Highly heterogeneous temperature sensitivity of 2009 pandemic influenza A(H1N1) viral isolates, northern France.

We assayed the temperature sensitivity of 2009 pandemic influenza A(H1N1) viral isolates (n=23) and seasonal influenza A(H1N1) viruses (n=18) isolated in northern France in 2007/08 and 2008/09. All isolates replicated with a similar efficiency at 34 °C and 37 °C, and with a lower efficiency at 40 °C. The pandemic viral isolates showed a stronger heterogeneity in their ability to grow at the highest temperature, as compared with the seasonal isolates. No statistically significant difference in temperature sensitivity was observed between the pandemic viral isolates from severe and mild cases of influenza. Our data point to the impact of temperature sensitivity on the genetic evolution and diversification of the pandemic influenza A(H1N1) virus since its introduction into the human population in April 2009, and call for close surveillance of this phenotypic marker related to host and tissue tropism.

[Genetic evolution of poliovirus: success and difficulties in the eradication of paralytic poliomyelitis]. / Evolution génétique du poliovirus: succès et difficultés de l'éradication de la poliomyélite paralytique.

Poliovirus, the aetiological agent of poliomyelitis, is an enterovirus of the Picronaviridae family. Despite the success of the World Health Organisation (WHO) worldwide vaccination campaign against poliomyelitis, poliovirus remains a public health problem in several developing countries, in Africa and Asia in particular. This is partly due to the considerable capacity of poliovirus strains to circulate and spread in populations with insufficient vaccine coverage. In addition, the attenuated strains of the oral polio vaccine (OPV) may rapidly evolve a neurovirulent phenotype, causing rare cases of paralytic poliomyelitis. The recent occurrence of epidemics associated with vaccine-derived poliovirus (VDPV) has highlighted the emergence of recombinant strains with genomes constituted of sequences from OPV strains together with sequences from non-polio enteroviruses. In this review, after briefly describing the molecular biology of poliovirus and the pathogenesis of poliomyelitis, we will provide an overview of the current situation concerning poliomyelitis prophylaxis and the strategies developed to fight this disease. We will also deal with the issue of the possible re-emergence of poliovirus after declaration of the eradication of wildtype poliovirus.

[Poliovirus and apoptosis]. / Poliovirus et apoptose.

Poliovirus is the causal agent of paralytic poliomyelitis. Flaccid paralysis characteritic of poliomyelitis result from the destruction of motor neurons, the specific target cells of poliovirus in the central nervous system (CNS). The development of new animal and cell models has allowed the key steps of the pathogenesis of poliomyelitis to be investigated at the molecular level. In particular, it has been shown that poliovirus-induced apoptosis is an important component of the tissue injury in the CNS of infected mice that leads to paralysis. In this review, the molecular biology of poliovirus and the pathogenesis of poliomyelitis will be briefly described, and then several models of poliovirus-induced apoptosis will be considered ; the role of the cellular receptor of poliovirus, CD155, in the modulation of apoptosis will also be addressed.

Poliovirus, pathogenesis of poliomyelitis, and apoptosis.

Poliovirus (PV) is the causal agent of paralytic poliomyelitis, an acute disease of the central nervous system (CNS) resulting in flaccid paralysis. The development of new animal and cell models has allowed the key steps of the pathogenesis of poliomyelitis to be investigated at the molecular level. In particular, it has been shown that PV-induced apoptosis is an important component of the tissue injury in the CNS of infected mice, which leads to paralysis. In this review the molecular biology of PV and the pathogenesis of poliomyelitis are briefly described, and then several models of PV-induced apoptosis are considered; the role of the cellular receptor of PV, CD155, in the modulation of apoptosis is also addressed.

Inhibition of poliovirus RNA synthesis as a molecular mechanism contributing to viral persistence in the mouse central nervous system.

Many survivors of poliomyelitis, several decades after the acute phase of the disease, develop a set of new muscle symptoms called post-polio syndrome. The persistence of poliovirus (PV) in the central nervous system (CNS) may be involved in the aetiology of this syndrome. By using a mouse model, we have shown that PV persists in the CNS of paralysed mice for over a year after the acute disease. Detection of PV plus- and minus-strand RNAs in the spinal cord of paralysed mice suggested continuous PV RNA replication in the CNS. However, infectious PV particles could not be recovered from homogenates of CNS from paralysed mice beyond 20 days post-paralysis, indicating that PV replication was restricted. In an attempt to identify the molecular mechanism by which PV replication was limited, PV plus- and minus-strand RNA levels were estimated in the CNS of persistently infected mice by a semi-quantitative RT-nested PCR method. Results revealed that RNA replication was inhibited at the level of plus-strand RNA synthesis during persistent infection. Similar results were obtained in neuroblastoma IMR-32 cell cultures persistently infected with PV Restriction of PV RNA synthesis could be involved in persistence by limiting PV replication.

