one to seven constant (C) domains. C domains define the effector functions characteristic of a given class of Ig whereas V domains each display a unique sequence and structure defining antigen specificity. Igs can be subdivided further into Fab and Fc fragments, responsible for antigen binding and for effector function, respectively. Ig and TCR V regions are encoded by a mosaic of genes ligated together somatically during lymphocyte ontogeny (2). Specifically, single V and J elements are joined together at the DNA level for Ig L chain or TCR ␣ and ␥ V regions. In Ig H chains and TCR  and ␦ chains, one or, occasionally, two D elements are joined between the V and J segments. Together, the V, (D), and J elements encode framework (FR, responsible for protein folding and structure) and complementarity-determining regions (CDR, responsible for antigen interactions) within the V domains.The evolutionary origin of antigen receptors is unknown, but the first indication of their emergence phylogenetically is in cartilaginous fish (sharks, skates, and rays), where at least three types of Ig (3-9)...
BackgroundChitinases are prevalent in life and are found in species including archaea, bacteria, fungi, plants, and animals. They break down chitin, which is the second most abundant carbohydrate in nature after cellulose. Hence, they are important for maintaining a balance between carbon and nitrogen trapped as insoluble chitin in biomass. Chitinases are classified into two families, 18 and 19 glycoside hydrolases. In addition to a catalytic domain, which is a triosephosphate isomerase barrel, many family 18 chitinases contain another module, i.e., chitinase insertion domain. While numerous studies focus on the biological role of the catalytic domain in chitinase activity, the function of the chitinase insertion domain is not completely understood. Bioinformatics offers an important avenue in which to facilitate understanding the role of residues within the chitinase insertion domain in chitinase function.ResultsTwenty-seven chitinase insertion domain sequences, which include four experimentally determined structures and span five kingdoms, were aligned and analyzed using a modified sequence entropy parameter. Thirty-two positions with conserved residues were identified. The role of these conserved residues was explored by conducting a structural analysis of a number of holo-enzymes. Hydrogen bonding and van der Waals calculations revealed a distinct subset of four conserved residues constituting two sequence motifs that interact with oligosaccharides. The other conserved residues may be key to the structure, folding, and stability of this domain.ConclusionsSequence and structural studies of the chitinase insertion domains conducted within the framework of evolution identified four conserved residues which clearly interact with the substrates. Furthermore, evolutionary studies propose a link between the appearance of the chitinase insertion domain and the function of family 18 chitinases in the subfamily A.
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