Molecular simulation studies of peptide/bilayer systems: application to structure/activity relationship of the indolicidin and mutants.

Interações de peptídeos antimicrobianos com modelos de membranas biológicas têm sido extensivamente estudadas para entender as funções destes peptídeos e para elucidar seus mecanismos de ação. Muitos esforços têm sido realizados para aumentar a potência e a especificidade desses peptídeos com o propósito de serem mais seletivos aos organismos patogênicos do que às células dos hospedeiros, como também para um melhor entendimento desta classe de processo biológico. Os mecanismos geralmente propostos para a atividade antimicrobiana envolvem a permeabilização das membranas celulares pela formação de poros ou por outras mudanças nas membranas. Um ponto fundamental no entendimento da atividade é que a composição de lipídeos das membranas dos patógenos e dos hospedeiros é diferente, observação que é entendida como a chave principal da seletividade dos peptídeos antimicrobianos. O objetivo do presente trabalho é contribuir para o entendimento da ação de peptídeos antimicrobianos pelo estudo, por simulação molecular, do peptídeo antimicrobiano indolicidina e de alguns de seus mutantes. A indolicidina é um peptídeo constituído por 13 resíduos de aminoácidos que foi isolada dos neutrófilos de bovinos cuja função é ingerir e matar bactérias. Apesar de numerosos estudos experimentais, não se sabe ainda como a indolicidina atua. Este conhecimento é importante tanto no entendimento dos processos de defesa dos organismos multicelulares como no desenvolvimento de novos antibióticos. Estas questões foram abordadas através do estudo do comportamento da indolicidina e de alguns dos seus mutantes em solução aquosa e em interação com modelos de membranas celulares.Interactions of the antimicrobial peptides with biological membrane models have been broadly studied to understand the function and the action mechanism of this class of peptides. Many efforts have been realized to increase the potency and the specificity of these peptides with the purpose of obtain more selective pathogen antimicrobials with decrease of the toxic effects and for a better explanation of the biological process concerned in the peptide action. The action mechanism approached to antimicrobial peptides concern the cellular membrane permeation by pore formation or other type of membrane disruption. A fundamental point in the knowledge of the activity is the distinct lipid composition of pathogen and host cells that is conceived as the principal key point in the selectivity of the antimicrobial peptides. The aim of the present work is to contribute for the knowledge of the action of the antimicrobial peptide indolicidin and some of its mutants by molecular dynamics simulation. The indolicidin is a short 13 amino acid residues antimicrobial peptide that was isolated from bovine neutrofils that have the function of ingest and kill pathogens. The action mechanism of the indolicidin is not yet known despite of numerous experimental studies realized with this peptide. The interaction of the indolicidin with the membrane models is important both for the knowledge of the defense machinery of the live organisms and for the development of new antimicrobials. These questions were approached by the study of the indolicidin and some of its mutants in solution and in interaction with cell membrane models

Study of the antimicrobial peptide indolicidin and mutants in eukaryotic modelled membrane by molecular dynamics simulations

In this work the interaction of the antimicrobial peptide indolicidin (IND) and its mutants CP10A and CP11 with a eukaryotic membrane model was examined by molecular dynamics simulations. The aim was to analyse the behaviour of these antimicrobial peptides when they interact with a eukaryotic modelled membrane, thereby obtaining atomic detailed observations that are not experimentally available. In the simulations, the widely studied dipalmitoylphosphatidylcholine hydrated bilayer was used as a eukaryotic membrane model. In agreement with experimental observations, the peptides IND, CP10A, and CP11 insert into the bilayer differently; the peptides that insert more deeply present the major hemolytic activities. The hydrophobic residues are responsible for the insertion, but some Trp residues of the peptides remain at the bilayer/water interface because they interact with the bilayer choline groups by cation-pi interactions that should be important for recognition of eukaryotic membrane by the three studied peptides.Fundacao de Amparo a Pesquisa do Estado de Sao Paulo (Fapesp)Conselho Nacional de Desenvolvimento Cientifico e Tecnologico (CNPq)Coordenacao de Aperfeicoamento de Pessoal de Nivel Superior (CAPES

The pH dependence of flavivirus envelope protein structure: insights from molecular dynamics simulations

<div><p>The flavivirus membrane fusion is triggered by the acid pH of the endosomes after virus endocytosis. The proposed mechanism involves changes in the protonation state of conserved histidine residues of the E protein present in the viral surface that undergoes a series of structural rearrangements that result in the fusion between the endosome and viral bilayers. We studied the pH dependence of E protein rearrangements of dengue virus type 2, used as a model, in the pH range experimented by the virus along the fusion process. We employed a low computational cost scheme to explore the behavior of the E protein by molecular dynamics (MD) simulations of complete systems that include the protein, the solvent, and ions. The procedure alternates cyclically the update of the ionization states of the protein residues with common MD steps applied to the new ionization configuration. Important pH-dependent protein structure rearrangements consistent with the changes of the protonation states of conserved histidine residues were observed. The involvement of other conserved residues in the flavivirus in the rearrangements was also identified. The results show interesting correlations with a proposed model for the fusion mechanism, as well as the experimentally identified key residues, contributing to a better understanding of the structural changes in protein E that lead to the fusion process.</p></div

Interaction of cyclic and linear labaditin peptides with anionic and zwitterionic micelles

