H9N2 virus-derived M1 protein promotes H5N6 virus release in mammalian cells: Mechanism of avian influenza virus inter-species infection in humans

H5N6 highly pathogenic avian influenza virus (HPAIV) clade 2.3.4.4 not only exhibits unprecedented intercontinental spread in poultry, but can also cause serious infection in humans, posing a public health threat. Phylogenetic analyses show that 40% (8/20) of H5N6 viruses that infected humans carried H9N2 virus-derived internal genes. However, the precise contribution of H9N2 virus-derived internal genes to H5N6 virus infection in humans is unclear. Here, we report on the functional contribution of the H9N2 virus-derived matrix protein 1 (M1) to enhanced H5N6 virus replication capacity in mammalian cells. Unlike H5N1 virus-derived M1 protein, H9N2 virus-derived M1 protein showed high binding affinity for H5N6 hemagglutinin (HA) protein and increased viral progeny particle release in different mammalian cell lines. Human host factor, G protein subunit beta 1 (GNB1), exhibited strong binding to H9N2 virus-derived M1 protein to facilitate M1 transport to budding sites at the cell membrane. GNB1 knockdown inhibited the interaction between H9N2 virus-derived M1 and HA protein, and reduced influenza virus-like particles (VLPs) release. Our findings indicate that H9N2 virus-derived M1 protein promotes avian H5N6 influenza virus release from mammalian, in particular human cells, which could be a major viral factor for H5N6 virus cross-species infection.

Lysozyme-like Protein Produced by Bifidobacterium longum Regulates Human Gut Microbiota Using In Vitro Models

The extracellular secreted protein of Bifidobacterium longum (B. longum) plays an important role in maintaining the homeostasis of the human intestinal microenvironment. However, the mechanism(s) of interaction remain unclear. Lysozyme is a kind of antibacterial peptide. In this study, the amino acid sequence of a lysozyme-like protein of B. longum based on whole-genome data of an isolate from human gut feces was found. We further predicted functional domains from the amino acid sequence, purified the protein, and verified its bioactivity. The growth of some bacteria were significantly delayed by the 020402_LYZ M1 protein. In addition, the gut microbiota was analyzed via high-throughput sequencing of 16S rRNA genes and an in vitro fermentation model, and the fluctuations in the gut microbiota under the treatment of 020402_LYZ M1 protein were characterized. The 020402_LYZ M1 protein affected the composition of human gut microbiota significantly, implying that the protein is able to communicate with intestinal microbes as a regulatory factor.

An Intracellular Human Single Chain Antibody to Matrix Protein (M1) of H5N1 Virus

Background: Influenza virus matrix protein M1 is encoded by viral RNA fragment 7 and is the most abundant protein in virus particles. M1 is expressed in the late stages of viral replication and exerts functionality by inhibiting viral transcription. The M1 protein sequence is an attractive target for antibody drugs.Methods: The M1 protein sequence was amplified by RT-PCR using cDNA from the H5N1 virus as a template; the M1 protein was then expressed and purified. A human strain, high affinity, and single chain antibody (HuScFv) against M1 protein was obtained by phage antibody library screening using M1 as an antigen. A recombinant TAT-HuScFv protein was expressed by fusion with the TAT protein transduction domain (PTD) gene of HIV to prepare a human intracellular antibody against avian influenza virus. The differences between HuScFv and TAT-HUScFv were verified by various experiments and the amino acid binding site of the M1 protein was determined.Results: The M1 protein of H5N1, HuScFv, and TAT-HuScFv, were successfully purified and expressed by and in E. coli. Further analysis demonstrated that TAT-HuScFv inhibited the hemagglutination activity of the 300TCID50 H1N1 virus, thus providing preliminary validation of the universality of the antibody. After two rounds of M1 protein decomposition, the TAT-HuScFv antigen binding site was identified as Alanine (A) at position 239. Collectively, our data describe a recombinant antibody with high binding activity against the conserved sequences of avian influenza viruses. This intracellular recombinant antibody blocked the M1 protein that infected intracellular viruses, thus inhibiting the replication and reproduction of H5N1 viruses.Conclusion: Recombinant HuScFv was successfully identified using the Tomlinson (I+J) phage antibody library and successfully linked to the TAT protein transductive domain of the HIV virus. Compared with the HuScFv, the addition of the TAT peptide improved its ability to penetrate the cell membrane. A definite amino acid binding site was identified after the decomposition of M1 protein, thus providing a target and reference for the development of antibody drugs and the study of new drugs.

Structural determination of Streptococcus pyogenes M1 protein interactions with human immunoglobulin G using integrative structural biology

Streptococcus pyogenes (Group A streptococcus; GAS) is an important human pathogen responsible for mild to severe, life-threatening infections. GAS expresses a wide range of virulence factors, including the M family proteins. The M proteins allow the bacteria to evade parts of the human immune defenses by triggering the formation of a dense coat of plasma proteins surrounding the bacteria, including IgGs. However, the molecular level details of the M1-IgG interaction have remained unclear. Here, we characterized the structure and dynamics of this interaction interface in human plasma on the surface of live bacteria using integrative structural biology, combining cross-linking mass spectrometry and molecular dynamics (MD) simulations. We show that the primary interaction is formed between the S-domain of M1 and the conserved IgG Fc-domain. In addition, we show evidence for a so far uncharacterized interaction between the A-domain and the IgG Fc-domain. Both these interactions mimic the protein G-IgG interface of group C and G streptococcus. These findings underline a conserved scavenging mechanism used by GAS surface proteins that block the IgG-receptor (FcγR) to inhibit phagocytic killing. We additionally show that we can capture Fab-bound IgGs in a complex background and identify XLs between the constant region of the Fab-domain and certain regions of the M1 protein engaged in the Fab-mediated binding. Our results elucidate the M1-IgG interaction network involved in inhibition of phagocytosis and reveal important M1 peptides that can be further investigated as future vaccine targets.

Investigating the impact of M1 protein from Group A Streptococcus on fibrin clot formation, structure and fibrinolytic potential

Background: Fibrin formation is an essential part of innate immunity, sealing off infections to limit bacterial spreading.The surface-anchored M1 protein is a major virulence determinant of Group A streptococcus (GAS). During early infection M1 is cleaved from the cell surface by SpeB, a streptococcal protease regulated by CovR/S. M1 forms a supramolecular complex with fibrinogen however the impact on fibrin formation is not known. Methods: The effects of recombinant M1 (rM1) were assessed in fibrin clots made from plasma or purified fibrinogen incubated with thrombin, by confocal microscopy and scanning electron microscopy. Clotting and lysis profiles (with plasminogen activators and plasminogen) were investigated kinetically using thromboelastography (ROTEM). Results: rM1 (0.47-60 μg/ml) increased clotting rates to produce heterogeneous clots with irregular fibre bundles and compacted fibrin. Formation of the protective fibrin biofilm was also disrupted by rM1. Furthermore, mechanical strength of fibrin clots was reduced with increasing rM1 concentrations and was undetectable above 15.5 μg/ml. Purified and plasma clots formed with rM1 were more susceptible to lysis by plasmin, with a 1.4 – 2-fold reduction in lysis times. Conclusions: At sites of GAS infection, cleaved M1 may bind to fibrinogen generating fibrin clots which: lack the protective film at the clot surface; are mechanically weaker; and are less resistant to lysis by plasmin. GAS strains of M1-type are commonly associated with invasive infections; the impact of M1 on fibrin structure could contribute to the severity of GAS infection by compromising the fibrin barrier that limits bacterial proliferation and migration.