Effect of silver nanoparticles and hydroxyproline,administered in ovo,on the development of blood vessels and cartilage collagen structure in chicken embryos

It has been considered that concentrations of certain amino acids in the egg are not sufficient to fully support embryonic development of modern broilers. In this study we evaluated embryo growth and development with particular emphasis on one of the major components of connective tissue, collagen. Experiments were performed on Ross 308 chicken embryos from 160 fertilised eggs. Experimental solutions of silver nanoparticles (Ag), hydroxyproline solution (Hyp) and a complex of silver nanoparticles with hydroxyproline (AgHyp) were injected into albumen, and embryos were incubated until day 20. An assessment of the mass of embryo and selected organs was carried out followed by measurements of the expression of the key signalling factors’ fibroblast growth factor-2 (FGF-2) and vascular endothelial growth factor-A (VEGF-A). Finally, an evaluation of collagen microstructure using scanning electron microscopy was performed. Our results clearly indicate that Hyp, Ag and AgHyp administered in ovo to chicken embryos did not harm embryos. Comparing to the control group, Hyp, Ag and the AgHyp complex significantly upregulated expression of the FGF-2 at the mRNA and protein levels. Moreover, Hyp, Ag and, in particular, the complex of AgHyp significantly increased blood vessel size, cartilage collagen fibre lattice size and bundle thickness. The general conclusion from this study is that AgHyp treatment may help to build a stronger and longer lasting form of collagen fibres.     

Conformational fluctuations versus constraints in amino acid side chains: the evolution of information content from free amino acids to proteins

Like all other complex biological systems, proteins exhibit properties not found in free amino acids (i.e., emergent properties). Here, we explore top-down constraints experienced by the residue side chains in proteins compared to amino acids in increasingly complex molecular environments: free amino acids, end-capped amino acids, and the central residue in an alpha-helical nonapeptide. The crystalline structure of the contractile protein profilin Ib and the enzyme trypsin were chosen as objects of study, and submitted to 10 ns molecular dynamics (MD) simulations. The results revealed increased conformational constraints on the side chains when going from the simpler to the more complex compounds. A Shannon entropy (SE) analysis of the conformational behavior of the side chains showed in most cases a progressive and marked decrease in the SE of the chi1 and chi2 dihedral angles. This is equivalent to stating that conformational constraints on the side chain of residues increase their information content and, hence, recognition specificity compared to free amino acids. In other words, the vastly increased information content of a protein relative to its free monomers is embedded not only in the tertiary structure of the backbone, but also in the conformational behavior of the side chains. The postulated implication is that both backbone and side chains, by virtue of being conformationally constrained, contribute to the protein's recognition specificity toward other macromolecules and ligands.     

Immunoglobulin kappa light chain and its amyloidogenic mutants: a molecular dynamics study

AL amyloidosis and LCDD are pathological conditions caused by extracellural deposition of monoclonal Ig light chain variable domains. In the former case, deposits have a form of amyloid fibrils, in the latter, amorphous aggregates. 1REI kappa light chain variable domain and its two point mutants, R61N and D82I, were chosen for the analysis in this work. Wild 1REI does not create deposits in vitro, while R61N aggregates as amyloid fibrils and D82I creates amorphous aggregates. Both mutated residues create a conserved salt bridge; thus, substitution of any of them should decrease V(L) domain stability. For these three proteins, 5 ns MD simulations were conducted in temperatures of 300 K and 400 K, with protonated and unprotonated acidic residues, mimicking acidic and neutral experimental pH conditions (3 sets: N300, N400, and A400). The analysis of trajectories focused on characterization of changes in conformational behavior and stability of Ig kappa light chain variable domain caused by single aminoacid substitutions that were experimentally proved to enhance aggregation propensity, both in the form of amyloid and amorphous aggregates. Residue D82 turns out to be involved not only in R61-D82 but also in K45-D82 interaction, which was not observed in the X-ray structure, but frequently populated simulations of 1REI. The substitution D82I excludes both interactions, resulting in substantial destabilization (i.e., easier aggregation). Examination of behavior of edge regions of V(L) beta-sandwich reveals significant alterations in D82I mutant compared to wild 1REI, while relatively small changes occur in R61N. This suggests that mild and slow destabilization is the reason of the conversion of V(L) to partially folded amyloidogenic intermediate structure.     

