NOX5 variants are functionally active in endothelial cells

NADPH oxidases have been identified as sources of reactive oxygen species (ROS) in vascular cells. In addition to the initially described enzyme containing gp91phox (NOX2), several homologues to NOX2 have been identified. Whereas NOX1, NOX2, and NOX4 are expressed in endothelial cells, a functional role of NOX5 containing additional N-terminal calcium-binding domains of varying sequences has not been reported in these cells. NOX5 protein was found in the endoplasmic reticulum of human microvascular endothelial cells (HMEC-1) and in the vascular wall. HMEC-1 cells expressed NOX5beta and NOX5delta as well as a variant lacking calcium-binding domains (NOX5S). NOX5beta and NOX5S increased basal ROS levels. Ionomycin exclusively enhanced NOX5beta-mediated ROS production. Although p22phox, when overexpressed, interacted with both NOX5 proteins, it was not essential for NOX5-mediated ROS production. NOX5 proteins stimulated endothelial cell proliferation and the formation of capillary-like structures whereas depletion of NOX5 by siRNA prevented these responses to thrombin. These data show that endothelial cells express different NOX5 variants including NOX5S lacking calcium-binding domains. NOX5 proteins are functional, promoting endothelial ROS production, proliferation, and the formation of capillary-like structures and contribute to the endothelial response to thrombin. These findings suggest that NOX5 variants play a novel role in controlling ROS-dependent processes in the vasculature.     

Heart development in fibronectin-null mice is governed by a genetic modifier on chromosome four

Absence of the fibronectin (FN) gene leads to early embryonic lethality in both 129S4 and C57BL/6J strains due to severe cardiovascular defects. However, heart development is arrested at different stages in these embryos depending on the genetic background. In the majority of 129S4 FN-null embryos, heart progenitors remain at their anterior bilateral positions and fail to fuse at the midline to form a heart tube. However, on the C57BL/6J genetic background, cardiac development progresses further and results in a centrally positioned and looped heart. To find factor(s) involved in embryonic heart formation and governing the extent of heart development in FN-null embryos in 129S4 and C57BL/6J strains, we performed genetic mapping and haplotype analyses. These analyses lead to identification of a significant linkage to a 1-Mbp interval on chromosome four. Microarray analysis and sequencing identified 21 genes in this region, including five that are differentially expressed between the strains, as potential modifiers. Since none of these genes was previously known to play a role in heart development, one or more of them is likely to be a novel modifier affecting cardiac development. Identification of the modifier would significantly enhance our understanding of the molecular underpinning of heart development and disease.     

The growth-hormone inducible transmembrane protein (Ghitm) belongs to the Bax inhibitory protein-like family

The conserved protein domain UPF0005 is a protein family signature distributed among many species including fungi and bacteria. Although of unknown functionality this motif has been found in newly identified antiapoptotic proteins comprising the BI-1 family, namely Bax-inhibitory Protein-1 (BI-1), Lifeguard (LFG), and h-GAAP. In a search for vertebrate proteins presumably belonging to the BI-1 family, we found that Growth-hormone inducible transmembrane protein (Ghitm) is another prospective member of the BI-1 family. Here we characterise Ghitm in a first analysis regarding its phylogeny, expression in cancer cell lines, and proteomical properties.     

Bacterial regulatory networks include direct contact of response regulator proteins: interaction of RegA and NtrX in Rhodobacter capsulatus

The formation of photosynthetic complexes in facultatively photosynthetic bacteria is controlled by the oxygen tension in the environment. In Rhodobacter capsulatus the two-component system RegB/RegA plays a major role in the redox control of photosynthesis genes but also controls other redox-dependent systems. The response regulator RegA is phosphorylated under low oxygen tension and activates the puf and puc operons, which encode pigment binding proteins, by binding to their promoter regions. Data from a yeast two-hybrid analysis as well as an in vitroanalysis indicate that RegA interacts with the NtrX protein, the response regulator of the NtrY/NtrX two-component system which is believed to be involved in regulation of nitrogen fixation genes. Our further analysis revealed that NtrX is indeed involved in the regulation of the puf and puc operons. Furthermore, we showed that an altered NtrX protein, which is predicted to adopt the conformation of phosphorylated NtrX protein, binds within the puf promoter region close to the RegA binding sites. We conclude that a direct interaction of two response regulators connects the regulatory systems for redox control and nitrogen control.     

A new piece of an old jigsaw: glucose kinase is activated posttranslationally in a glucose transport-dependent manner in streptomyces coelicolor A3(2)

Members of the soil-dwelling prokaryotic genus Streptomyces are indispensable for the recycling of complex polysaccharides, and produce a wide range of natural products. Nutrient limitation is likely to be a major signal for the onset of their development, resulting in spore formation by specialized aerial hyphae. Streptomycetes grow on numerous carbon sources, which they utilize in a preferential manner. The main signaling pathway underlying this phenomenon is carbon catabolite repression, which in streptomycetes is totally dependent on the glycolytic enzyme glucose kinase (Glk). How Glk exerts this fascinating dual role (metabolic and regulatory) is still largely a mystery. We show here that while Glk is made constitutively throughout the growth of Streptomyces coelicolor A3(2), its catalytic activity is modulated in a carbon source-dependent manner: while cultures growing exponentially on glucose exhibit high Glk activity, mannitol- grown cultures show negligible activity. Glk activity was directly proportional to the amount of two Glk isoforms observed by Western blot analysis. The activity profile of GlcP, the major glucose permease, correlated very well with that of Glk. Our data are consistent with a direct interaction between Glk and GlcP, suggesting that a Glk-GlcP permease complex is required for efficient glucose transport by metabolic trapping. This is supported by the strongly reduced accumulation of glucose in glucose kinase mutants. A model to explain our data is presented.     

Dermal fibroblasts derived from fetal and postnatal humans exhibit distinct responses to insulin like growth factors

Background  

It has been well established that human fetuses will heal cutaneous wounds with perfect regeneration. Insulin-like growth factors are pro-fibrotic fibroblast mitogens that have important roles in both adult wound healing and during development, although their relative contribution towards fetal wound healing is currently unknown. We have compared responses to IGF-I and -II in human dermal fibroblast strains derived from early gestational age fetal (<14 weeks) and developmentally mature postnatal skin to identify any differences that might relate to their respective wound healing responses of regeneration or fibrosis.     

Biotransformation of β-hydroxyphenyl selenides, diphenyldiselenide and benzeneseleninic acid by whole cells of Aspergillus terreus

Aspergillus terreus CCT 3320 and A. terreus URM 3571 catalysed the biotransformations of organic β-hydroxyphenyl selenides through oxidation and methylation reactions. The kinetic resolution of (RS)-1-(phenylseleno)-2-propanol (1) via enantioselective oxidation produced (+)-(S)-1 in high enantiomeric excess (>99%) and in a yield of 50% as determined by product isolation. Oxidation of the R-enantiomer of 1, followed by elimination of the propyl moiety and subsequent methylation of the presumed intermediate, led to the formation of methylphenyl-selenide, which was isolated in a yield of 40%. Whole cells of A. terreus also biocatalysed transformations of diphenyldiselenide, benzeneseleninic acid, (RS)-1-(phenylseleno)-2-pentanol and (RS)-1-(phenylseleno)-3-methyl-2-butanol, but not of (RS)-1-(phenylseleno)-2-phenyl-methanol. This is the first report of the biomethylation of organoselenium compounds by whole cells of A. terreus.