JNK promotes Bax translocation to mitochondria through phosphorylation of 14-3-3 proteins

Targeted gene disruption studies have established that the c-Jun NH2-terminal kinase (JNK) is required for the stress-induced release of mitochondrial cytochrome c and apoptosis, and that the Bax subfamily of Bcl-2-related proteins is essential for JNK-dependent apoptosis. However, the mechanism by which JNK regulates Bax has remained unsolved. Here we demonstrate that activated JNK promotes Bax translocation to mitochondria through phosphorylation of 14-3-3, a cytoplasmic anchor of Bax. Phosphorylation of 14-3-3 led to dissociation of Bax from this protein. Expression of phosphorylation-defective mutants of 14-3-3 blocked JNK-induced Bax translocation to mitochondria, cytochrome c release and apoptosis. Collectively, these results have revealed a key mechanism of Bax regulation in stress-induced apoptosis.     

Evidence that a local refolding event triggers maturation of HK97 bacteriophage capsid

Bacteriophage capsids are a striking example of a robust yet dynamic genome delivery vehicle. Like most phages, HK97 undergoes a conformational maturation that converts a metastable Prohead into the mature Head state. In the case of HK97, maturation involves a significant expansion of the capsid and concomitant cross-linking of capsid subunits. The final state, termed Head-II, is a 600 angstroms diameter icosahedral structure with catenated subunit rings. Cryo-EM, small angle X-ray scattering (SAXS), and biochemical assays were used previously to characterize the initial (Prohead-II) and final states (Head-II) as well as four maturation intermediates. Here we extend the characterization of the acid-induced expansion of HK97 in vitro by monitoring changes in intrinsic fluorescence, circular dichroism (CD), and SAXS. We find that the greatest changes in all observables occur at an early stage of maturation. Upon acidification, fluorescence emissions from HK97 exhibit a blueshift and decrease in intensity. These spectral changes reveal two kinetic phases of the expansion reaction. The early phase exhibits sensitivity to pH, increasing in rate nearly 200-fold when acidification pH is lowered from 4.5 to 3.9. The second, slower phase reported by fluorescence is relatively insensitive to pH. Time-resolved SAXS experiments report an increase in overall particle dimension that parallels the fluorescence changes for the early phase. Native agarose gel assays corroborated this finding. By contrast, probes of CD at far-UV indicate that secondary structural changes precede the early expansion phase reported by SAXS and fluorescence. Based on the crystallographic structure of Head-II and the pseudo-atomic model of Prohead-II, we interpret these changes as reflecting the conversion of subunit N-terminal arms (N-arm) from unstructured polypeptide to the mixture of beta-strand and beta-turn observed in the Head-II crystal structure. Refolding of the N-arm may thus represent the conformational trigger that initiates the irreversible expansion of the phage capsid.     

Crucial role of the specificity-determining loop of the integrin beta4 subunit in the binding of cells to laminin-5 and outside-in signal transduction

Within each hemidesmosome, alpha6beta4 integrin plays a crucial role in hemidesmosome assembly by binding to laminin-5 in the basement membrane zone of epithelial tissue. Recent analyses have implicated "specificity-determining loops" (SDLs) in the I-like domain of beta integrin in regulating ligand binding. Here, we investigated the function of an SDL-like motif within the extracellular I-like domain of beta4 integrin. We generated point mutations within the SDL of beta4 integrin tagged with green fluorescent protein (GFP-beta4K150A and GFP-beta4Q155L). We also generated a mutation within the I-like domain of the beta4 integrin, lying outside the SDL region (GFP-beta4V284E). We transfected constructs encoding the mutated beta4 integrins and a GFP-conjugated wild type beta4 integrin (GFP-beta4WT) into 804G cells, which assemble hemidesmosomes, and human endothelial cells, which express little endogenous beta4 integrin. In transfected 804G cells, GFP-beta4WT and GFP-beta4V284E colocalize with hemidesmosome proteins, whereas hemidesmosomal components in cells expressing GFP-beta4K150A and GFP-beta4Q155L are aberrantly localized. In endothelial cells, GFP-beta4WT and mutant proteins are co-expressed at the cell surface with alpha6 integrin. When transfected endothelial cells are plated onto laminin-5 matrix, GFP-beta4WT and GFP-beta4V284E localize with laminin-5, whereas GFP-beta4K150A and GFP-beta4Q155L do not. GFP-beta4WT and GFP-beta4V284E expressed in endothelial cells associate with the adaptor protein Shc when the cells are stimulated with laminin-5. However, GFP-beta4K150A and GFP-beta4Q155L fail to associate with Shc even when laminin-5 is present, thus impacting downstream signaling. These results provide evidence that the SDL segment of the beta4 integrin subunit is required for ligand binding and is involved in outside-in signaling.     

