Project description:Naturally-occurring variants of human cytochrome c (Cytc) that induce thrombocytopenia IV occur within Ω-loop C (residues 40-57). These variants enhance the peroxidase activity of human Cytc apparently by facilitating access to the heme by destabilizing Ω-loops C and D (residues 70-85). Given the importance of peroxidase activity in the early stages of apoptosis, we identified three sites with the EVmutation algorithm in or near Ω-loop C that coevolve and differ between yeast iso-1-Cytc and human Cytc. We prepared iso-1-Cytc variants with all possible combinations of the S40T, V57I and N63T substitutions to determine if these residues decrease the peroxidase activity of iso-1-Cytc to that of human Cytc producing an effective off state for a peroxidase signaling switch. At pH 6 and above, all variants significantly decreased peroxidase activity. However, the correlation of peroxidase activity with local and global stability, expected if cooperative unfolding of Ω-loops C and D is required for peroxidase activity, was generally poor. The m-values derived from the guanidine hydrochloride dependence of the kinetics of imidazole binding to horse Cytc, which is well-characterized by native-state hydrogen exchange methods, and K72A/K73A/K79A iso-1-Cytc show that local structural fluctuations and not subglobal cooperative unfolding of Ω-loops C and D are sufficient to permit binding of a small molecule like peroxide to the heme. A 2.46 Å structure of N63T iso-1-Cytc identifies a change to a hydrogen bond network linking Ω-loops C and D that could modulate the local fluctuations needed for the intrinsic peroxidase activity of Cytc.

Project description:An A81H variant of yeast iso-1-cytochrome c is prepared to test the hypothesis that the steric size of the amino acid at sequence position 81 of cytochrome c, which has evolved from Ala in yeast to Ile in mammals, slows the dynamics of the opening of the heme crevice. The A81H mutation is used both to increase steric size and to provide a probe of the dynamics of the heme crevice through measurement of the thermodynamics and kinetics of the His81-mediated alkaline conformational transition of A81H iso-1-cytochrome c. Thermodynamic measurements show that the native conformer is more stable than the His81-heme alkaline conformer for A81H iso-1-cytochrome c. ΔGu°(H2O) is approximately 1.9 kcal/mol for formation of the His81-heme alkaline conformer. By contrast, for K79H iso-1-cytochrome c, the native conformer is less stable than the His79-heme alkaline conformer. ΔGu°(H2O) is approximately -0.34 kcal/mol for formation of the His79-heme alkaline conformer. pH jump and gated electron transfer kinetics demonstrate that this stabilization of the native conformer in A81H iso-1-cytochrome c arises primarily from a decrease in the rate constant for formation of the His81-heme alkaline conformer, kf,His81, relative to kf,His79 for formation of the His79-heme alkaline conformer, which forms by a mechanism similar to that observed for the His81-heme alkaline conformer. The result is discussed in terms of the effect of global protein stability on protein dynamics and in terms of optimization of the sequence of cytochrome c for its role as a peroxidase in the early stages of apoptosis in higher eukaryotes.

Project description:The competition between intramolecular histidine-heme loop formation and ligand-mediated oligomer formation in the denatured state is investigated for two yeast iso-1-cytochrome c variants, AcH26I52 and AcA25H26I52. Besides the native His 18 heme ligand, both variants contain a single His at position 26. The AcA25H26I52 variant has Pro 25 mutated to Ala. The concentration dependence of the apparent pK(a) for His 26-heme binding in 3 M guanidine hydrochloride indicates that the P25A mutation disfavors oligomerization mediated by intermolecular heme ligation by 10-fold. Single- and double-pH-jump stopped-flow experiments with the AcH26I52 variant show that fast phases for His-heme bond formation and breakage are due to intramolecular loop formation and slow phases for His-heme bond formation and breakage are due to intermolecular aggregation. The presence of two closely spaced slow phases in the kinetics of loop formation for both variants suggests that intermolecular His 26-heme ligation results in both dimers and higher-order aggregates. The P25A mutation slows formation and speeds breakdown of an initial dimer, demonstrating a strong effect of local sequence on aggregation. Analysis of the kinetic data yields equilibrium constants for intramolecular loop formation and intermolecular dimerization at pH 7.1 and indicates that the rate constant for intermolecular aggregation is very fast at this pH (10(7)-10(8) M(-1) s(-1)). In light of the very fast rates of aggregation in the denatured state, comparison of models involving reversible or irreversible oligomerization steps suggests that equilibrium control of the partitioning between folding and aggregation is advantageous for productive protein folding in vivo.

