Why does the herpes simplex 1 virus-encoded UL49.5 protein fail to inhibit the TAP-dependent antigen presentation?

Herpes simplex virus 1 (HSV-1) is a well-studied herpesvirus that causes various human diseases. Like other herpesviruses, HSV-1 produces the transmembrane glycoprotein N (gN/UL49.5 protein), which has been extensively studied, but its function in HSV-1 remains largely unknown. The amino-acid sequences and lengths of UL49.5 proteins differ between herpesvirus species. It is, therefore, crucial to determine whether and to what extent the spatial structure of UL49.5 orthologs that are transporter associated with antigen processing (TAP) inhibitors (i.e., of bovine herpesvirus 1; BoHV-1) differ from that of non-TAP inhibitors (i.e., of HSV-1). Our study aimed to examine the 3D structure of the HSV-1-encoded UL49.5 protein in an advanced model of the endoplasmic reticulum (ER) membrane using circular dichroism, 2D nuclear magnetic resonance, and multiple-microsecond all-atom molecular dynamics simulations in an ER membrane mimetic environment. According to our findings, the N-terminus of the HSV-1-encoded UL49.5 adopts a highly flexible, unordered structure in the extracellular part due to the presence of a large number of proline and glycine residues. In contrast to the BoHV-1-encoded homolog, the transmembrane region of the HSV-1-encoded UL49.5 is formed by a single long transmembrane α-helix, rather than two helices oriented perpendicularly, while the cytoplasmic part of the protein (C-terminus) has a short unordered structure. Our findings provide valuable experimental structural information on the HSV-1-encoded UL49.5 protein and offer, based on the obtained structure, insight into its lack of biological activity in inhibiting the TAP-dependent antigen presentation pathway.

Three Component Composite Scaffolds Based on PCL, Hydroxyapatite, and L-Lysine Obtained in TIPS-SL: Bioactive Material for Bone Tissue Engineering.

In this research, we describe the properties of three-component composite foam scaffolds based on poly(ε-caprolactone) (PCL) as a matrix and hydroxyapatite whiskers (HAP) and L-Lysine as fillers (PCL/HAP/Lys with wt% ratio 50/48/2). The scaffolds were prepared using a thermally induced phase separation technique supported by salt leaching (TIPS-SL). All materials were precisely characterized: porosity, density, water uptake, wettability, DSC, and TGA measurements and compression tests were carried out. The microstructure of the obtained scaffolds was analyzed via SEM. It was found that the PCL/HAP/Lys scaffold has a 45% higher Young's modulus and better wettability compared to the PCL/HAP system. At the same time, the porosity of the system was ~90%. The osteoblast hFOB 1.19 cell response was also investigated in osteogenic conditions (39 °C) and the cytokine release profile of interleukin (IL)-1ß, IL-6, and tumor necrosis factor (TNF)-α was determined. Modification of PCL scaffolds with HAP and L-Lysine significantly improved the proliferation of pre-osteoblasts cultured on such materials.

Investigation of the Effects of Primary Structure Modifications within the RRE Motif on the Conformation of Synthetic Bovine Herpesvirus 1-Encoded UL49.5 Protein Fragments.

Herpesviruses are the most prevalent viruses that infect the human and animal body. They can escape a host immune response in numerous ways. One way is to block the TAP complex so that viral peptides, originating from proteasomal degradation, cannot be transported to the endoplasmic reticulum. As a result, a reduced number of MHC class I molecules appear on the surface of infected cells and, thus, the immune system is not efficiently activated. BoHV-1-encoded UL49.5 protein is one such TAP transporter inhibitor. This protein binds to TAP in such a way that its N-terminal fragment interacts with the loops of the TAP complex, and the C-terminus stimulates proteasomal degradation of TAP. Previous studies have indicated certain amino acid residues, especially the RRE(9-11) motif, within the helical structure of the UL49.5 N-terminal fragment, as being crucial to the protein's activity. In this work, we investigated the effects of modifications within the RRE region on the spatial structure of the UL49.5 N-terminal fragment. The introduced RRE(9-11) variations were designed to abolish or stabilize the structure of the α-helix and, consequently, to increase or decrease protein activity compared to the wild type. The terminal structure of the peptides was established using circular dichroism (CD), 2D nuclear magnetic resonance (NMR), and molecular dynamics (MD) in membrane-mimetic or membrane-model environments. Our structural results show that in the RRE(9-11)AAA and E11G peptides the helical structure has been stabilized, whereas for the RRE(9-11)GGG peptide, as expected, the helix structure has partially unfolded compared to the native structure. These RRE modifications, in the context of the entire UL49.5 proteins, slightly altered their biological activity in human cells.

