Distinct involvement of the Jun-N-terminal kinase and NF-kappaB pathways in the repression of the human COL1A2 gene by TNF-alpha

We used a gene knockout approach to elucidate the specific roles played by the Jun-N-terminal kinase (JNK) and NF-κB pathways downstream of TNF-α in the context of α(2) type I collagen gene (COL1A2) expression. In JNK₁^−/−-JNK₂^−/− (JNK^−/−) fibroblasts, TNF-α inhibited basal COL1A2 expression but had no effect on TGF-β-driven gene transactivation unless jnk1 was introduced ectopically. Conversely, in NF-κB essential modulator^−/− (NEMO^−/−) fibroblasts, lack of NF-κB activation did not influence the antagonism exerted by TNF-α against TGF-β but prevented repression of basal COL1A2 gene expression. Similar regulatory mechanisms take place in dermal fibroblasts, as evidenced using transfected dominant-negative forms of MKK4 and IKK-α, critical kinases upstream of the JNK and NF-κB pathways, respectively. These results represent the first demonstration of an alternate usage of distinct signaling pathways by TNF-α to inhibit the expression of a given gene, COL1A2, depending on its activation state.     

Meningococcus Hijacks a β2-adrenoceptor/β-Arrestin pathway to cross brain microvasculature endothelium

Following pilus-mediated adhesion to human brain endothelial cells, meningococcus (N. meningitidis), the bacterium causing cerebrospinal meningitis, initiates signaling cascades, which eventually result in the opening of intercellular junctions, allowing meningeal colonization. The signaling receptor activated by the pathogen remained unknown. We report that N. meningitidis specifically stimulates a biased β2-adrenoceptor/β-arrestin signaling pathway in endothelial cells, which ultimately traps β-arrestin-interacting partners, such as the Src tyrosine kinase and junctional proteins, under bacterial colonies. Cytoskeletal reorganization mediated by β-arrestin-activated Src stabilizes bacterial adhesion to endothelial cells, whereas β-arrestin-dependent delocalization of junctional proteins results in anatomical gaps used by bacteria to penetrate into tissues. Activation of β-adrenoceptor endocytosis with specific agonists prevents signaling events downstream of N. meningitidis adhesion and inhibits bacterial crossing of the endothelial barrier. The identification of the mechanism used for hijacking host cell signaling machineries opens perspectives for treatment and prevention of meningococcal infection.     

A mutational study in the transmembrane domain of Ccc2p, the yeast Cu(I)-ATPase, shows different roles for each Cys-Pro-Cys cysteine

Ccc2p is homologous to the human Menkes and Wilson copper ATPases and is herein studied as a model for human copper transport. Most studies to date have sought to understand how mutations in the human Menkes or Wilson genes impair copper homeostasis and induce disease. Here we analyze whether eight conserved amino acids of the transmembrane domain are important for copper transport. Wild-type Ccc2p and variants were expressed in a ccc2-Delta yeast strain to check whether they were able to restore copper transport by complementation. Wild-type Ccc2p and variants were also expressed in Sf9 cells using baculovirus to study their enzymatic properties on membrane preparations. The latter system allowed us to measure a copper-activated ATPase activity of about 20 nmol/mg/min for the wild-type Ccc2p at 37 degrees C. None of the variants was as efficient as the wild type in restoring copper homeostasis. The mutation of each cysteine of the (583)CPC(585) motif into a serine resulted in nonfunctional proteins that could not restore copper homeostasis in yeast and had no ATPase activity. Phosphorylation by ATP was still possible with the C583S variant, although it was not possible with the C585S variant, suggesting that the cysteines of the CPC motif have a different role in copper transport. Cys(583) would be necessary for copper dissociation and/or enzyme dephosphorylation and Cys(585) would be necessary for ATP phosphorylation, suggesting a role in copper binding.     

