Deep time structural evolution of retroviral and filoviral surface envelope proteins

The retroviral surface envelope protein subunit (SU) mediates receptor binding and triggers membrane fusion by the transmembrane subunit (TM). SU evolves rapidly under strong selective conditions, resulting in seemingly unrelated SU structures in highly divergent retroviruses. Structural modeling of the SU of several retroviruses and related endogenous retroviral elements with AlphaFold identifies a TM-proximal SU β-sandwich structure that has been conserved in the orthoretroviruses for at least 110 million years. The SU of orthoretroviruses diversified by differential expansion of the β-sandwich core to form domains involved in virus-host interactions. The β-sandwich domain is also conserved in the SU equivalent GP1 of Ebola virus although with a significantly different orientation in the trimeric envelope protein structure. The unified structural view of orthoretroviral SU and filoviral GP1 identifies an ancient, structurally conserved and evolvable domain underlying the structural diversity of orthoretroviral SU and filoviral GP1.

Domain Organization of Lentiviral and Betaretroviral Surface Envelope Glycoproteins Modeled with AlphaFold

The surface envelope glycoproteins of non-primate lentiviruses and betaretroviruses share sequence similarity with the inner proximal domain β-sandwich of the human immunodeficiency virus type 1 (HIV-1) gp120 glycoprotein that faces the transmembrane glycoprotein as well as patterns of cysteine and glycosylation site distribution that points to a similar two-domain organization in at least some lentiviruses. Here, high reliability models of the surface glycoproteins obtained with the AlphaFold algorithm are presented for the gp135 glycoprotein of the small ruminant caprine arthritis-encephalitis (CAEV) and visna lentiviruses and the betaretroviruses jaagsiekte sheep retrovirus (JSRV), mouse mammary tumor virus (MMTV) and consensus human endogenous retrovirus type K (HERV-K). The models confirm and extend the inner domain structural conservation in these viruses and identify two outer domains with a putative receptor binding site in the CAEV and visna virus gp135. The location of that site is consistent with patterns of sequence conservation and glycosylation site distribution in gp135. In contrast, a single domain is modeled for the JSRV, MMTV and HERV-K betaretrovirus envelope proteins that is highly conserved structurally in the proximal region and structurally diverse in apical regions likely to interact with cell receptors. The models presented here identify sites in small ruminant lentivirus and betaretrovirus envelope glycoproteins likely to be critical for virus entry and virus neutralization by antibodies and will facilitate their functional and structural characterization. Importance Structural information on the surface envelope proteins of lentiviruses and related betaretroviruses is critical to understand mechanisms of virus-host interactions. However, experimental determination of these structures has been challenging and only the structure of the human immunodeficiency virus type 1 gp120 has been determined. The advent of the AlphaFold artificial intelligence method for structure prediction allows high-quality modeling of the structures of small ruminant lentiviral and betaretroviral surface envelope proteins. The models are consistent with much of previously described experimental data, show regions likely to interact with receptors and identify domains that may be involved in mechanisms of antibody neutralization resistance in the small ruminant lentiviruses. The models will allow more precise design of mutants to further determine mechanisms of viral entry and immune evasion in this group of viruses and constructs for structure of these surface envelope proteins.

Domain Organization of Lentiviral and Betaretroviral Surface Envelope Glycoproteins Modeled with AlphaFold

The surface envelope glycoproteins of non-primate lentiviruses and betaretroviruses share sequence similarity with the inner proximal domain β-sandwich of the human immunodeficiency virus type 1 (HIV-1) gp120 glycoprotein that faces the transmembrane glycoprotein as well as patterns of cysteine and glycosylation site distribution that points to a similar two-domain organization in at least some lentiviruses. Here, high reliability models of the surface glycoproteins obtained with the AlphaFold algorithm are presented for the gp135 glycoprotein of the small ruminant caprine arthritis-encephalitis (CAEV) and visna lentiviruses and the betaretroviruses jaagsiekte sheep retrovirus (JSRV), mouse mammary tumor virus (MMTV) and consensus human endogenous retrovirus type K (HERV-K). The models confirm and extend the inner domain structural conservation in these viruses and identify two outer domains with a putative receptor binding site in the CAEV and visna virus gp135. The location of that site is consistent with patterns of sequence conservation and glycosylation site distribution in gp135. In contrast, a single domain is modeled for the JSRV, MMTV and HERV-K betaretrovirus envelope proteins that is highly conserved structurally in the proximal region and structurally diverse in apical regions likely to interact with cell receptors. The models presented here identify sites in small ruminant lentivirus and betaretrovirus envelope glycoproteins likely to be critical for virus entry and virus neutralization by antibodies and will facilitate their functional and structural characterization.