Poliovirus persistence in human cells in vitro.

Poliovirus (PV) can persist in vivo in the intestine of immunocompromised hosts for years. Moreover, immunocompetent individuals who have survived paralytic poliomyelitis sometimes develop the post-poliomyelitis syndrome (PPS), consisting of a variety of symptoms including new muscular atrophies. PPS may be due to PV persistence. We have developed models of PV persistence in neural cells and epidermoid cells. Cell determinants are of crucial importance for the establishment of persistent infections in human neuronal cells, whereas viral determinants play the primary role in human epidermoid HEp-2 cells. The results obtained with these in vitro models show the capacity of PV to persist and reveal a virus and cell co-evolution involving PV-receptor interactions. In addition, they suggest that several mechanisms are used by PV to establish and maintain persistent infections.

Expression of mutated poliovirus receptors in human neuroblastoma cells persistently infected with poliovirus.

Poliovirus (PV) is able to establish persistent infections in human neuroblastoma IMR-32 cells [Colbère-Garapin et al. (1989) Proc. Natl. Acad. Sci. USA 86, 7590]. During persistent infection, PV mutants are selected that display substitutions of residues in regions of the capsid known to interact with the PV receptor (PVR), a glycoprotein of the immunoglobulin superfamily. The mechanism of persistent infection in IMR-32 cells may therefore involve the selection of mutant PVRs. To test this hypothesis, the sequences of the PVR mRNAs in uninfected IMR-32 cells and in two independent IMR-32 cell cultures persistently infected with the Mahoney strain of PV type 1 (PV1/Mahoney) were determined. The PVR mRNA population of uninfected cells was homogeneous, and no mutation was repeatedly found, whereas that of persistently infected cells displayed missense mutations. Particular mutations were repeatedly detected, and all of them mapped to the N-terminal domain of PVR (domain 1), which interacts directly with PV. These mutations generated several types of PVR variants with the following substitutions: Ala67-->Thr alone, Ala67-->Thr associated with Gly39-->Ser, and Arg104-->Gln. Functional analysis of PVR in murine LM cells, stably expressing each of the PVR forms, showed that the PVR forms selected during persistent infection conferred on LM cells partial resistance to PV1/Mahoney-induced lysis. Although adsorption onto PVR seemed to be independent of the PVR form, an analysis of the conformational changes of the capsid during the early steps of the PV cycle provided evidence that the Ser39/Thr67 and Gln104 substitutions almost halved the conversion of 160S infectious particles into 135S A particles associated with the PV-PVR interaction. Altogether, these findings indicate that during persistent infection, specific mutations were selected in the domain 1 of PVR and that these mutations increased the resistance of cells to PV-induced lysis. These results are discussed in view of the position of the mutations on PVR.

An approach to understanding the mechanisms of poliovirus persistence in infected cells of neural or non-neural origin.

BACKGROUND: Poliovirus (PV) is the etiologic agent of paralytic poliomyelitis, which is sometimes followed, after decades of clinical stability, by new symptoms, including progressive muscular atrophy, collectively known as the post-polio syndrome. This raises the question of possible PV persistence in post polio patients. OBJECTIVE: To test the capacity of PV to establish persistent infections in human cells, three models were developed. STUDY DESIGN: This review focuses on the viral and cellular parameters involved in persistent PV infection. RESULTS: Many PV strains, which are generally lytic in primate cell lines, are able to establish persistent infections in human neuroblastoma cells. During persistent infection, PV mutants (PVpi) are consistently selected, and several of their capsid substitutions occur at positions known to be involved in PV-PV receptor interactions. PVpi have a particular property: they can establish persistent infections in non-neural HEp-2 cells. PV can also persistently infect primary cultures of human fetal brain cells and the majority of cells which survive infection belong to the neuronal lineage. CONCLUSIONS: The results obtained with the three models of persistent PV infection in human cells suggest that several mechanisms are used by PV to establish and maintain persistent infections in neural and non-neural cells. The interactions of the virus with its receptor seem to be a key-step in all cases. In the future, the elucidation of the etiology of the post-polio syndrome will require the characterization of PV sequences having persisted for decades in post-polio patients.

