Age-related nitration/dysfunction of myogenic stem cell activator HGF

Mechanical perturbation triggers activation of resident myogenic stem cells to enter the cell cycle through a cascade of events including hepatocyte growth factor (HGF) release from its extracellular tethering and the subsequent presentation to signaling-receptor c-met. Here, we show that with aging, extracellular HGF undergoes tyrosine-residue (Y) nitration and loses c-met binding, thereby disturbing muscle homeostasis. Biochemical studies demonstrated that nitration/dysfunction is specific to HGF among other major growth factors and is characterized by its locations at Y198 and Y250 in c-met-binding domains. Direct-immunofluorescence microscopy of lower hind limb muscles from three age groups of rat, provided direct in vivo evidence for age-related increases in nitration of ECM-bound HGF, preferentially stained for anti-nitrated Y198 and Y250-HGF mAbs (raised in-house) in fast IIa and IIx myofibers. Overall, findings highlight inhibitory impacts of HGF nitration on myogenic stem cell dynamics, pioneering a cogent discussion for better understanding age-related muscle atrophy and impaired regeneration with fibrosis (including sarcopenia and frailty).     

Mechanically induced electrical responses in murine mammary epithelial cells in primary culture

In mouse mammary epithelial cells in primary culture, mechanical stimulation of a cell induced in other cells within the same colony a short depolarization of less than 15 mV with a duration of 1-8 s and a subsequent, prominent hyperpolarization of 6 mV lasting 10-40 s. Epidermal growth factor induces a spontaneous hyperpolarizing response in cultured mammary cells, and in cells treated with EGF mechanical stimulation produced a greater hyperpolarization, while the amplitude of the depolarizing response was not affected. The amplitude of the mechanically induced hyperpolarization was markedly reduced by quinine and tetraethylammonium, blockers of the Ca2+ -dependent K+ channel. The results suggest that the Ca2+ -dependent K+ channel was involved in the hyperpolarization.     

Redox-Dependent Domain Rearrangement of Protein Disulfide Isomerase Coupled with Exposure of Its Substrate-Binding Hydrophobic Surface

Protein disulfide isomerase (PDI) is a major protein in the endoplasmic reticulum, operating as an essential folding catalyst and molecular chaperone for disulfide-containing proteins by catalyzing the formation, rearrangement, and breakage of their disulfide bridges. This enzyme has a modular structure with four thioredoxin-like domains, a, b, b′, and a′, along with a C-terminal extension. The homologous a and a′ domains contain one cysteine pair in their active site directly involved in thiol-disulfide exchange reactions, while the b′ domain putatively provides a primary binding site for unstructured regions of the substrate polypeptides. Here, we report a redox-dependent intramolecular rearrangement of the b′ and a′ domains of PDI from Humicola insolens, a thermophilic fungus, elucidated by combined use of nuclear magnetic resonance (NMR) and small-angle X-ray scattering (SAXS) methods. Our NMR data showed that the substrates bound to a hydrophobic surface spanning these two domains, which became more exposed to the solvent upon oxidation of the active site of the a′ domain. The hydrogen-deuterium exchange and relaxation data indicated that the redox state of the a′ domain influences the dynamic properties of the b′ domain. Moreover, the SAXS profiles revealed that oxidation of the a′ active site causes segregation of the two domains. On the basis of these data, we propose a mechanistic model of PDI action; the a′ domain transfers its own disulfide bond into the unfolded protein accommodated on the hydrophobic surface of the substrate-binding region, which consequently changes into a “closed” form releasing the oxidized substrate.     

Extracellular production system of heterologous peptide driven by a secretory protease inhibitor of Streptomyces

Summary The value of a heterologous peptide extracellular production system in Streptomyces using a secretory protease inhibitor, was examined. DNA was synthesized encoding apidaecin 1b (AP1), an interesting antibacterial peptide discovered in lymph fluid of the honeybee, and was joined to the Streptomyces subtilisin inhibitor (SSI) gene via a 12-bp nucleotide sequence corresponding to the amino acid sequence specific for cleavage by blood coagulation factor Xa. The fusion protein (SSI-AP1) could be expressed and excreted efficiently into the medium by culturing S. lividans 66 harbouring a plasmid vector constructed for SSI secretion, into which the synthetic DNA was introduced. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis and amino acid analysis of the purified SSI-AP1 protided reasonable results of molecular size and composition value. Interestingly, SSI-AP1 protein showed bifunctional activity: inhibitory activity of SSI and antibacterial activity of AP1. The inhibitory activity against Escherichia coli could be also detected after the fusion protein was cleaved by factor Xa. The extracellular production system presented here should provide a useful tool for production, analysis of mode of action, and also for genetic improvement of antimicrobial peptides such as apidaecin.Offprint requests to: H. Momose     

Dysfunction of regulatory volume increase is a key component of apoptosis

Sustained cell shrinkage is a major hallmark of apoptotic cell death. In apoptotic cells, whole cell volume reduction, called apoptotic volume decrease (AVD), proceeds until fragmentation of cells. Under non-apoptotic conditions, human epithelial HeLa cells exhibited a slow regulatory volume increase (RVI) after osmotic shrinkage induced by exposure to hypertonic solution. When AVD was induced by treatment with a Fas ligand, TNF-alpha or staurosporine, however, it was found that HeLa cells failed to undergo RVI. When RVI was inhibited by combined application of Na+/H+ exchanger (NHE) and anion exchanger blockers, hypertonic stress induced prolonged shrinkage followed by caspase-3 activation in HeLa cells. Hypertonicity also induced apoptosis in NHE1-deficient PS120 fibroblasts, which lack the RVI response. When RVI was restored by transfection of these cells with NHE1, hypertonicity-induced apoptosis was completely prevented. Thus, it is concluded that RVI dysfunction is indispensable for the persistence of AVD and induction of apoptosis.