Butyric acid sensitizes Vero cells to ricin-induced apoptosis via accelerated activation of multiple signal transduction pathways

We found that the treatment with 1 mM butyric acid for 2 days renders Vero cells highly sensitive to ricin-induced apoptosis reflected by cytolysis concomitant with apoptotic cellular and nuclear morphological changes, DNA fragmentation, and increase in caspase-3 like activity, whereas butyric acid alone had no cytotoxic effect on Vero cells. During the treatment with butyric acid, gradual increase in alkaline phosphatase activity, an indicator for butyric acid-induced differentiation, was observed in Vero cells. Although the potency of ricin-mediated protein synthesis was increased in butyric acid-treated Vero cells as compared to untreated cells, the binding and internalization of ricin to the cells were not much affected. Furthermore, DNA fragmentation caused by other protein synthesis inhibitors such as diphtheria toxin and anisomysin were also highly potentiated in butyric acid-treated Vero cells, whereas the potencies of these toxins to inhibit the protein synthesis were not affected by butyric acid treatment. These results suggest that the apoptosis signaling pathway, which may be triggered by cytotoxic stress response caused by toxins, is sensitized in butyric acid-treated cells, while the pathways leading to the protein synthesis inhibition by these toxins are relatively unchanged. No significant differences in the expression levels of p21, p53, and Bcl-2 proteins were observed between butyric acid-treated and untreated Vero cells. The treatment with ricin resulted in the activation of p38 MAP kinase, and this activation occurred on an accelerated time schedule in butyric acid-treated Vero cells than in untreated cells. The specific inhibitor of p38 MAP kinase SB203580 showed a partial inhibitory effect on ricin-induced apoptosis in control Vero cells, but it was less effective in butyric acid-treated Vero cells. Taken together, our results suggest that butyric acid-treatment may result in sensitization of multiple intracellular signal transduction pathways including apoptotic signaling pathways and p38 MAP kinase pathway.     

Nutrient regulation of epothilone biosynthesis in heterologous and native production strains

Fermentation media with different initial concentrations of ammonium and phosphate salts were used to study the inhibitory effects of those ions on growth and production of epothilone in Sorangium cellulosum and Myxococcus xanthus. The native epothilone producer, S. cellulosum was more sensitive to ammonium and phosphate than the heterologous producer, M. xanthus. An ammonium concentration of 12 mM reduced epothilone titers by 90% in S. cellulosum but by only 40% in M. xanthus. When 5 mM phosphate was added to the medium, production in both strains was 60% lower. Higher phosphate concentrations had little additional effect on M. xanthus titers, but epothilone production with 17 mM extra-cellular phosphate in S. cellulosum was 95% lower than in the control condition. The effect of iron supplementation to the fermentation medium was also investigated. Both strains showed best production with 20 microM iron added to the medium.     

A functional variant of Fcgamma receptor IIIA is associated with rheumatoid arthritis in individuals who are positive for anti-glucose-6-phosphate isomerase antibodies

Anti-glucose-6-phosphate isomerase (GPI) antibodies are known to be arthritogenic autoantibodies in K/BxN mice, although some groups have reported that few healthy humans retain these antibodies. The expression of Fcgamma receptors (FcgammaRs) is genetically regulated and has strong implications for the development of experimental arthritis. The interaction between immune complexes and FcgammaRs might therefore be involved in the pathogenesis of some arthritic conditions. To explore the relationship between functional polymorphisms in FcgammaRs (FCGR3A-158V/F and FCGR2A-131H/R) and arthritis in individuals positive for anti-GPI antibodies, we evaluated these individuals with respect to FCGR genotype. Genotyping for FCGR3A-158V/F and FCGR2A-131H/R was performed by PCR amplification of the polymorphic site, followed by site specific restriction digestion using the genome of 187 Japanese patients with rheumatoid arthritis (including 23 who were anti-GPI antibody positive) and 158 Japanese healthy individuals (including nine who were anti-GPI antibody positive). We report here on the association of FCGR3A-158V/F functional polymorphism with anti-GPI antibody positive status. Eight out of nine healthy individuals who were positive for anti-GPI antibodies possessed the homozygous, low affinity genotype FCGR3A-158F (odds ratio = 0.09, 95% confidence interval 0.01-0.89; P = 0.0199), and probably were 'protected' from arthritogenic antibodies. Moreover, among those who were homozygous for the high affinity genotype FCGR3A-158V/V, there were clear differences in anti-human and anti-rabbit GPI titres between patients with rheumatoid arthritis and healthy subjects (P = 0.0027 and P = 0.0015, respectively). Our findings provide a molecular model of the genetic regulation of autoantibody-induced arthritis by allele-specific affinity of the FcgammaRs.     

