Integrin α11ß1 is a receptor for collagen XIII.

Collagen XIII is a conserved transmembrane collagen mainly expressed in mesenchymal tissues. Previously, we have shown that collagen XIII modulates tissue development and homeostasis. Integrins are a family of receptors that mediate signals from the environment into the cells and vice versa. Integrin α11ß1 is a collagen receptor known to recognize the GFOGER (O=hydroxyproline) sequence in collagens. Interestingly, collagen XIII and integrin α11ß1 both have a role in the regulation of bone homeostasis. To study whether α11ß1 is a receptor for collagen XIII, we utilized C2C12 cells transfected to express α11ß1 as their only collagen receptor. The interaction between collagen XIII and integrin α11ß1 was also confirmed by surface plasmon resonance and pull-down assays. We discovered that integrin α11ß1 mediates cell adhesion to two collagenous motifs, namely GPKGER and GF(S)QGEK, that were shown to act as the recognition sites for the integrin α11-I domain. Furthermore, we studied the in vivo significance of the α11ß1-collagen XIII interaction by crossbreeding α11 null mice (Itga11-/-) with mice overexpressing Col13a1 (Col13a1oe). When we evaluated the bone morphology by microcomputed tomography, Col13a1oe mice had a drastic bone overgrowth followed by severe osteoporosis, whereas the double mutant mouse line showed a much milder bone phenotype. To conclude, our data identifies integrin α11ß1 as a new collagen XIII receptor and demonstrates that this ligand-receptor pair has a role in the maintenance of bone homeostasis.

Phylogenetic relationships and classification of thiolases and thiolase-like proteins of Mycobacterium tuberculosis and Mycobacterium smegmatis.

Thiolases are enzymes involved in lipid metabolism. Thiolases remove the acetyl-CoA moiety from 3-ketoacyl-CoAs in the degradative reaction. They can also catalyze the reverse Claisen condensation reaction, which is the first step of biosynthetic processes such as the biosynthesis of sterols and ketone bodies. In human, six distinct thiolases have been identified. Each of these thiolases is different from the other with respect to sequence, oligomeric state, substrate specificity and subcellular localization. Four sequence fingerprints, identifying catalytic loops of thiolases, have been described. In this study genome searches of two mycobacterial species (Mycobacterium tuberculosis and Mycobacterium smegmatis), were carried out, using the six human thiolase sequences as queries. Eight and thirteen different thiolase sequences were identified in M. tuberculosis and M. smegmatis, respectively. In addition, thiolase-like proteins (one encoded in the Mtb and two in the Msm genome) were found. The purpose of this study is to classify these mostly uncharacterized thiolases and thiolase-like proteins. Several other sequences obtained by searches of genome databases of bacteria, mammals and the parasitic protist family of the Trypanosomatidae were included in the analysis. Thiolase-like proteins were also found in the trypanosomatid genomes, but not in those of mammals. In order to study the phylogenetic relationships at a high confidence level, additional thiolase sequences were included such that a total of 130 thiolases and thiolase-like protein sequences were used for the multiple sequence alignment. The resulting phylogenetic tree identifies 12 classes of sequences, each possessing a characteristic set of sequence fingerprints for the catalytic loops. From this analysis it is now possible to assign the mycobacterial thiolases to corresponding homologues in other kingdoms of life. The results of this bioinformatics analysis also show interesting differences between the distributions of M. tuberculosis and M. smegmatis thiolases over the 12 different classes.

The first identification of carbohydrate binding modules specific to chitosan.

