Phosphoinositides affect both the cellular distribution and activity of the F-BAR-containing RhoGAP Rgd1p in yeast

Cell polarity is a key element of development in most eukaryotes. The Rho GTPase-activating protein Rgd1p positively regulates the GTPase activity of Rho3p and Rho4p, which are involved in bud growth and cytokinesis, respectively, in the budding yeast Saccharomyces cerevisiae. Rgd1p contains an F-BAR domain at its N-terminal end in addition to its RhoGAP domain at its C-terminal end. We demonstrate here that phospholipids discriminate between the GTPase activities of Rho3p and Rho4p through Rgd1p and specifically stimulate the RhoGAP activity on Rho4p. The central region of the protein contiguous to the F-BAR domain is required for this stimulation. The F-BAR region binds to phosphoinositides in vitro and also plays a key role in the localization of Rgd1p to the bud tip and neck during the cell cycle. Studies of heat-sensitive mutants lacking phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-biphosphate suggested that Rgd1p initially binds to Golgi membranes via phosphatidylinositol 4-phosphate and is then transported to the plasma membrane, where it binds phosphatidylinositol 4,5-biphosphate. We demonstrate here the dual effects of phosphoinositides on a RhoGTPase-activating protein. Phosphoinositides both regulate the recruitment and trafficking of Rgd1p to membranes via the F-BAR domain and specifically stimulate GTPase-activating protein activity, consistent with functional interplay between lipids, RhoGAP, and its related GTPases in yeast growth.     

Intramolecular activation mechanism of the Dictyostelium LRRK2 homolog Roco protein GbpC

GbpC is a large multidomain protein involved in cGMP-mediated chemotaxis in the cellular slime mold Dictyostelium discoideum. GbpC belongs to the Roco family of proteins that often share a central core region, consisting of leucine-rich repeats, a Ras domain (Roc), a Cor domain, and a MAPKKKinase domain. In addition to this core, GbpC contains a RasGEF domain and two cGMP-binding domains. Here, we report on an intramolecular signaling cascade of GbpC. In vitro, the RasGEF domain of GbpC specifically accelerates the GDP/GTP exchange of the Roc domain. Moreover, cGMP binding to GbpC strongly stimulates the binding of GbpC to GTP-agarose, suggesting cGMP-stimulated GDP/GTP exchange at the Roc domain. The function of the protein in vivo was investigated by rescue analysis of the chemotactic defect of gbpC null cells. Mutants that lack a functional guanine exchange factor (GEF), Roc, or kinase domain are inactive in vivo. Together, the results suggest a four-step intramolecular activation mechanism of the Roco protein GbpC: cGMP binding to the cyclic nucleotide-binding domains, activation of the GEF domain, GDP/GTP exchange of Roc, and activation of the MAPKKK domain.     

PPARgamma-dependent and -independent effects of rosiglitazone on lipotoxic human pancreatic islets

We explored the in vitro effects of Rosiglitazone (RZG), a PPARγ agonist, on human pancreatic islet dysfunctions induced by chronic free fatty acid exposure. We demonstrated that RZG beneficial effects on insulin secretion and apoptosis did not imply PDX-1 or insulin gene modulation. It rather involved, through a PPARγ-dependent mechanism, a reduction of iNOS overexpressed in lipotoxic islets. This reduction likely led to the restoration of ATP level and insulin secretion as well as the decrease in apoptosis. More interestingly, we also demonstrated that RZG beneficial effects involved PPARγ-independent mechanisms. RZG treatment led to a limitation of oxidative stress exemplified by an increase of GPx and SOD expression. It also increased UCP2 expression that seemed to display antioxidant action in this model. Thus, RZG did not appear to exert a direct action on insulin expression but rather an indirect action on insulin secretion and apoptosis, through PPARγ-dependent and -independent mechanisms, via regulation of nitrogen and oxygen reactive species injury.     

