The rapid assignment of ruminal fungi to presumptive genera using ITS1 and ITS2 RNA secondary structures to produce group-specific fingerprints.

Identification of microbial community members in complex environmental samples is time consuming and repetitive. Here, ribosomal sequences and hidden Markov models are used in a novel approach to rapidly assign fungi to their presumptive genera. The ITS1 and ITS2 fragments from a range of axenic, anaerobic gut fungal cultures, including several type strains, were isolated and the RNA secondary structures predicted for these sequences were used to generate a fingerprinting program. The methodology was then tested and the algorithms improved using a collection of environmentally derived sequences, providing a rapid indicator of the fungal diversity and numbers of novel sequence groups within the environmental sample from which they were derived. While the methodology was developed to assist in investigations involving the rumen ecosystem, it has potential generic application in studying diversity and population dynamics in other microbial ecosystems.

The alpha2beta1 integrin inhibitor rhodocetin binds to the A-domain of the integrin alpha2 subunit proximal to the collagen-binding site.

Rhodocetin is a snake venom protein that binds to alpha2beta1 integrin, inhibiting its interaction with its endogenous ligand collagen. We have determined the mechanism by which rhodocetin inhibits the function of alpha2beta1. The interaction of alpha2beta1 with collagen and rhodocetin differed: Ca(2+) ions and slightly acidic pH values increased the binding of alpha2beta1 integrin to rhodocetin in contrast with their attenuating effect on collagen binding, suggesting that rhodocetin preferentially binds to a less active conformation of alpha2beta1 integrin. The alpha2A-domain [von Willebrand factor domain A homology domain (A-domain) of the integrin alpha2 subunit] is the major site for collagen binding to alpha2beta1. Recombinant alpha2A-domain bound rhodocetin, demonstrating that the A-domain is also the rhodocetin-binding domain. Although the interaction of alpha2beta1 with rhodocetin is affected by altering divalent cations, the interaction of the A-domain was divalent-cation-independent. The rhodocetin-binding site on the alpha2A-domain was mapped first by identifying an anti-alpha2 antibody that blocked rhodocetin binding and then mapping the epitope of the antibody using human-mouse alpha2A-domain chimaeras; and secondly, by binding studies with alpha2A-domain, which bear point mutations in the vicinity of the mapped epitope. In this way, the rhodocetin-binding site was identified as the alpha3-alpha4 loop plus adjacent alpha-helices. This region is known to form part of the collagen-binding site, thus attaining a mainly competitive mode of inhibition by rhodocetin.

A novel and highly conserved collagen (pro(alpha)1(XXVII)) with a unique expression pattern and unusual molecular characteristics establishes a new clade within the vertebrate fibrillar collagen family.

The type XXVII collagen gene codes for a novel vertebrate fibrillar collagen that is highly conserved in man, mouse, and fish (Fugu rubripes). The pro(alpha)1(XXVII) chain has a domain structure similar to that of the type B clade chains (alpha1(V), alpha3(V), alpha1(XI), and alpha2(XI)). However, compared with other vertebrate fibrillar collagens (types I, II, III, V, and XI), type XXVII collagen has unusual molecular features such as no minor helical domain, a major helical domain that is short and interrupted, and a short chain selection sequence within the NC1 domain. Pro(alpha)1(XXVII) mRNA is 9 kb and expressed by chondrocytes but also by a variety of epithelial cell layers in developing tissues including stomach, lung, gonad, skin, cochlear, and tooth. By Western blotting, type XXVII antisera recognized multiple bands of 240-110 kDa in tissue extracts and collagenous bands of 150-140 kDa in the conditioned medium of the differentiating chondrogenic ATDC5 cell line. Phylogenetic analyses revealed that type XXVII, together with the closely related type XXIV collagen gene, form a new, third clade (type C) within the vertebrate fibrillar collagen family. Furthermore, the exon structure of the type XXVII collagen gene is similar to, but distinct from, those of the genes coding for the type A or B clade pro(alpha) chains.

Fibrillar collagen: the key to vertebrate evolution? A tale of molecular incest.

Fibril-forming (fibrillar) collagens are extracellular matrix proteins conserved in all multicellular animals. Vertebrate members of the fibrillar collagen family are essential for the formation of bone and teeth, tissues that characterise vertebrates. The potential role played by fibrillar collagens in vertebrate evolution has not been considered previously largely because the family has been around since the sponge and it was unclear precisely how and when those particular members now found in vertebrates first arose. We present evidence that the classical vertebrate fibrillar collagens share a single common ancestor that arose at the very dawn of the vertebrate world and prior to the associated genome duplication events. Furthermore, we present a model, 'molecular incest', that not only accounts for the characteristics of the modern day vertebrate fibrillar collagen family but demonstrates the specific effects genome or gene duplications may have on the evolution of multimeric proteins in general.