Selection and structural analysis of the NY25 peptide - A vaccine candidate from hemagglutinin of swine-origin Influenza H1N1.

The aim of this study was to construct a vaccine peptide candidate against pandemic Influenza H1N1 hemagglutinin and to test its structure. With the help of bioinformatic algorithms we showed that the sequence encoding the second polypeptide of pandemic Influenza H1N1 hemagglutinin (HA2) is protected from nonsynonymous mutations better than the sequence encoding its first polypeptide (HA1). With the help of secondary and ternary structure predicting algorithms we found the fragment of HA2 with the most reproducible secondary structure and synthesized the NY25 peptide corresponding to the residues Asn117 - Tyr141 of HA2. According to the circular dichroism spectra analysis, the peptide has short helix and beta hairpin. According to the analysis of differential fluorescence quenching results, two tyrosine residues are situated on a long distance from each other. These facts taken together with the positive results of affine chromatography with the serum of a person immunized by full-length hemagglutinin confirm that the structure of the fragment of viral full-length protein has been reproduced in the synthetic NY25 peptide. Amino acid sequence of the NY25 peptide (NLYEKVRSQLKNNAKEIGNGCFEFY) is relatively conserved in 18 subtypes of Influenza A virus hemagglutinin.

The alpha helix 1 from the first conserved region of HIV1 gp120 is reconstructed in the short NQ21 peptide.

Investigations of short peptides that can be used in the next phase of synthetic HIV1 vaccine development are an urgent goal, as well as investigations of peptides that can be used in immunological tests with the aim to check the titer of antibodies against the alpha helix 1 from the first conserved region of HIV1 gp120 that are known to cause antibody-dependent cellular cytotoxicity (ADCC). The aim of this work was to study the structure of the NQ21 peptide corresponding to the less mutable part of the first conserved region of HIV1 gp120 (residues 94-114). The NQ21 peptide and its conjugate with biotin (biotin-NQ21) are absolutely alpha-helical in phosphate buffer solutions at pH = 6.8, 7.4 and 8.0, as well as in the dried form, according to the results of surface-enhanced Raman scattering (SERS) spectroscopy. Results of the native gel electrophoresis and thermal analysis under the control of spectrofluorometer and near UV circular dichroism (CD) showed that the peptide exists in form of octamers and tetramers at pH = 7.4, that is important information for further vaccine development. Strong signal of interacting Trp residues in oligomers in the far UV CD obscures the signal from secondary structure, but becomes less intensive during the heating.

Peptide Models of the Cytoplasmic Tail of Influenza A/H1N1 Virus Hemagglutinin Expand Understanding its pH-Dependent Modes of Interaction with Matrix Protein M1.

Influenza A virus hemagglutinin (HA) is a major virus antigen. No cryo-electron microscopy or X-ray data can be obtained for the HA intraviral (cytoplasmic) domain (CT) post-translationally modified with long fatty acid residues bound to three highly conserved cysteines. We recently proposed a model of HA CT of Influenza A/H1N1 virus possessing an antiparallel beta structure based on the experimental secondary structure analysis of four 14-15 amino acid long synthetic peptides, corresponding to the HA CT sequence, with free or acetaminomethylated cysteines. To dispel doubts about possible non-specific "amyloid-like" aggregation of those synthetic peptides in phosphate buffer solution, we have determined the order of oligomers based on blue native gel electrophoresis, membrane filtration, fluorescence spectroscopy and molecular modeling approaches. We have found that unmodified peptides form only low molecular weight oligomers, while modified peptides form both oligomers of low order similar to those found for unmodified peptides and high order conglomerates, which however are not of beta-amyloid-like fold. This study confirms that the beta structure previously detected by circular dichroism spectroscopy analysis is more likely the result of intrinsic propensity of the HA CT amino acid sequence than the consequence of aggregation. The structures of low order oligomers of the synthetic peptides were used for in silico experiments on modeling of HA CT interactions with matrix protein M1 at physiological and acidic pH levels and revealed two different areas of binding. Finally, tripeptides capable of blocking interactions between HA CT and M1 were proposed.

Equilibrium Between Dimeric and Monomeric Forms of Human Epidermal Growth Factor is Shifted Towards Dimers in a Solution.

An interplay between monomeric and dimeric forms of human epidermal growth factor (EGF) affecting its interaction with EGF receptor (EGFR) is poorly understood. While EGF dimeric structure was resolved at pH 8.1, the possibility of EGF dimerization under physiological conditions is still unclear. This study aimed to describe the oligomeric state of EGF in a solution at physiological pH value. With centrifugal ultrafiltration followed by blue native gel electrophoresis, we showed that synthetic human EGF in a solution at a concentration of 0.1 mg/ml exists mainly in the dimeric form at pH 7.4 and temperature of 37 °C, although a small fraction of its monomers was also observed. Based on bioinformatics predictions, we introduced the D46G substitution to examine if EGF C-terminal part is directly involved in the intermolecular interface formation of the observed dimers. We found a reduced ability of the resulting EGF D46G dimers to dissociate at temperatures up to 50 °C. The D46G substitution also increased the intermolecular antiparallel ß-structure content within the EGF peptide in a solution according to the CD spectra analysis that was confirmed by HATR-FTIR results. Additionally, the energy transfer between Tyr and Trp residues was detected by fluorescence spectroscopy for the EGF D46G mutant, but not for the native EGF. This allowed us to suggest the elongation and rearrangement of the intermolecular ß-structure that leads to the observed stabilization of EGF D46G dimers. The results imply EGF dimerization under physiological pH value and temperature and the involvement of EGF C-terminal part in this process.