Identification of dkk4 as a target of Eda-A1/Edar pathway reveals an unexpected role of ectodysplasin as inhibitor of Wnt signalling in ectodermal placodes

The development of epithelial appendages, including hairs, glands and teeth starts from ectodermal placodes, and is regulated by interplay of stimulatory and inhibitory signals. Ectodysplasin-A1 (Eda-A1) and Wnts are high in hierarchy of placode activators. To identify direct targets of ectodysplasin pathway, we performed microarray profiling of genes differentially regulated by short exposure to recombinant Eda-A1 in embryonic eda^−/− skin explants. Surprisingly, there were only two genes with obvious involvement in Wnt pathway: dkk4 (most highly induced gene in the screen), and lrp4. Both genes colocalized with Eda-A1 receptor Edar in placodes of ectodermal organs. They were upregulated upon Edar activation while several other Wnt associated genes previously suggested as Edar targets were unaffected. However, low dkk4 and lrp4 expression was retained in the absence of NF-κB signalling in eda^−/− hair placodes. We provide evidence that this expression was dependent on Wnt activity present prior to Eda-A1/Edar signalling. Dkk4 was recently suggested as a key Wnt antagonist regulating lateral inhibition essential for correct patterning of hair follicles. Several pieces of evidence suggest Lrp4 as a Wnt inhibitor, as well. The finding that Eda-A1 induces placode inhibitors was unexpected, and underlines the importance of delicate fine-tuning of signalling during placode formation.     

Fraction of informative recombinations: a heuristic approach to analyze recombination rates

In this article we present a new heuristic approach (informative recombinations, InfRec) to analyze recombination density at the sequence level. InfRec is intuitive and easy and combines previously developed methods that (i) resolve genotypes into haplotypes, (ii) estimate the minimum number of recombinations, and (iii) evaluate the fraction of informative recombinations. We tested this approach in its sliding-window version on 117 genes from the SeattleSNPs program, resequenced in 24 African-Americans (AAs) and 23 European-Americans (EAs). We obtained population recombination rate estimates (rho(obs)) of 0.85 and 0.37 kb(-1) in AAs and EAs, respectively. Coalescence simulations indicated that these values account for both the recombinations and the gene conversions in the history of the sample. The intensity of rho(obs) varied considerably along the sequence, revealing the presence of recombination hotspots. Overall, we observed approximately 80% of recombinations in one-third and approximately 50% in only 10% of the sequence. InfRec performance, tested on published simulated and additional experimental data sets, was similar to that of other hotspot detection methods. Fast, intuitive, and visual, InfRec is not constrained by sample size limitations. It facilitates understanding data and provides a simple and flexible tool to analyze recombination intensity along the sequence.     

Brain size predicts the success of mammal species introduced into novel environments

Large brains, relative to body size, can confer advantages to individuals in the form of behavioral flexibility. Such enhanced behavioral flexibility is predicted to carry fitness benefits to individuals facing novel or altered environmental conditions, a theory known as the brain size-environmental change hypothesis. Here, we provide the first empirical link between brain size and survival in novel environments in mammals, the largest-brained animals on Earth. Using a global database documenting the outcome of more than 400 introduction events, we show that mammal species with larger brains, relative to their body mass, tend to be more successful than species with smaller brains at establishing themselves when introduced to novel environments, when both taxonomic and regional autocorrelations are accounted for. This finding is robust to the effect of other factors known to influence establishment success, including introduction effort and habitat generalism. Our results replicate similar findings in birds, increasing the generality of evidence for the idea that enlarged brains can provide a survival advantage in novel environments.     