Project description:Protein folding is dependent on the formation and persistence of simple loops during the earliest events of the folding process. Ease of loop formation and persistence is believed to be dependent on the steric properties of the residues involved in loop formation. We have investigated this conformational factor in the denatured state of iso-1-cytchrome c using a five alanine insert in front of a unique histidine in the N-terminal region of the protein. The alanine residues have then been progressively substituted with sterically less-constrained glycine residues. Guanidine-HCl unfolding shows that all variants have a free energy of unfolding of approximately 2 kcal/mol. The low stability of these variants is well accounted for by stabilization of the denatured state by histidine-heme loop formation. The stability of the 22 residue histidine-heme loop has been measured in 3 M guanidine hydrochloride for all variants. Surprisingly, relative to alanine, glycine has only a very modest effect on equilibrium loop stability. Thus, the greater flexibility that glycine confers on the main-chain provides no advantage in terms of the persistence of simple loops early in folding. The underlying basis for the similar behavior of loops with polyalanine versus polyglycine inserts is discussed in terms of the current knowledge of the structure and loop formation kinetics of glycine versus alanine-rich peptides.

Project description:Thrombocytopenia 4 is an inherited autosomal dominant thrombocytopenia, which occurs due to mutations in the human gene for cytochrome c that results in enhanced mitochondrial apoptotic activity. The Gly41Ser mutation was the first to be reported. Here we report stopped-flow kinetic studies of azide binding to human ferricytochrome c and its Gly41Ser variant, together with backbone amide H/D exchange and (15)N-relaxation dynamics using NMR spectroscopy, to show that alternative conformations are kinetically and thermodynamically more readily accessible for the Gly41Ser variant than for the wild-type protein. Our work reveals a direct conformational link between the 40-57 Ω-loop in which residue 41 resides and the dynamical properties of the axial ligand to the heme iron, Met80, such that the replacement of glycine by serine promotes the dissociation of the Met80 ligand, thereby increasing the population of a peroxidase active state, which is a key non-native conformational state in apoptosis.

Project description:A new class of deformation is presented for a planar loop structure made up of slender elastic bodies and joints. In demonstrating the circumferential shortening of the multi-jointed elastic loop, diverse three-dimensional (3D) deformations emerge through piecewise deflections and discrete rotations. These 3D morphologies correspond to conformations of molecular ring systems. Through image processing, the 3D reconstructions of the deformed structures are characterized by number, geometry, and initial imperfections of the body segments. We elucidate from measurements that the conformational deformation without self-stress results from a cyclical assembly of compressive bending of elastic bodies with high shear rigidity. The mechanical insights gained may apply in controlling the polymorphism exhibited by the cyclical structures across scales.

Project description:AimTo compare n-butyl-2-cyanoacrylate, iso-amyl-2-cyanoacrylate and a mixture of 72% chromated glycerin with hypertonic glucose solution in management of gastric varices.MethodsNinety patients with gastric varices presented to Endoscopy Unit of Ain Shams University Hospital were included. They were randomly allocated into three groups; each group included 30 patients treated with intravariceal sclerosant injections in biweekly sessions till complete obturation of gastric varices; Group I (n-butyl-2-cyanoacrylate; Histoacryl(®)), Group II (iso-amyl-2-cyanoacrylate; Amcrylate(®)) and Group III (mixture of 72% chromated glycerin; Scleremo(®) with glucose solution 25%). All the procedures were performed electively without active bleeding. Recruited patients were followed up for 3 mo.Results26% of Scleremo group had bleeding during puncture vs 3.3% in each of the other two groups with significant difference, (P < 0.05). None of Scleremo group had needle obstruction vs 13.3% in each of the other two groups with no significant difference, (P > 0.05). Rebleeding occurred in 13.3% of Histoacryl and Amcrylate groups vs 0% in Scleremo group with no significant difference. The in hospital mortality was 6.6% in both Histoacryl and Amcrylate groups, while it was 0% in Scleremo group with no significant difference. In the first and second sessions, the amount of Scleremo needed for obturation was significantly high, while the amount of Histoacryl was significantly low. Scleremo was the less costly of the two treatments.ConclusionAll used sclerosant substances showed efficacy and success in management of gastric varices with no significant differences except in total amount, cost and bleeding during puncture.

