Biomolecular condensates with liquid properties formed during viral infections.

During a viral infection, several membraneless compartments with liquid properties are formed. They can be of viral origin concentrating viral proteins and nucleic acids, and harboring essential stages of the viral cycle, or of cellular origin containing components involved in innate immunity. This is a paradigm shift in our understanding of viral replication and the interaction between viruses and innate cellular immunity.

Properties of rabies virus phosphoprotein and nucleoprotein biocondensates formed in vitro and in cellulo.

Rabies virus (RABV) transcription and replication take place within viral factories having liquid properties, called Negri bodies (NBs), that are formed by liquid-liquid phase separation (LLPS). The co-expression of RABV nucleoprotein (N) and phosphoprotein (P) in mammalian cells is sufficient to induce the formation of cytoplasmic biocondensates having properties that are like those of NBs. This cellular minimal system was previously used to identify P domains that are essential for biocondensates formation.

Negri bodies and other virus membrane-less replication compartments.

Viruses reshape the organization of the cell interior to achieve different steps of their cellular cycle. Particularly, viral replication and assembly often take place in viral factories where specific viral and cellular proteins as well as nucleic acids concentrate. Viral factories can be either membrane-delimited or devoid of any cellular membranes.

Identification of a pH-Sensitive Switch in VSV-G and a Crystal Structure of the G Pre-fusion State Highlight the VSV-G Structural Transition Pathway.

VSV fusion machinery, like that of many other enveloped viruses, is triggered at low pH in endosomes after virion endocytosis. It was suggested that some histidines could play the role of pH-sensitive switches. By mutating histidine residues H22, H60, H132, H162, H389, H397, H407, and H409, we demonstrate that residues H389 and D280, facing each other in the six-helix bundle of the post-fusion state, and more prominently H407, located at the interface between the C-terminal part of the ectodomain and the fusion domain, are crucial for fusion.

Crystal structure of Mokola virus glycoprotein in its post-fusion conformation.

Mokola virus (MOKV) belongs to the lyssavirus genus. As other genus members-including rabies virus (RABV)-it causes deadly encephalitis in mammals. MOKV entry into host cells is mediated by its transmembrane glycoprotein G.

Structural and cellular biology of rhabdovirus entry.

Rhabdoviruses are enveloped viruses with a negative-sense single strand RNA genome and are widespread among a great variety of organisms. In their membrane, they have a single glycoprotein (G) that mediates both virus attachment to cellular receptors and fusion between viral and endosomal membranes allowing viral genome release in the cytoplasm. We present structural and cellular aspects of Rhabdovirus entry into their host cell with a focus on vesicular stomatitis virus (VSV) and rabies virus (RABV) for which the early events of the viral cycle have been extensively studied.

Monomeric Intermediates Formed by Vesiculovirus Glycoprotein during Its Low-pH-induced Structural Transition.

• Vesiculovirus G is the prototype of class III viral fusion glycoproteins. • The structures of both G pre- and post-fusion conformation have been determined. • The structure of monomeric intermediates reveals the pathway of the transition.

Structural intermediates in the fusion-associated transition of vesiculovirus glycoprotein.

Vesiculoviruses enter cells by membrane fusion, driven by a large, low-pH-induced, conformational change in the fusion glycoprotein G that involves transition from a trimeric pre-fusion toward a trimeric post-fusion state via monomeric intermediates. Here, we present the structure of the G fusion protein at intermediate pH for two vesiculoviruses, vesicular stomatitis virus (VSV) and Chandipura virus (CHAV), which is responsible for deadly encephalopathies. First, a CHAV G crystal structure shows two intermediate conformations forming a flat dimer of heterodimers.

Recent mechanistic and structural insights on class III viral fusion glycoproteins.

Enveloped viruses enter the cell by fusing their envelope with a cellular membrane. Fusion is catalyzed by conformational changes of viral glycoproteins from pre-fusion to post-fusion states. Structural studies have defined three classes of viral fusion glycoproteins.

Structure of the low pH conformation of Chandipura virus G reveals important features in the evolution of the vesiculovirus glycoprotein.

Chandipura virus (CHAV), a member of the vesiculovirus genus, is an emerging human pathogen. As for other rhabdoviruses, CHAV entry into susceptible cells is mediated by its single envelope glycoprotein G which is both involved in receptor recognition and fusion of viral and cellular membranes. Here, we have characterized the fusion properties of CHAV-G.

Intermediate conformations during viral fusion glycoprotein structural transition.

Entry of enveloped viruses into cells requires the fusion of viral and cellular membranes, driven by conformational changes in viral glycoproteins. Three different classes of viral fusion proteins have been hitherto identified based on common structural elements. Crystal structures have provided static pictures of pre-fusion and post-fusion conformations of these proteins and have revealed the dramatic reorganization of the molecules, but the transition pathway remains elusive.

Crystallization and preliminary X-ray analysis of Chandipura virus glycoprotein G.