Large-scale characterization of natural ligands explains the unique gluten-binding properties of HLA-DQ2

Celiac disease is an enteropathy caused by intolerance to dietary gluten. The disorder is strongly associated with DQA1*0501/DQB1*0201 (HLA-DQ2) as approximately 95% of celiac patients express this molecule. HLA-DQ2 has unique Ag-binding properties that allow it to present a diverse set of gluten peptides to gluten-reactive CD4+ T cells so instigating an inflammatory reaction. Previous work has indicated that the presence of negatively charged amino acids within gluten peptides is required for specific binding. This, however, only partly explains the scale of the interaction. We have now characterized 432 natural ligands of HLA-DQ2 representing length variants of 155 distinct sequences. The sequences were aligned and the binding cores were inferred. Analysis of the amino acid distribution of these cores demonstrated that negatively charged residues in HLA-DQ2-bound peptides are favored at virtually all positions. This contrasts with a more restricted presence of such amino acids in T cell epitopes from gluten. Yet, HLA-DQ2 was also found to display a strong preference for proline at several anchor and nonanchor positions that largely match the position of proline in gluten T cell epitopes. Consequently, the bias for proline at p6 and p8 facilitates the enzymatic conversion of glutamine into glutamic acid in gluten peptides at p4 and p6, two important anchor sites. These observations provide new insights in the unique ability of HLA-DQ2 to bind a large repertoire of glutamine- and proline-rich gluten peptides. This knowledge may be an important asset in the development of future treatment strategies.     

Genotypic and Phenotypic Diversity within Species of Purple Nonsulfur Bacteria Isolated from Aquatic Sediments

To assess the extent of genotypic and phenotypic diversity within species of purple nonsulfur bacteria found in aquatic sediments, a total of 128 strains were directly isolated from agar plates that had been inoculated with sediment samples from Haren and De Biesbosch in The Netherlands. All isolates were initially characterized by BOX-PCR genomic DNA fingerprinting, and 60 distinct genotypes were identified. Analyses of 16S rRNA gene sequences of representatives of each genotype showed that five and eight different phylotypes of purple nonsulfur bacteria were obtained from the Haren and De Biesbosch sites, respectively. At the Haren site, 80.5% of the clones were Rhodopseudomonas palustris, whereas Rhodoferax fermentans and Rhodopseudomonas palustris were numerically dominant at the De Biesbosch site and constituted 45.9 and 34.4% of the isolates obtained, respectively. BOX-PCR genomic fingerprints showed that there was a high level of genotypic diversity within each of these species. The genomic fingerprints of Rhodopseudomonas palustris isolates were significantly different for isolates from the two sampling sites, suggesting that certain strains may be endemic to each sampling site. Not all Rhodopseudomonas palustris isolates could degrade benzoate, a feature that has previously been thought to be characteristic of the species. There were differences in the BOX-PCR genomic fingerprints and restriction fragment length polymorphisms of benzoate-coenzyme A ligase genes and form I and form II ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) genes between benzoate-degrading and non-benzoate-degrading genotypes. The ability to distinguish these two Rhodopseudomonas palustris groups based on multiple genetic differences may reflect an incipient speciation event resulting from adaptive evolution to local environmental conditions.     

Towards the saturation of the pepper linkage map by alignment of three intraspecific maps including known-function genes.

Three populations composed of a total of 215 doubled haploid lines and 151 F2 individuals were used to design an intraspecific consensus map of pepper (Capsicum annuum L.). The individual maps varied from 685 to 1668 cM with 16 to 20 linkage groups (LGs). The alignment of the three individual maps permitted the arrangement of 12 consensus major linkage groups corresponding to the basic chromosome number of pepper and displaying a complex correspondence with the tomato map. The consensus map contained 100 known-function gene markers and 5 loci of agronomic interest (the disease-resistance loci L, pvr2, and Pvr4; the C locus, which determines capsaicin content; and the up locus, controlling the erect habit of the fruits). The locations of three other disease-resistance loci (Tsw, Me3, and Bs3) and the y locus, which determines the yellow fruit colour, were also found on this consensus map thanks to linked markers. Here we report on the first functional detailed map in pepper. The use of candidate gene sequences as genetic markers allowed us to localize four clusters of disease-resistance gene analogues and to establish syntenic relationships with other species.