Sarcoplasmic reticulum adenosinetriphosphatase phosphorylation from inorganic phosphate. Theoretical and experimental reinvestigation

Pi phosphorylation of sarcoplasmic reticulum (SR) vesicles in the absence of Ca was reinvestigated. Theoretical analysis shows that, for various substrate concentrations, the time dependence of phosphoenzyme formation does not allow determination of an unambiguous reaction scheme or estimation of the stoichiometry of the reaction. To overcome this difficulty, we measured medium Pi oxygen exchange, [32P]-phosphoenzyme formation, and intrinsic fluorescence. We found that contrarily to the usual assumption the substrate binding step in the phosphorylation direction at pH 6.0, KCl = 0, and 23 degrees C is a slow process whose bimolecular rate constant is around 5 X 10(3) M-1 s-1 for both Mg and Pi binding. We confirm [Lacapère, J. J., Gingold, M. P., Champeil, P., & Guillain, F. (1981) J. Biol. Chem. 256, 2302-2306] that, in a second step, the establishment of a covalent bond between the bound Pi and the enzyme is formed with a rate constant greater than or equal to 20 s-1 whereas the dephosphorylation rate constant is 2-3 s-1. These results imply that under optimal conditions for phosphorylation, the enzyme is almost entirely phosphorylated at concentrations of 20 mM MgCl2 and 20 mM Pi. Study of the phosphorylation reaction under various experimental conditions shows that reduction of the phosphoenzyme level upon KCl addition is mainly due to the augmentation of the hydrolysis rate constant. In addition we propose that the strong inhibition by large amounts of MgCl2 is due to the formation of an E? . Mg complex unfit for phosphorylation by Pi.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pressure-induced inactivation of sarcoplasmic reticulum adenosine triphosphatase during high-speed centrifugation

Sarcoplasmic reticulum vesicles were found to be highly sensitive to high-speed centrifugation in metal-deprived mediums at low temperature (4 degrees C). The irreversible modifications induced were easily detected from observation of the environment-sensitive spectrum of an iodoacetamide spin-label bound to the ATPase. Centrifugation also resulted in vesicle aggregation and inhibition of calcium transport, ATPase activity, and phosphoenzyme formation. These denaturation-like phenomena were prevented in the presence of sucrose, or by nucleotide binding, or, again, by cation binding to the ATPase high-affinity calcium binding sites and were only present when centrifugation was performed at low temperature. The crucial parameter during this process was found to be the hydrostatic pressure which developed in the centrifuge tube. SR vesicles exposed to 800 bars in a pressure bomb displayed the same features. It is suggested that irreversible denaturation takes place after one or both of the two following well-documented effects of pressure: a rise in the lipid order/disorder transition temperature or dissociation of the oligomeric structure of the calcium pump.     

The invasive pathogen Yersinia pestis disrupts host blood vasculature to spread and provoke hemorrhages

Yersinia pestis is a powerful pathogen with a rare invasive capacity. After a flea bite, the plague bacillus can reach the bloodstream in a matter of days giving way to invade the whole organism reaching all organs and provoking disseminated hemorrhages. However, the mechanisms used by this bacterium to cross and disrupt the endothelial vascular barrier remain poorly understood. In this study, an innovative model of in vivo infection was used to focus on the interaction between Y. pestis and its host vascular system. In the draining lymph nodes and in secondary organs, bacteria provoked the porosity and disruption of blood vessels. An in vitro model of endothelial barrier showed a role in this phenotype for the pYV/pCD1 plasmid that carries a Type Three Secretion System. This work supports that the pYV/pCD1 plasmid is responsible for the powerful tissue invasiveness capacity of the plague bacillus and the hemorrhagic features of plague.     

Tumor necrosis factor inhibits collagen and fibronectin synthesis in human dermal fibroblasts

Tumor necrosis factor (TNF) caused inhibition of collagen production by confluent cultures of human dermal fibroblasts in a dose-dependent manner. Concomitant increase of prostaglandin E2 release was observed as a result of TNF-induced cell activation. However, a blockade of the cyclooxygenase pathway of arachidonate metabolism by indomethacin did not abrogate the inhibitory effect of TNF on collagen synthesis, suggesting that this effect could be independent of prostaglandin metabolism. Gel electrophoresis of the newly synthesized macromolecules from the culture media showed that both type I and type III collagens as well as fibronectin were affected by the inhibition. Electrophoresis of cell layer-associated proteins demonstrated that the reduction in amounts of collagen and fibronectin in the medium did not result from an intracellular accumulation of these macromolecules. Production of procollagens was reduced in parallel to that of collagens, suggesting that the effect of TNF is exerted before the processing steps of procollagens. These results clearly show that TNF could play a role in modulation of matrix deposition by fibroblasts during inflammatory processes.