Conformational changes of the cyclic (Lo) peptide Labaditin (VWTVWGTIAG) and its linear analogue (L1) promoted by presence of anionic sodium dodecyl sulfate (SDS) and zwitterionic L-α-Lysophosphatidylcholine (LPC) micelles were investigated. Results from λmax blue-shift of tryptophan fluorescence emission combined with Stern–Volmer constants values and molecular dynamics (MD) simulations indicated that L1 interacts with SDS micelles to a higher extent than does Lo. Further, the MD simulation demonstrated that both Lo and L1 interact similarly with LPC micelles, being preferentially located at the micelle/water interface. The peptide–micelle interaction elicits conformational changes in the peptides. Lo undergoes limited modifications and presents unordered structure in both LPC and SDS micelles. On the other hand, L1 displays a random-coil structure in aqueous medium, pH 7.0, and it acquires a β-structure upon interaction with SDS and LPC, albeit with structural differences in each medium.Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq

Insertion of a xylanase in xylose binding protein results in a xylose-stimulated xylanase

Abstract\ud \ud Background\ud Product inhibition can reduce catalytic performance of enzymes used for biofuel production. Different mechanisms can cause this inhibition and, in most cases, the use of classical enzymology approach is not sufficient to overcome this problem. Here we have used a semi-rational protein fusion strategy to create a product-stimulated enzyme.\ud \ud \ud Results\ud A semi-rational protein fusion strategy was used to create a protein fusion library where the Bacillus subtilis GH11 xylanase A (XynA) was inserted at 144 surface positions of the Escherichia coli xylose binding protein (XBP). Two XynA insertions at XBP positions 209 ([209]XBP-Xyn-XBP) and 262 ([262]XBP-Xyn-XBP) showed a 20% increased xylanolytic activity in the presence of xylose, conditions where native XynA is inhibited. Random linkers of 1-4 Gly/Ala residues were inserted at the XynA N- and C-termini in the [209]XBP and [262]XBP, and the chimeras 2091A and 2621B were isolated, showing a twofold increased xylanolytic activity in the presence of xylose and k\ud cat values of 200 and 240 s−1 in the 2091A and 2621B, respectively, as compared to 70 s−1 in the native XynA. The xylose affinity of the XBP was unchanged in the chimeras, showing that the ~3- to 3.5-fold stimulation of catalytic efficiency by xylose was the result of allosteric coupling between the XBP and XynA domains. Molecular dynamics simulations of the chimeras suggested conformation alterations in the XynA on xylose binding to the XBP resulted in exposure of the catalytic cavity and increased mobility of catalytic site residues as compared to the native XynA.\ud \ud \ud Conclusions\ud These results are the first report of engineered glycosyl hydrolase showing allosteric product stimulation and suggest that the strategy may be more widely employed to overcome enzyme product inhibition and to improve catalytic performance.\ud \ud \ud Graphical abstract\ud \ud Protein fusion of a GH11 xylanase (in red) and a xylose binding protein (XBP, in blue) results in a xylanase-XBP chimera that presents allosteric activation of the xylanase activity by xylose (shown as a space-filled molecule bound to the xylanase-XBP chimera)Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq Grant: 473327/2013-9)FAPESP (project no. 2010/18850-2). LFR (2010/07133-8) and LFCR (2010/10184-3

Contribution of genetic ancestry and polygenic risk score in meeting vitamin B12 needs in healthy Brazilian children and adolescents

Abstract Polymorphisms in genes related to the metabolism of vitamin B12 haven’t been examined in a Brazilian population. To (a) determine the correlation between the local genetic ancestry components and vitamin B12 levels using ninety B12-related genes; (b) determine associations between these genes and their SNPs with vitamin B12 levels; (c) determine a polygenic risk score (PRS) using significant variants. This cross-sectional study included 168 children and adolescents, aged 9–13 years old. Total cobalamin was measured in plasma. Genotyping arrays and whole exome data were combined to yield ~ 7000 SNPs in 90 genes related to vitamin B12. The Efficient Local Ancestry Inference was used to estimate local ancestry for African (AFR), Native American, and European (EUR). The association between the genotypes and vitamin B12 levels were determined with generalized estimating equation. Vitamin B12 levels were driven by positive (EUR) and negative (AFR, AMR) correlations with genetic ancestry. A set of 36 variants were used to create a PRS that explained 42% of vitamin level variation. Vitamin B12 levels are influenced by genetic ancestry and a PRS explained almost 50% of the variation in plasma cobalamin in Brazilian children and adolescents

Synonymous mutation rs1129293 is associated with PIK3CG expression and PI3Kγ activation in patients with chronic Chagas cardiomyopathy

Single nucleotide polymorphisms (SNPs) that do not change the composition of amino acids and cause synonymous mutations (sSNPs) were previously considered to lack any functional roles. However, sSNPs have recently been shown to interfere with protein expression owing to a myriad of factors related to the regulation of transcription, mRNA stability, and protein translation processes. In patients with Chagas disease, the presence of the synonymous mutation rs1129293 in phosphatidylinositol-4,5-bisphosphate 3-kinase gamma (PIK3CG) gene contributes to the development of the chronic Chagas cardiomyopathy (CCC), instead of the digestive or asymptomatic forms. In this study, we aimed to investigate whether rs1129293 is associated with the transcription of PIK3CG mRNA and its activity by quantifying AKT phosphorylation in the heart samples of 26 chagasic patients with CCC. Our results showed an association between rs1129293 and decreased PIK3CG mRNA expression levels in the cardiac tissues of patients with CCC. The phosphorylation levels of AKT, the protein target of PI3K, were also reduced in patients with this mutation, but were not correlated with PI3KCG mRNA expression levels. Moreover, bioinformatics analysis showed that rs1129293 and other SNPs in linkage disequilibrium (LD) were associated with the transcriptional regulatory elements, post-transcriptional modifications, and cell-specific splicing expression of PIK3CG mRNA. Therefore, our data demonstrates that the synonymous SNP rs1129293 is capable of affecting the PIK3CG mRNA expression and PI3Kγ activation