Ewes from the Booroola strain of Australian Mé rino sheep are characterized by high ovulation rate and litter size. This phenotype is due to the action of the FecB B allele of a major gene named FecB, as determined by statistical analysis of phenotypic data. By genetic analysis of 31 informative half-sib families from heterozygous sires, we showed that the FecB locus is situated in the region of ovine chromosome 6 corresponding to the human chromosome 4q22-23 that contains the bone morphogenetic protein receptor IB (BMPR-IB) gene encoding a member of the transforming growth factor- (TGF-) receptor family. A nonconservative substitution (Q249R) in the BMPR-IB coding sequence was found to be associated fully with the hyperprolificacy phenotype of Booroola ewes. In vitro, ovarian granulosa cells from FecB B ͞FecB B ewes were less responsive than granulosa cells from FecB ؉ ͞FecB ؉ ewes to the inhibitory effect on steroidogenesis of GDF-5 and BMP-4, natural ligands of BMPR-IB. It is suggested that in FecB B ͞FecB B ewes, BMPR-IB would be inactivated partially, leading to an advanced differentiation of granulosa cells and an advanced maturation of ovulatory follicles.
The pathogen Brucella suis resides and multiplies within a phagocytic vacuole of its host cell, the macrophage. The resulting complex relationship has been investigated by the analysis of the set of genes required for virulence, which we call intramacrophagic virulome. Ten thousand two hundred and seventy-two miniTn5 mutants of B. suis constitutively expressing gfp were screened by fluorescence microscopy for lack of intracellular multiplication in human macrophages. One hundred thirty-one such mutants affected in 59 different genes could be isolated, and a function was ascribed to 53 of them. We identified genes involved in (i) global adaptation to the intracellular environment, (ii) amino acid, and (iii) nucleotide synthesis, (iv) sugar metabolism, (v) oxidoreduction, (vi) nitrogen metabolism, (vii) regulation, (viii) disulphide bond formation, and (ix) lipopolysaccharide biosynthesis. Results led to the conclusion that the replicative compartment of B. suis is poor in nutrients and characterized by low oxygen tension, and that nitrate may be used for anaerobic respiration. Intramacrophagic virulome analysis hence allowed the description of the nature of the replicative vacuole of the pathogen in the macrophage and extended our understanding of the niche in which B. suis resides. We propose calling this specific compartment ''brucellosome.'' I nteractions between microorganisms and their hosts extend from acute infections to persistent infectious diseases or symbiosis. This type of interaction can result from a million years of coevolution and coadaptation of the two organisms. Thus, the biology of the interaction can be read, at least partially, in the genome of the microorganism. In the specific case of pathogenic bacteria, deciphering of the genes involved in the interaction and analysis of their functions will shed light on the environment encountered by the parasite in the host and will contribute to the understanding of the complex relationship between two organisms. As a name for the whole set of genes required for virulence, i.e., involved in the invasion of the host by the bacteria and their adaptation to the environment provided by this host, we propose virulome. In this study, we will perform a thorough analysis of the intramacrophagic virulome of Brucella suis.Brucella spp. is an ␣ proteobacteriaceae that induces a persistent disease in some mammals, resulting in abortion. In humans, initial septicemia may be followed by a subacute or a chronic infection (1). Brucella spp. is phyletically related as well to plant symbionts such as rhizobiaceae, as to rickettsiae, which generate an acute infectious disease (2). In terms of virulence, brucellae occupy an intermediate position where the adaptation results in a mild disease that allows them to persist in mammal hosts. It is usually considered that, for a facultative intracellular bacterium such as Brucella spp., which multiplies in trophoblasts or macrophages (3), one of the challenges is to rapidly adapt to the intracellular settings but also to resis...
We show here high levels of expression and secretion of the chemokine CXCL5 in the macrophage fraction of white adipose tissue (WAT). Moreover, we find that CXCL5 is dramatically increased in serum of human obese compared to lean subjects. Conversely, CXCL5 concentration is decreased in obese subjects after a weight reduction program, or in obese non-insulin resistant, compared to insulin resistant obese subjects. Most importantly we demonstrate that treatment with recombinant CXCL5 blocks insulin-stimulated glucose uptake in muscle in mice. CXCL5 blocks insulin signaling by activating the Jak2/STAT5/SOCS2 pathway. Finally, by treating obese, insulin resistant mice with either anti-CXCL5 neutralizing antibodies or antagonists of CXCR2, which is the CXCL5 receptor we demonstrate that CXCL5 mediates insulin resistance. Furthermore CXCR2−/− mice are protected against obesity-induced insulin resistance. Taken together, these results show that secretion of CXCL5 by WAT resident macrophages represents a link between obesity, inflammation, and insulin resistance.
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