Project description:The reovirus outer capsid protein μ1 forms a lattice surrounding the viral core. In the native state, μ1 determines the environmental stability of the viral capsid. Additionally, during cell entry, μ1 undergoes structural rearrangements that facilitate delivery of the viral cores across the membrane. To determine how the capsid-stabilizing functions of μ1 impinge on the capacity of μ1 to undergo conformational changes required for cell entry, we characterized viruses with mutations engineered at charged residues within the μ1 loop formed by residues 72 to 96 (72-96 loop). This loop is proposed to stabilize the capsid by mediating interactions between neighboring μ1 trimers and between trimers and the core. We found that mutations at Glu89 (E89) within this loop produced viruses with compromised efficiency for completing their replication cycle. ISVPs of E89 mutants converted to ISVP*s more readily than those of wild-type viruses. The E89 mutants yielded revertants with second-site substitutions within regions that mediate interaction between μ1 trimers at a site distinct from the 72-96 loop. These viruses also contained changes in regions that control interactions within μ1 trimers. Viruses containing these second-site changes displayed restored plaque phenotypes and were capable of undergoing ISVP-to-ISVP* conversion in a regulated manner. These findings highlight regions of μ1 that stabilize the reovirus capsid and demonstrate that an enhanced propensity to form ISVP*s in an unregulated manner compromises viral fitness.

Project description:Hierarchical twinning, at multiple length scales, was noted in a metastable body-centered cubic (bcc) ?-titanium alloy on tensile deformation. Site-specific characterization within the deformation bands, carried out using EBSD and TEM, revealed {332} <113> type primary bcc twins, containing different variants of secondary and tertiary twins, as well as the formation of stress-induced martensite (?"). Within the primary {332} <113> type twin, "destruction" of the prior quenched-in athermal ? phase was observed, while a stress-induced ? phase reforms within the tertiary twins, revealing the intricate nature of coupling between deformation twinning and displacive ? transformation.

Project description:Evolutionary conservation of substructure architecture between yeast iso-1-cytochrome c and the well-characterized horse cytochrome c is studied with limited proteolysis, the alkaline conformational transition and global unfolding with guanidine-HCl. Mass spectral analysis of limited proteolysis cleavage products for iso-1-cytochrome c show that its least stable substructure is the same as horse cytochrome c. The limited proteolysis data yield a free energy of 3.8 +/- 0.4 kcal mol(-1) to unfold the least stable substructure compared with 5.05 +/- 0.30 kcal mol(-1) for global unfolding of iso-1-cytochrome c. Thus, substructure stabilities of iso-1-cytochrome c span only approximately 1.2 kcal mol(-1) compared with approximately 8 kcal mol(-1) for horse cytochrome c. Consistent with the less cooperative folding thus expected for the horse protein, the guanidine-HCl m-values are approximately 3 kcal mol(-1)M(-1) versus approximately 4.5 kcal mol(-1)M(-1) for horse versus yeast cytochrome c. The tight free energy spacing of the yeast cytochrome c substructures suggests that its folding has more branch points than for horse cytochrome c. Studies on a variant of iso-1-cytochrome c with an H26N mutation indicate that the least and most stable substructures unfold sequentially and the two least stable substructures unfold independently as for horse cytochrome c. Thus, important aspects of the substructure architecture of horse cytochrome c, albeit compressed energetically, are preserved evolutionally in yeast iso-1-cytochrome c.