Andrei Fokine

Structure and inhibition of EV-D68, a virus that causes respiratory illness in children

Targeting EV-D68, a respiratory virus A recent outbreak of respiratory illness in U.S. children was caused by entorovirus D68 (EV-D68). Enteroviruses also include human pathogens such as human rhinovirus, which causes the common cold, and poliovirus. Most of these viruses are stabilized by a factor that binds in a hydrophobic pocket of the capsid protein VP1, and antiviral compounds can act by displacing this factor. Liu et al. report the crystal structure of EV-D68 and its complex with the antiviral compound peconaril. In EV-D68, the hydrophobic pocket contained a fatty acid that was displaced by peconaril. Peconaril efficiently inhibited EV-D68 infection of cells, making it a possible drug candidate against EV-D68. Science, this issue p. 71 A virus that causes respiratory illness in children can be inhibited by an anti-rhinovirus drug. Enterovirus D68 (EV-D68) is a member of Picornaviridae and is a causative agent of recent outbreaks of respiratory illness in children in the United States. We report here the crystal structures of EV-D68 and its complex with pleconaril, a capsid-binding compound that had been developed as an anti-rhinovirus drug. The hydrophobic drug-binding pocket in viral protein 1 contained density that is consistent with a fatty acid of about 10 carbon atoms. This density could be displaced by pleconaril. We also showed that pleconaril inhibits EV-D68 at a half-maximal effective concentration of 430 nanomolar and might, therefore, be a possible drug candidate to alleviate EV-D68 outbreaks.

Icosahedral bacteriophage ΦX174 forms a tail for DNA transport during infection

Prokaryotic viruses have evolved various mechanisms to transport their genomes across bacterial cell walls. Many bacteriophages use a tail to perform this function, whereas tail-less phages rely on host organelles. However, the tail-less, icosahedral, single-stranded DNA ΦX174-like coliphages do not fall into these well-defined infection processes. For these phages, DNA delivery requires a DNA pilot protein. Here we show that the ΦX174 pilot protein H oligomerizes to form a tube whose function is most probably to deliver the DNA genome across the host’s periplasmic space to the cytoplasm. The 2.4 Å resolution crystal structure of the in vitro assembled H protein’s central domain consists of a 170 Å-long α-helical barrel. The tube is constructed of ten α-helices with their amino termini arrayed in a right-handed super-helical coiled-coil and their carboxy termini arrayed in a left-handed super-helical coiled-coil. Genetic and biochemical studies demonstrate that the tube is essential for infectivity but does not affect in vivo virus assembly. Cryo-electron tomograms show that tubes span the periplasmic space and are present while the genome is being delivered into the host cell’s cytoplasm. Both ends of the H protein contain transmembrane domains, which anchor the assembled tubes into the inner and outer cell membranes. The central channel of the H-protein tube is lined with amide and guanidinium side chains. This may be a general property of viral DNA conduits and is likely to be critical for efficient genome translocation into the host.

Molecular architecture of tailed double-stranded DNA phages

The tailed double-stranded DNA bacteriophages, or Caudovirales, constitute ~96% of all the known phages. Although these phages come in a great variety of sizes and morphology, their virions are mainly constructed of similar molecular building blocks via similar assembly pathways. Here we review the structure of tailed double-stranded DNA bacteriophages at a molecular level, emphasizing the structural similarity and common evolutionary origin of proteins that constitute these virions.

A human antibody against Zika virus crosslinks the E protein to prevent infection.

The recent Zika virus (ZIKV) epidemic has been linked to unusual and severe clinical manifestations including microcephaly in fetuses of infected pregnant women and Guillian-Barré syndrome in adults. Neutralizing antibodies present a possible therapeutic approach to prevent and control ZIKV infection. Here we present a 6.2 Å resolution three-dimensional cryo-electron microscopy (cryoEM) structure of an infectious ZIKV (strain H/PF/2013, French Polynesia) in complex with the Fab fragment of a highly therapeutic and neutralizing human monoclonal antibody, ZIKV-117. The antibody had been shown to prevent fetal infection and demise in mice. The structure shows that ZIKV-117 Fabs cross-link the monomers within the surface E glycoprotein dimers as well as between neighbouring dimers, thus preventing the reorganization of E protein monomers into fusogenic trimers in the acidic environment of endosomes.

Structure of the bacteriophage phi KZ lytic transglycosylase gp144.

Lytic transglycosylases are enzymes that act on the peptidoglycan of bacterial cell walls. They cleave the glycosidic linkage between N-acetylmuramoyl and N-acetylglucosaminyl residues with the concomitant formation of a 1,6-anhydromuramoyl product. The x-ray structure of the lytic transglycosylase gp144 from the Pseudomonas bacteriophage φKZ has been determined to 2.5-Å resolution. This protein is probably employed by the bacteriophage in the late stage of the virus reproduction cycle to destroy the bacterial cell wall to release the phage progeny. φKZ gp144 is a 260-residue α-helical protein composed of a 70-residue N-terminal cell wall-binding domain and a C-terminal catalytic domain. The fold of the N-terminal domain is similar to the peptidoglycan-binding domain from Streptomyces albus G d-Ala-d-Ala carboxypeptidase and to the N-terminal prodomain of human metalloproteinases that act on extracellular matrices. The C-terminal catalytic domain of gp144 has a structural similarity to the catalytic domain of the transglycosylase Slt70 from Escherichia coli and to lysozymes. The gp144 catalytic domain has an elongated groove that can bind at least five sugar residues at sites A-E. As in other lysozymes, the peptidoglycan cleavage (catalyzed by Glu115 in gp144) occurs between sugar-binding subsites D and E. The x-ray structure of the φKZ transglycosylase complexed with the chitotetraose (N-acetylglucosamine)4 has been determined to 2.6-Å resolution. The N-acetylglucosamine residues of the chitotetraose bind in sites A-D.