Small Molecule HIV-1 Attachment Inhibitors: Discovery, Mode of Action and Structural Basis of Inhibition

Viral entry into host cells is a critical step in the viral life cycle. HIV-1 entry is mediated by the sole surface envelope glycoprotein Env and is initiated by the interaction between Env and the host receptor CD4. This interaction, referred to as the attachment step, has long been considered an attractive target for inhibitor discovery and development. Fostemsavir, recently approved by the FDA, represents the first-in-class drug in the attachment inhibitor class. This review focuses on the discovery of temsavir (the active compound of fostemsavir) and analogs, mechanistic studies that elucidated the mode of action, and structural studies that revealed atomic details of the interaction between HIV-1 Env and attachment inhibitors. Challenges associated with emerging resistance mutations to the attachment inhibitors and the development of next-generation attachment inhibitors are also highlighted.

The barley lectin, horcolin, binds high-mannose glycans in a multivalent fashion, enabling high-affinity, specific inhibition of cellular HIV infection

N-Linked glycans are critical to the infection cycle of HIV, and most neutralizing antibodies target the high-mannose glycans found on the surface envelope glycoprotein-120 (gp120). Carbohydrate-binding proteins, particularly mannose-binding lectins, have also been shown to bind these glycans. Despite their therapeutic potency, their ability to cause lymphocyte proliferation limits their application. In this study, we report one such lectin named horcolin (Hordeum vulgare lectin), seen to lack mitogenicity owing to the divergence in the residues at its carbohydrate-binding sites, which makes it a promising candidate for exploration as an anti-HIV agent. Extensive isothermal titration calorimetry experiments reveal that the lectin was sensitive to the length and branching of mannooligosaccharides and thereby the total valency. Modeling and simulation studies demonstrate two distinct modes of binding, a monovalent binding to shorter saccharides and a bivalent mode for higher glycans, involving simultaneous interactions of multiple glycan arms with the primary carbohydrate-binding sites. This multivalent mode of binding was further strengthened by interactions of core mannosyl residues with a secondary conserved site on the protein, leading to an exponential increase in affinity. Finally, we confirmed the interaction of horcolin with recombinant gp120 and gp140 with high affinity and inhibition of HIV infection at nanomolar concentrations without mitogenicity.

Generation of Equine Herpesvirus type 1 glycoprotein pseudotyped lentiviral particles for use as a tool for tropism and diagnostic studies

Equine herpesviruses (EHVs) are enveloped DNA viruses infecting mainly members of the Equidae family and also members of other taxa. EHVs primarily causing respiratory disease, however EHV type 1 (EHV-1) can produce cases of a neurological disease, abortion and neonatal death, sometimes as regional outbreaks. Thus these viruses represent a welfare issue for the equine industry and scientific focus for researchers. EHV-1 presents a complex array of 12 glycoproteins on its surface envelope, but it is unclear which ones are important for virus cell entry and the role of each in host immune response. In order to investigate the contribution of these glycoproteins, pseudotype viruses (PVs) could provide a perfect study tool. In 2016, Rogalin & Heldwein successfully generated the first functional herpesvirus pseudotype, bearing the four glycoproteins gB, gD, gH and gL from human Herpes simplex 1. Our study is the first to attempt pseudotyping of EHV-1. We have employed homologous glycoproteins of EHV-1 in lentivirus PV generation, using different mammalian cells (e.g. epithelial, dermal, CNS) as transduction targets. The glycoprotein sequences obtained from an EHV-1 strain isolated from organs of aborted foetus during a significant outbreak in Normandy (France) in 2010. Future work will focus on the development of a PV assay for detection of neutralising antibodies in naturally infected horses for diagnostics and for vaccine evaluation.