Structure of functional a salina – E Coli hybrid ribosome by electron microscopy

Small 40S Artemia salina and large 50S Escherichia coli ribosomal subunits can be assembled into 73S hybrid monosomes active in model assays for protein synthesis. The reciprocal combination–small 30S E coli and large 60S A salina–fails to form hybrids. The 73S hybrid particles strongly resemble homologous 70S E coli and 80S A salina monosomes. The morphologic differences between the corresponding eukaryotic and prokaryotic ribosomal particles, established by electron microscopy, do not significantly affect the assembly and mutual orientation of 40S A salina and 50S E coli subunits in the heterologous monosome. The fact that the structure of the interface, the supposed site of protein synthesis, is preserved in the active hybrid implies that retention or loss of biologic activity of hybrid ribosomes is determined by the extent of conformational changes in the interface.     

Molecular analysis of the gene for vitamin K dependent protein S and its pseudogene. Cloning and partial gene organization

Protein S is a vitamin K dependent plasma protein and a cofactor to activated protein C, a serine protease that regulates blood coagulation. The haploid genome contains two protein S genes (alpha and beta) with the protein S alpha-gene corresponding to the cloned cDNA. We have now isolated and mapped overlapping genomic clones that cover an area of 50 kilobases of the protein S alpha-gene which code for the 3' part of the gene, i.e., the thrombin-sensitive region, the four domains that are homologous to the epidermal growth factor (EGF) precursor, the COOH-terminal part of protein S that is homologous to a plasma sex hormone binding globulin (SHBG), and, finally, the 3' untranslated region. The thrombin-sensitive region and the EGF-like domains are each coded on a separate exon. The sizes of the exons coding for the COOH-terminal half of protein S and the location of the introns are nearly identical with those in the homologous SHBG gene. Furthermore, the phase class of the splice junctions is the same in these two genes. We have also isolated and mapped genomic clones that cover 25 kilobases of the protein S beta-gene, which was found to contain stop codons and a 2 bp deletion which introduces a frame shift, suggesting that it is a pseudogene. The structure of the two protein S genes and a comparison with the vitamin K dependent clotting factors support a model for their origin by exon shuffling and recruitment of the 3' part of the gene from an ancestor shared with the sex hormone binding globulin.     

Expression of completely gamma-carboxylated and beta-hydroxylated recombinant human vitamin-K-dependent protein S with full biological activity

Human anticoagulant vitamin-K-dependent protein S was expressed in mouse C127 cells using a bovine papilloma virus vector system. A full-length cDNA construct was introduced into the vector in the 5' untranslated region of the mouse metallothionein-I gene. Transfected cells expressed approximately 10 micrograms/ml of the recombinant protein which was purified by ion-exchange chromatography followed by affinity chromatography using Ca2(+)-dependent monoclonal antibodies against the region of protein S containing 4-carboxyglutamic acid. Recombinant protein S was structurally and functionally similar to protein S purified from plasma. On SDS/polyacrylamide-gel electrophoresis recombinant protein S had a slightly higher molecular mass than plasma protein S. After treatment with endoglycosidase F, the proteins comigrated suggesting the observed molecular mass difference to be due to alterations in the N-linked carbohydrate side chains. Recombinant and plasma protein S demonstrated identical amino-terminal sequences, similar amino acid composition and number of 4-carboxyglutamyl and 3-hydroxyaspartyl/asparaginyl residues. Recombinant protein S had the same affinity for Ca2+ as protein S from plasma and the two proteins had the same activated protein C cofactor activity in a functional assay. In addition, both forms of protein S formed complexes with C4b-binding protein with the same apparent Kd. Protein S is the most extensively post-translationally modified vitamin-K-dependent protein, and all the modifications were carried out in the recombinant DNA system yielding a recombinant protein S with full biological activity.