Imunofan-RDKVYR Peptide-Stimulates Skin Cell Proliferation and Promotes Tissue Repair.

Regeneration and wound healing are vital to tissue homeostasis and organism survival. One of the biggest challenges of today's science and medicine is finding methods and factors to stimulate these processes in the human body. Effective solutions to promote regenerative responses will accelerate advances in tissue engineering, regenerative medicine, transplantology, and a number of other clinical specialties. In this study, we assessed the potential efficacy of a synthetic hexapeptide, RDKVYR, for the stimulation of tissue repair and wound healing. The hexapeptide is marketed under the name "Imunofan" (IM) as an immunostimulant. IM displayed stability in aqueous solutions, while in plasma it was rapidly bound by albumins. Structural analyses demonstrated the conformational flexibility of the peptide. Tests in human fibroblast and keratinocyte cell lines showed that IM exerted a statistically significant (p < 0.05) pro-proliferative activity (30-40% and 20-50% increase in proliferation of fibroblast and keratinocytes, respectively), revealed no cytotoxicity over a vast range of concentrations (p < 0.05), and had no allergic properties. IM was found to induce significant transcriptional responses, such as enhanced activity of genes involved in active DNA demethylation (p < 0.05) in fibroblasts and activation of genes involved in immune responses, migration, and chemotaxis in adipose-derived stem cells derived from surgery donors. Experiments in a model of ear pinna injury in mice indicated that IM moderately promoted tissue repair (8% in BALB/c and 36% in C57BL/6 in comparison to control).

Structure determination of UL49.5 transmembrane protein from bovine herpesvirus 1 by NMR spectroscopy and molecular dynamics.

The transporter associated with antigen processing (TAP) directly participates in the immune response as a key component of the cytosolic peptide to major histocompatibility complex (MHC) class I protein loading machinery. This makes TAP an important target for viruses avoiding recognition by CD8+ T lymphocytes. Its activity can be suppressed by the UL49.5 protein produced by bovine herpesvirus 1, although the mechanism of this inhibition has not been understood so far. Therefore, the main goal of our study was to investigate the 3D structure of bovine herpesvirus 1 - encoded UL49.5 protein. The final structure of the inhibitor was established using circular dichroism (CD), 2D nuclear magnetic resonance (NMR), and molecular dynamics (MD) in membrane mimetic environments. In NMR studies, UL49.5 was represented by two fragments: the extracellular region (residues 1-35) and the transmembrane-intracellular fragment (residues 36-75), displaying various functions during viral invasion. After the empirical structure determination, a molecular docking procedure was used to predict the complex of UL49.5 with the TAP heterodimer. Our results revealed that UL49.5 adopted a highly flexible membrane-proximal helical structure in the extracellular part. In the transmembrane region, we observed two short α-helices. Furthermore, the cytoplasmic part had an unordered structure. Finally, we propose three different orientations of UL49.5 in the complex with TAP. Our studies provide, for the first time, the experimental structural information on UL49.5 and structure-based insight in its mechanism of action which might be helpful in designing new drugs against viral infections.

Structural studies of the C-terminal 19-peptide of serum amyloid A and its Pro → Ala variants interacting with human cystatin C.

Serum amyloid A (SAA) is a multifunctional acute-phase protein whose concentration in serum increases markedly following a number of chronic inflammatory and neoplastic diseases. Prolonged high SAA level may give rise to reactive systemic amyloid A (AA) amyloidosis, where the N-terminal segment of SAA is deposited as amyloid fibrils. Besides, recently, well-documented association of SAA with high-density lipoprotein or glycosaminoglycans, in particular heparin/heparin sulfate (HS), and specific interaction between SAA and human cystatin C (hCC), the ubiquitous inhibitor of cysteine proteases, was proved. Using a combination of selective proteolytic excision and high-resolution mass spectrometry, a hCC binding site in the SAA sequence was determined as SAA(86-104). The role of this SAA C-terminal fragment as a ligand-binding locus is still not clear. It was postulated important in native SAA folding and in pathogenesis of AA amyloidosis. In the search of conformational details of this SAA fragment, we did its structure and affinity studies, including its selected double/triple Pro → Ala variants. Our results clearly show that the SAA(86-104) 19-peptide has rather unordered structure with bends in its C-terminal part, which is consistent with the previous results relating to the whole protein. The results of affinity chromatography, fluorescent ELISA-like test, CD and NMR studies point to an importance of proline residues on structure of SAA(86-104). Conformational details of SAA fragment, responsible for hCC binding, may help to understand the objective of hCC-SAA complex formation and its importance for pathogenesis of reactive amyloid A amyloidosis.