Fusion in members of the Rhabdoviridae virus family is mediated by the G glycoprotein. At low pH, the G glycoprotein catalyzes fusion between viral and endosomal membranes by undergoing a major conformational change from a pre-fusion trimer to a post-fusion trimer. The structure of the G glycoprotein from vesicular stomatitis virus (VSV G), the prototype of Vesiculovirus, has recently been solved in its trimeric pre-fusion and post-fusion conformations; however, little is known about the structural details of the transition.

Characterization of monomeric intermediates during VSV glycoprotein structural transition.

Entry of enveloped viruses requires fusion of viral and cellular membranes, driven by conformational changes of viral glycoproteins. Crystal structures provide static pictures of pre- and post-fusion conformations of these proteins but the transition pathway remains elusive. Here, using several biophysical techniques, including analytical ultracentrifugation, circular dichroïsm, electron microscopy and small angle X-ray scattering, we have characterized the low-pH-induced fusogenic structural transition of a soluble form of vesicular stomatitis virus (VSV) glycoprotein G ectodomain (G(th), aa residues 1-422, the fragment that was previously crystallized).

Molecular and cellular aspects of rhabdovirus entry.

Rhabdoviruses enter the cell via the endocytic pathway and subsequently fuse with a cellular membrane within the acidic environment of the endosome. Both receptor recognition and membrane fusion are mediated by a single transmembrane viral glycoprotein (G). Fusion is triggered via a low-pH induced structural rearrangement.

Fossil rhabdoviral sequences integrated into arthropod genomes: ontogeny, evolution, and potential functionality.

Retroelements represent a considerable fraction of many eukaryotic genomes and are considered major drives for adaptive genetic innovations. Recent discoveries showed that despite not normally using DNA intermediates like retroviruses do, Mononegaviruses (i.e.

Structure and working of viral fusion machinery.

This chapter discusses the structure and working of viral fusion machinery. The entry of enveloped viruses into cells requires the fusion of viral and cellular membranes, driven by conformational changes in viral glycoproteins. Structural studies have defined three classes of viral membrane fusion proteins.

Rabies virus transcription and replication.

Rabies virus (RABV) is a negative-stranded RNA virus. Its genome is tightly encapsidated by the viral nucleoprotein (N) and this RNA-N complex is the template for transcription and replication by the viral RNA-dependent RNA polymerase (L) and its cofactor, the phosphoprotein (P). We present molecular, structural, and cellular aspects of RABV transcription and replication.

Distinct structural rearrangements of the VSV glycoprotein drive membrane fusion.

The entry of enveloped viruses into cells requires the fusion of viral and cellular membranes, driven by conformational changes in viral glycoproteins. Many studies have shown that fusion involves the cooperative action of a large number of these glycoproteins, but the underlying mechanisms are unknown. We used electron microscopy and tomography to study the low pH-induced fusion reaction catalyzed by vesicular stomatitis virus glycoprotein (G).

Binding of rabies virus polymerase cofactor to recombinant circular nucleoprotein-RNA complexes.

In rabies virus, the attachment of the L polymerase (L) to the viral nucleocapsids (NCs)-a nucleoprotein (N)-RNA complex that serves as template for RNA transcription and replication-is mediated by the polymerase cofactor, the phosphoprotein (P). P forms dimers (P(2)) that bind through their C-terminal domains (P(CTD)) to the C-terminal region of the N. Recombinant circular N(m)-RNA complexes containing 9 to 12 protomers of N (hereafter, the subscript m denotes the number of N protomers) served here as model systems for studying the binding of P to NC-like N(m)-RNA complexes.

[Structures of rhabdovirus glycoprotein].

Glycoprotein G of the rhabdoviruses is involved in both receptor recognition at the host cell surface and membrane fusion via a low pHinduced structural rearrangement. G is an atypical fusion protein as there is a pH-dependent equilibrium between the pre- and post-fusion conformations of the protein. The atomic structures of the pre- and post-fusion conformations reveal that G is homologous to both glycoprotein gB of herpesviruses and gp64 of baculovirus and also that it combines features of the previously characterized class I and class II fusion proteins.

Isolation and crystallization of a unique size category of recombinant Rabies virus Nucleoprotein-RNA rings.

In order to study the packaging of rabies virus RNA inside the viral nucleocapsid, rabies nucleoprotein was expressed in insect cells. In the cells, it binds to cellular RNA to form long, helical or short circular complexes, depending on the length of the bound RNA. The circular complexes contained from 9 up to 13 N-protomers per ring.

Crystal structure of the rabies virus nucleoprotein-RNA complex.

Negative-strand RNA viruses condense their genome into a helical nucleoprotein-RNA complex, the nucleocapsid, which is packed into virions and serves as a template for the RNA-dependent RNA polymerase complex. The crystal structure of a recombinant rabies virus nucleoprotein-RNA complex, organized in an undecameric ring, has been determined at 3.5 angstrom resolution.

The 12 A structure of trypsin-treated measles virus N-RNA.

Recombinant measles virus nucleoprotein (N) was produced in insect cells where it bound to cellular RNA to form helical N-RNA structures. These structures were observed by electron microscopy but were too flexible for high-resolution image analysis. Removal of the C-terminal tail of N by trypsin treatment resulted in structures that were much more rigid and seemed more regular.