Fibrillin-1 mgΔlpn Marfan syndrome mutation associates with preserved proteostasis and bypass of a protein disulfide isomerase-dependent quality checkpoint

Fibrillin-1 mutations promote Marfan syndrome (MFS) via complex yet unclear pathways. The roles of endoplasmic reticulum (ER) and the major ER redox chaperone protein disulfide isomerase-A1 in the processing of normal and mutated fibrillin-1 and ensuing protein secretion and/or intracellular retention are unclear. Our results in mouse embryonic fibroblasts bearing the exon-skipping mgΔ^lox-P-neo (mgΔ^lpn) mutation, which associates in vivo with MFS and in vitro with disrupted microfibrils, indicate a preserved ER-dependent proteostasis or redox homeostasis. Rather, mutated fibrillin-1 is secreted normally through Golgi-dependent pathways and is not intracellularly retained. Similar results occurred for the C1039G point mutation. In parallel, we provide evidence that PDIA1 physically interacts with fibrillin-1 in the ER. Moreover, siRNA against PDIA1 augmented fibrillin-1 secretion rates in wild-type cells. However, fibrillin-1 with the mgΔ^lpn mutation bypassed PDI checkpoint delay, while the C1039G mutation did not. This heretofore undisclosed PDIA1-mediated mechanism may be important to control the extracellular availability of function-competent fibrillin-1, an important determinant of disease phenotype. Moreover, our results may reveal a novel, holdase-like, PDI function associated with ER protein quality control.     

Molecular dynamics simulation of crack growth in pure titanium under uniaxial tension

The analysis of crack growth in titanium was performed using molecular dynamics simulation with Embedded Atom Method potentials. The effect of temperature and strain rate on the mechanism of crack growth and the change of microstructure were discussed. After setting an initial crack, the specimen was subjected to uniaxial tension strain up to the total strain level of 0.2 with a constant strain rate. During the period, the shape and the microstructure of crack tip as well as the stress–strain curves were monitored. In the simulation, the gather of voids and stress concentration leading to the crack growth occurred, which are in agreement with experimental results observed by transmission electron microscopy. The transformation from HCP to BCC also occurred at crack tip. The remarkable effect of temperature and strain rate on the growth direction and rate of stacking fault of crack tip was observed. Moreover, initial crack greatly lowered the tension yield point of pure titanium. In the stage of deformation, simulation results showed that loading strain rate and temperature strongly influenced peak stress point, which was increased by the low temperature and high strain, whereas the initial slope of the stress strain curve was independent of loading strain rate.     

Effect of disulfide bond on the conformation and anticoagulant activity of an Arg-Gly-Asp motif displayed on a mutant insulin protein framework

Protein engineering techniques were employed to graft the known anticoagulant Arg-Gly-Asp (RGD) motif-containing sequences onto the surface of a mutant, inactive insulin framework. To probe the effect of a disulfide bond on the resultant anticoagulant activity, a native RGD-containing sequence from disintegrin dendroaspin, CFTPRGDMPGPYC, as well as a modified sequence, SFTPRGDMPGPYS, were each examined. The peptide was placed between the C-terminal of the B chain and the N-terminal of the A chainand connected with B27 and A1 residues of the inactive insulin that lacks the characteristic intramolecular A6-11 disulfide bondwithin the A chain. The two RGD-containing insulin genes were over-expressed in E. coli, and purified and designatedas RGD-Cys-Ins and RGD-Ser-Ins, respectively. Their amino acid compositions and mass data were in good agreement with those ofexpected. The RGD-Cys-Ins showed inhibition of platelet aggregation with an IC₅₀ of 3 M, while the latter was3.5-fold less active. The in vivo assay also indicatedthat the RGD-Cys-Ins had a higher activity in prolonging the bleeding time in mice than RGD-Ser-Ins. Both RGD-Cys-Ins and RGD-Ser-Ins retained about 25% of the proinsulin immunoactivity and had almost no insulin receptor binding activity. The results indicate the necessity for the RGD motif to be conformationally constrained for it to elicit a greater anticoagulant activity.