Crystal structure of inhibitor-bound human MSPL that can activate high pathogenic avian influenza

Viral infection is triggered when a surface envelope glycoprotein, hemagglutinin (HA), is cleaved by host cell proteins of the transmembrane protease serine (TMPRSS) family. The extracellular region of TMPRSS-2, -3, -4, and MSPL are composed of LDLA, SRCR, and SPD domains. MSPL can cleave the consensus multibasic (R-X-X/R-R) and monobasic (Q(E)-T/X-R) motifs on HA, while TMPRSS2 or -4 only cleaves monobasic motifs. To better understand HA cleavage mediated by MSPL, we solved the crystal structure of the extracellular region of human MSPL in complex with the furin inhibitor. The structure revealed that three domains are gathered around the C-terminal α-helix of the SPD domain. The furin inhibitor structure shows that the side chain of P1-Arg inserts into the highly conserved S1 pocket, whereas the side chain of P2-Lys interacts with the Asp/Glu-rich 99 loop that is unique to MSPL. We also constructed a homology model of TMPRSS2, which is identified as an initiator of SARS-CoV-2 infection. The model suggests that TMPRSS2 is more suitable for Ala/Val residues at the P2 site than Lys/Arg residues.

Sars-CoV-2 Envelope and Membrane Proteins: Differences from Closely Related Proteins Linked to Cross-species Transmission?

The Coronavirus disease (COVID-19) is a new viral infection caused by severe acute respiratory coronavirus 2 (SARS-CoV-2) that was initially reported in city of Wuhan, China and afterwards spread globally. Genomic analyses revealed that SARS-CoV-2 is phylogenetically related to severe acute respiratory syndrome-like (SARS-like) Pangolin and Bat coronavirus specific isolates. In this study we focused on two proteins of Sars-CoV-2 surface: Envelope protein and Membrane protein. Sequences from Sars-CoV-2 isolates and other closely related virus were collected from the GenBank through TBlastN searches. The retrieved sequences were multiply aligned with MAFFT. The Envelope protein is identical to the counterparts from Pangolin CoV MP798 isolate and Bat CoV isolates CoVZXC21, CoVZC45 and RaTG13. However, a substitution at position 69 where an Arg replace for Glu, and a deletion in position 70 corresponding to Gly or Cys in other Envelope proteins were found. The Membrane glycoprotein appears more variable with respect to the SARS CoV proteins than the Envelope: a heterogeneity at the N-terminal position, exposed to the virus surface, was found between Pangolin CoV MP798 isolate and Bat CoV isolates CoVZXC21, CoVZC45 and RaTG13. Mutations observed on Envelope protein are drastic and may have significant implications for conformational properties and possibly for protein-protein interactions. Mutations on Membrane protein may also be relevant because this protein cooperates with the Spike during the cell attachment and entry. Therefore, these mutations may influence interaction with host cells. The mutations that have been detected in these comparative studies may reflect functional peculiarities of the Sars-CoV-2 virus and may help explaining the epizootic origin the COVID-19 epidemic.

Hepatitis B Virus (HBV) Subviral Particles as Protective Vaccines and Vaccine Platforms

Hepatitis B remains one of the major global health problems more than 40 years after the identification of human hepatitis B virus (HBV) as the causative agent. A critical turning point in combating this virus was the development of a preventative vaccine composed of the HBV surface (envelope) protein (HBsAg) to reduce the risk of new infections. The isolation of HBsAg sub-viral particles (SVPs) from the blood of asymptomatic HBV carriers as antigens for the first-generation vaccines, followed by the development of recombinant HBsAg SVPs produced in yeast as the antigenic components of the second-generation vaccines, represent landmark advancements in biotechnology and medicine. The ability of the HBsAg SVPs to accept and present foreign antigenic sequences provides the basis of a chimeric particulate delivery platform, and resulted in the development of a vaccine against malaria (RTS,S/AS01, MosquirixTM), and various preclinical vaccine candidates to overcome infectious diseases for which there are no effective vaccines. Biomedical modifications of the HBsAg subunits allowed the identification of strategies to enhance the HBsAg SVP immunogenicity to build potent vaccines for preventative and possibly therapeutic applications. The review provides an overview of the formation and assembly of the HBsAg SVPs and highlights the utilization of the particles in key effective vaccines.