Annette Martin

Engineering a poliovirus type 2 antigenic site on a type 1 capsid results in a chimaeric virus which is neurovirulent for mice

Poliovirus type 2 (PV‐2) Lansing strain produces a fatal paralytic disease in mice after intracerebral injection, whereas poliovirus type 1 (PV‐1) Mahoney strain causes disease only in primates. Atomic models derived from the three‐dimensional crystal structure of the PV‐1 Mahoney strain have been used to locate three antigenic sites on the surface of the virion. We report here the construction of type 1‐type 2 chimaeric polioviruses in which antigenic site 1 from the PV‐1 Mahoney strain was substituted by that of the PV‐2 Lansing strain by nucleotide cassette exchange in a cloned PV‐1 cDNA molecule. These chimaeras proved to have mosaic capsids with composite type 1 and type 2 antigenicity, and induced a neutralizing response against both PV‐1 and PV‐2 when injected into rabbits. Moreover, a six‐amino‐acid change in PV‐1 antigenic site 1 was shown to be responsible for a remarkable host‐range mutation in so far as one of the two type 1‐type 2 chimaera was highly neurovirulent for mice.

Three-dimensional structure of a mouse-adapted type 2/type 1 poliovirus chimera

The crystal structure of V510, a chimeric type 2/type 1 poliovirus, has been determined at 2.6 A resolution. Unlike the parental Mahoney strain of type 1 poliovirus, V510 is able to replicate in the mouse central nervous system, due entirely to the replacement of six amino acids in the exposed BC loop of capsid protein VP1. Significant structural differences between the two strains cluster in a major antigenic site of the virus, located at the apex of the radial projection which surrounds the viral five‐fold axis. Residues implicated in the mouse‐virulence of poliovirus by genetic studies are located in this area, and include the residues which are responsible for stabilizing the conformation of the BC loop in V510. Despite evidence that this area is not involved in receptor binding in cultured primate cells, the genetic and structural observations suggest that this area plays a critical role in receptor interactions in the mouse central nervous system. These results provide a structural framework for further investigation of the molecular determinants of host and tissue tropism in viruses.

Analysis of Deletion Mutants Indicates that the 2A Polypeptide of Hepatitis A Virus Participates in Virion Morphogenesis

ABSTRACT Unlike all other picornaviruses, the primary cleavage of the hepatitis A virus (HAV) polyprotein occurs at the 2A/2B junction and is carried out by the only proteinase encoded by the virus, 3Cpro. The resulting P1-2A capsid protein precursor is subsequently cleaved by 3Cpro to generate VP0, VP3, and VP1-2A, which associate as pentamers. An unidentified cellular proteinase acting at the VP1/2A junction releases the mature capsid protein VP1 from VP1-2A later in the morphogenesis process. Although these aspects of polyprotein processing are well characterized, the function of 2A is unknown. To study its role in the viral life cycle, we assessed the infectivity of synthetic, genome-length RNAs containing 11 different in-frame deletions in the 2A region. Deletions in the N-terminal 40% of 2A abolished infectivity, whereas deletions in the C-terminal 60% resulted in viruses with a small-focus replication phenotype. C-terminal deletions in 2A had no effect on RNA replication kinetics under one-step growth conditions, nor did they have an effect on capsid protein synthesis and 3Cpro-mediated processing. However, C-terminal deletions in 2A altered the VP1/2A cleavage, resulting in accumulation of uncleaved VP1-2A precursor in virions and possibly accounting for a delay in the appearance of infectious particles with these mutants, as well as a fourfold decrease in specific infectivity of the virus particles. When the capsid proteins were expressed from recombinant vaccinia viruses, the N-terminal part of 2A was required for efficient cleavage of the P1-2A precursor by 3Cpro and assembly of structural precursors into pentamers. These data indicate that the N-terminal domain of 2A must be present as a C-terminal extension of P1 for folding of the capsid protein precursor to allow efficient 3Cpro-mediated cleavages and to promote pentamer assembly, after which cleavage at the VP1/2A junction releases the mature VP1 protein, a process that appears to be necessary to produce highly infectious particles.

Construction of a chimaeric type 1/type 2 poliovirus by genetic recombination

A chimaeric poliovirus carrying a type-2-specific neutralization epitope on a type 1 capsid was created by site-directed mutagenesis of the Mahoney strain of poliovirus type 1. An EcoRV and a HindIII restriction sites were first constructed in the cDNA of poliovirus type 1 at nucleotide positions 2756 and 2786, respectively, i.e. on either side of the sequence encoding neutralization epitope C3 (VP1 amino acids 93-103), which is part of neutralization site NImI. The cDNA sequence framed by the two sites was next taken out and replaced by custom-made oligonucleotides encoding the equivalent region of VP1 from the Lansing strain of poliovirus type 2. The DNA from the plasmid carrying such a hybrid construct was transfected onto CV1 cells generating a chimaeric virus, v510. Neutralization of v510 with a panel of monoclonal antibodies showed that v510 has lost the poliovirus type 1 C3 epitope but acquired a new, poliovirus type-2-specific neutralization epitope. Preliminary results indicate that v510 also shows neurovirulence for mice, which is a specific trait of the Lansing strain of poliovirus type 2.

Differential regulation of the Wnt/β-catenin pathway by hepatitis C virus recombinants expressing core from various genotypes

Clinical studies have suggested association of some hepatitis C virus (HCV) subtypes or isolates with progression toward hepatocellular carcinoma (HCC). HCV core protein has been reported to interfere with host Wnt/β-catenin pathway, a cell fate-determining pathway, which plays a major role in HCC. Here, we investigated the impact of HCV core genetic variability in the dysregulation of Wnt/β-catenin pathway. We used both transient expression of core proteins from clinical isolates of HCV subtypes 1a (Cambodia), 4a (Romania) and 4f (Cameroon) and infection systems based on a set of engineered intergenotypic recombinant viruses encoding core from these various clinical strains. We found that TCF transcription factor-dependent reporter activity was upregulated by core in a strain-specific manner. We documented core sequence-specific transcriptional upregulation of several β-catenin downstream target genes associated with cell proliferation and malignant transformation, fibrogenesis or fat accumulation. The extent of β-catenin nuclear translocation varied in accordance with β-catenin downstream gene upregulation in infected cells. Pairwise comparisons of subgenotypic core recombinants and mutated core variants unveiled the critical role of core residues 64 and 71 in these dysregulations. In conclusion, this work identified natural core polymorphisms involved in HCV strain-specific activation of Wnt/β-catenin pathway in relevant infection systems.