Structure of the Three N-Terminal Immunoglobulin Domains of the Highly Immunogenic Outer Capsid Protein from a T4-Like Bacteriophage

ABSTRACT The head of bacteriophage T4 is decorated with 155 copies of the highly antigenic outer capsid protein (Hoc). One Hoc molecule binds near the center of each hexameric capsomer. Hoc is dispensable for capsid assembly and has been used to display pathogenic antigens on the surface of T4. Here we report the crystal structure of a protein containing the first three of four domains of Hoc from bacteriophage RB49, a close relative of T4. The structure shows an approximately linear arrangement of the protein domains. Each of these domains has an immunoglobulin-like fold, frequently found in cell attachment molecules. In addition, we report biochemical data suggesting that Hoc can bind to Escherichia coli, supporting the hypothesis that Hoc could attach the phage capsids to bacterial surfaces and perhaps also to other organisms. The capacity for such reversible adhesion probably provides survival advantages to the bacteriophage.

Functional Analysis of the Highly Antigenic Outer Capsid Protein, Hoc, a Virus Decoration Protein from T4-like Bacteriophages

Bacteriophage T4 is decorated with 155 copies of the highly antigenic outer capsid protein, Hoc. The Hoc molecule (40 kDa) is present at the centre of each hexameric capsomer and provides a good platform for surface display of pathogen antigens. Biochemical and modelling studies show that Hoc consists of a string of four domains, three immunoglobulin (Ig)‐like and one non‐Ig domain at the C‐terminus. Biochemical data suggest that the Hoc protein has two functional modules, a capsid binding module containing domains 1 and 4 and a solvent‐exposed module containing domains 2 and 3. This model is consistent with the dumbbell‐shaped cryo‐EM density of Hoc observed in the reconstruction of the T4 capsid. Mutagenesis localized the capsid binding site to the C‐terminal 25 amino acids, which are predicted to form two β‐strands flanking a capsid binding loop. Mutations in the loop residues, ESRNG, abolished capsid binding, suggesting that these residues might interact with the major capsid protein, gp23*. With the conserved capsid binding module forming a foothold on the virus and the solvent‐exposed module able to adapt to bind to a variety of surfaces, Hoc probably provides survival advantages to the phage, such as increasing the virus concentration near the host, efficient dispersion of the virus and exposing the tail for more efficient contact with the host cell surface prior to infection.

Role of bacteriophage T4 baseplate in regulating assembly and infection.

Significance This study examines how the high-energy, dome-shaped infectious form of the bacteriophage T4 baseplate assembles as opposed to how it assembles in the low-energy, star-shaped form that occurs after infection. Normal expectations would be that a molecular assembly occurs as a result of loss of energy. However, a virus has to be poised in a high-energy form to fight its way into a host. Our investigations of T4 have now shown how bacteriophage T4 can assemble into a high-energy form and how the structure of the components directs the sequential conformational changes that gain access to the host, an Escherichia coli bacterium. Bacteriophage T4 consists of a head for protecting its genome and a sheathed tail for inserting its genome into a host. The tail terminates with a multiprotein baseplate that changes its conformation from a “high-energy” dome-shaped to a “low-energy” star-shaped structure during infection. Although these two structures represent different minima in the total energy landscape of the baseplate assembly, as the dome-shaped structure readily changes to the star-shaped structure when the virus infects a host bacterium, the dome-shaped structure must have more energy than the star-shaped structure. Here we describe the electron microscopy structure of a 3.3-MDa in vitro-assembled star-shaped baseplate with a resolution of 3.8 Å. This structure, together with other genetic and structural data, shows why the high-energy baseplate is formed in the presence of the central hub and how the baseplate changes to the low-energy structure, via two steps during infection. Thus, the presence of the central hub is required to initiate the assembly of metastable, high-energy structures. If the high-energy structure is formed and stabilized faster than the low-energy structure, there will be insufficient components to assemble the low-energy structure.

Rubella virus capsid protein structure and its role in virus assembly and infection

Significance Rubella virus (RV) is a human pathogen that causes serious birth defects when contracted during pregnancy. However, due to its variable shape and size, little is known about the RV structure. The RV capsid protein is an essential component of the virus and a key factor for successful replication of the virus in host cells. Here we describe the atomic structure of the RV capsid protein. This structure, along with electron microscopic data on the virus, has provided a three-dimensional picture of the virion. The capsid protein structure has also helped to identify amino acid residues that are required for virus assembly. This information can be used for the development of antiviral therapies that target the viral capsid protein. Rubella virus (RV) is a leading cause of birth defects due to infectious agents. When contracted during pregnancy, RV infection leads to severe damage in fetuses. Despite its medical importance, compared with the related alphaviruses, very little is known about the structure of RV. The RV capsid protein is an essential structural component of virions as well as a key factor in virus–host interactions. Here we describe three crystal structures of the structural domain of the RV capsid protein. The polypeptide fold of the RV capsid protomer has not been observed previously. Combining the atomic structure of the RV capsid protein with the cryoelectron tomograms of RV particles established a low-resolution structure of the virion. Mutational studies based on this structure confirmed the role of amino acid residues in the capsid that function in the assembly of infectious virions.

From structure of the complex to understanding of the biology.

The most extensive structural information on viruses relates to apparently icosahedral virions and is based on X-ray crystallography and on cryo-electron microscopy single-particle reconstructions. This paper concerns itself with the study of the macromolecular complexes that constitute viruses, using structural hybrid techniques.