Design, production, and characterization of recombinant neocarzinostatin apoprotein in Escherichia coli

Neocarzinostatin (NCS) is the first discovered anti-tumor antibiotic having an enediyne-containing chromophore and an apoprotein with a 1:1 complex. An artificial gene library for NCS apoprotein (apo-NCS) production in Escherichia coli was designed and constructed on a phage-display vector, pJuFo. The recombinant phages expressing pre-apo-NCS protein were enriched with a mouse anti-apo-NCS monoclonal antibody, 1C7D4. The apo-NCS gene (encsA) for E. coli was successfully cloned, and then re-cloned into the pRSET A vector. After the his-tagged apo-NCS protein had been purified and cleaved with enterokinase, the binding properties of the recombinant protein as to ethidium bromide (EtBr) were studied by monitoring of total fluorescence intensity and fluorescence polarization with a BEACON 2000 system and GraphPad Prism software. A dissociation constant of 4.4 +/- 0.3 microM was obtained for recombinant apo-NCS in the fluorescence polarization study. This suggests that fluorescence polarization monitoring with EtBr as a chromophore mimic may be a simplified method for the characterization of recombinant apo-NCS binding to the NCS chromophore. When Phe78 on apo-NCS was substituted with Trp78 by site-directed mutagenesis using a two stage megaprimer polymerase chain reaction, the association of the apo-NCS mutant and EtBr observed on fluorescence polarization analysis was of the same degree as in the case of the wild type, although the calculated maximum change (DeltaIT(max)) in total fluorescence intensity decreased from 113.9 to 31.3. It was suggested that an environmental change of the bound EtBr molecule on F78W might have dramatically occurred as compared with in the case of wild type apo-NCS. This combination of monitoring of fluorescence polarization and total fluorescence intensity will be applicable for determination and prediction of the ligand state bound or associated with the target protein. The histone-specific proteolytic activity was also re-investigated using this recombinant apo-NCS preparation, and calf thymus histone H1, H2A, H2B, H3, and H4. The recombinant apo-NCS does not act as a histone protease because a noticeable difference was not observed between the incubation mixtures with and without apo-NCS under our experimental conditions.     

Heteromultimerization modulates P2X receptor functions through participating extracellular and C-terminal subdomains

P2X purinergic receptors (P2XRs) differ among themselves with respect to their ligand preferences and channel kinetics during activation, desensitization, and recovery. However, the contributions of distinct receptor subdomains to the subtype-specific behavior have been incompletely characterized. Here we show that homomeric receptors having the extracellular domain of the P2X(3) subunit in the P2X(2a)-based backbone (P2X(2a)/X(3)ex) mimicked two intrinsic functions of P2X(3)R, sensitivity to alphabeta-methylene ATP and ecto-ATPase-dependent recovery from endogenous desensitization; these two functions were localized to the N- and C-terminal halves of the P2X(3) extracellular loop, respectively. The chimeric P2X(2a)R/X(3)ex receptors also desensitized with accelerated rates compared with native P2X(2a)R, and the introduction of P2X(2) C-terminal splicing into the chimeric subunit (P2X(2b)/X(3)ex) further increased the rate of desensitization. Physical and functional heteromerization of native P2X(2a) and P2X(2b) subunits was also demonstrated. In heteromeric receptors, the ectodomain of P2X(3) was a structural determinant for ligand selectivity and recovery from desensitization, and the C terminus of P2X(2) was an important factor for the desensitization rate. Furthermore, [gamma-(32)P]8-azido ATP, a photoreactive agonist, was effectively cross-linked to P2X(3) subunit in homomeric receptors but not in heteromeric P2X(2) + P2X(3)Rs. These results indicate that heteromeric receptors formed by distinct P2XR subunits develop new functions resulting from integrative effects of the participating extracellular and C-terminal subdomains.