Two carbohydrate binding modules (DD1 and DD2) belonging to CBM32 are located at the C terminus of a chitosanase from Paenibacillus sp. IK-5. We produced three proteins, DD1, DD2, and tandem DD1/DD2 (DD1+DD2), and characterized their binding ability. Transition temperature of thermal unfolding (Tm) of each protein was elevated by the addition of cello-, laminari-, chitin-, or chitosan-hexamer (GlcN)6. The Tm elevation (ΔTm) in DD1 was the highest (10.3 °C) upon the addition of (GlcN)6 and was markedly higher than that in DD2 (1.0 °C). A synergistic effect was observed (ΔTm = 13.6 °C), when (GlcN)6 was added to DD1+DD2. From isothermal titration calorimetry experiments, affinities to DD1 were not clearly dependent upon chain length of (GlcN)n; ΔGr° values were -7.8 (n = 6), -7.6 (n = 5), -7.6 (n = 4), -7.6 (n = 3), and -7.1 (n = 2) kcal/mol, and the value was not obtained for GlcN due to the lowest affinity. DD2 bound (GlcN)n with the lower affinities (ΔGr° = -5.0 (n = 3) ~ -5.2 (n = 6) kcal/mol). Isothermal titration calorimetry profiles obtained for DD1+DD2 exhibited a better fit when the two-site model was used for analysis and provided greater affinities to (GlcN)6 for individual DD1 and DD2 sites (ΔGr° = -8.6 and -6.4 kcal/mol, respectively). From NMR titration experiments, (GlcN)n (n = 2~6) were found to bind to loops extruded from the core ß-sandwich of individual DD1 and DD2, and the interaction sites were similar to each other. Taken together, DD1+DD2 is specific to chitosan, and individual modules synergistically interact with at least two GlcN units, facilitating chitosan hydrolysis.

Phylogenetic analysis and selection pressures of 5-HT receptors in human and non-human primates: receptor of an ancient neurotransmitter.

Neurotransmitter serotonin (5-hydroxytryptamine, 5-HT) an ancient neurotransmitter, involved in several neurophysiological and behavioral functions, acts by interacting with multiple receptors (5-HT(1)-5-HT(7)). Alterations in serotonergic signalling have also been implicated in various psychiatric disorders. The availability of the genome data of non-human primates permits comparative analysis of human 5-HT receptors with sequences of non-human primates to understand evolutionary divergence. We compared and analyzed serotonergic receptor sequences from human and non-human primates. Phylogenetic analysis by Maximum Likelihood (ML) method classified human and primate 5-HT receptors into six unique clusters. There was considerable conservation of 5-HT receptor sequences between human and non-human primates; however, a greater diversity at the sub-group level was observed. Compared to the other subgroups, larger multiplicity and expansion was seen within the 5-HT(4) receptor subtype in both human and non-human primates. Analysis of non-synonymous and synonymous substitution ratios (Ka/Ks ratio) using the Nei-Gojobori method suggests that 5-HT receptor sequences have undergone negative (purifying) selection over the course of evolution in human, chimpanzee and rhesus monkey. Abnormal human and non-human primate psychopathalogy and behavior, in the context of these variations is discussed. Analysis of these 5-HT receptors in other species will help understand the molecular evolution of 5-HT receptors, and its possible influence on complex behaviors, and psychiatric disorders.

Evolutionary analysis of PHLPP1 gene in humans and non-human primates.

The chromosome 18q22-23 region has been shown to be implicated in bipolar disorder (BPAD) by several studies. PHLPP1 gene, in the locus (chromosome 18q22-23), is involved in circadian pathways and bears modules like 'PH domain and leucine rich repeat protein phosphatase'. This gene also contains a polyglutamine (CAG or PolyQ) repeat motif at the carboxyl terminal end. A comparative analysis of the PolyQ repeats of the PHLPP1 gene in humans, non-human primates and other species has been attempted in order to investigate the possible significance of repeat length as seen in other triplet-repeat associated diseases. Sequencing of the CAG repeat in humans and in non-human primates revealed that the CAG repeat is not polymorphic in humans; whereas, in other species it shows an area of high variability, both in length and sequence composition. Despite the conservation of circadian clock components in different species, there is remarkable diversity in the protein structure, regulation and biochemical functions of the circadian orthologs. These can be due to specific adaptations in accordance with the physiology of the particular species providing a species-specific biological advantage.