Molecular aspects of poliovirus biology with a special focus on the interactions with nerve cells.

Poliovirus (PV), the pathogenic agent of paralytic poliomyelitis, is the prototype of the picornavirus family. Although paralytic poliomyelitis has been nearly totally eradicated in most industrialized countries, PV continues to be an important public health problem in many developing countries. Moreover, in industrialized countries, two current concerns are the occurrence, albeit at a very low frequency, of vaccine-associated paralytic poliomyelitis, due to the genetic instability of the attenuated oral PV strains in vaccines, and the emergence of a neuro-muscular pathology in many survivors of the acute disease, called the post-polio syndrome. PV has been targeted by the World Health Organization for world-wide eradication in the coming decade and continues to be the subject of intensive research. The advances made in the molecular biology of PV, taken together with the development of new animal and cell models, have permitted a new look at a key step in the pathogenesis of poliomyelitis, i.e. the interactions between PV and nerve cells. These aspects of PV biology are developed in this review according to three themes: (i) the PV host range; (ii) the molecular determinants of PV neurovirulence and attenuation; and (iii) the persistence of PV in nerve cells, which has proven to be an interesting new domain in the field of PV research.

One amino acid change on the capsid surface of poliovirus sabin 1 allows the establishment of persistent infections in HEp-2c cell cultures.

Poliovirus mutants (PVpi) selected during the persistent infection of human neuroblastoma cells can establish secondary persistent infections in nonneural HEp-2c cells (I. Pelletier, T. Couderc, S. Borzakian, E. Wyckoff, R. Crainic, E. Ehrenfeld, and F. Colbère-Garapin, 1991, Virology, 180, 729-737). Previous results from our laboratory have also shown that, in the genome of PVpi S11 derived from the Sabin 1 strain, the genomic region involved in this phenotype contains 11 missense mutations which map exclusively to the genes encoding the capsid proteins VP1 and VP2. We report here the identification of precise viral determinants able to confer the capacity to establish persistent infections in HEp-2c cell cultures to the lytic Sabin 1 strain. We used a strategy based on the observation that PVpi, after a few months of persistent infection in HEp-2c cells, tend to regain a more lytic phenotype in uninfected HEp-2c cell cultures. We constructed mutant viruses carrying only a few mutations potentially involved in the phenotype of persistence. Two mutations were identified, one corresponding to the substitution His>Tyr of amino acid 142 of VP2 and another corresponding to the substitution Val>Ile of amino acid 160 of VP1. Mutants carrying one or the other of the two determinants established persistent infections in HEp-2c cell cultures in about 20% of the infections. Higher frequencies were obtained with the mutant carrying both determinants (30%), and with PVpi S11 (63%), indicating that the effects of several determinants can be cumulative. The two determinants are localized on the capsid surface in a region known to be involved in the interactions between poliovirus and its cell receptor and in fact, we demonstrate here that in the case of the two persistent mutants, these interactions are modified.

Two amino acid substitutions in the type 3 poliovirus capsid contribute to the establishment of persistent infection in HEp-2c cells by modifying virus-receptor interactions.

After 2.5 months of persistent infection in human neuroblastoma cells by the type 3 poliovirus (PV3) wild-type Leon strain, a mutant (PVpi), L2-2, capable of establishing a persistent infection in nonneural HEp-2c cells was isolated. Sequence analysis of the viral capsid protein genes revealed the presence of seven missense mutations, three of which were also present in a second PVpi, suggesting that they could be important determinants of the persistent phenotype. When the three mutations were introduced into the lytic Leon strain separately, in pairs or all together, all but one of the viruses was capable of establishing a persistent infection. However, aside from the triple mutant, only one mutant virus, bearing a Leu at position VP213 in the capsid interior and an Asn at position VP1290 on the capsid surface, was capable of establishing persistent infections in more than 30% of the cultures. When present together, these two determinants affect the early steps of the virus cycle including cell binding and the receptor-mediated conformational changes believed to be necessary for viral penetration and uncoating. In fact, this persistent double mutant appears to undergo a novel capsid transition when in contact with the human PV receptor, altering from the native virion which sediments at 160S to a form which sediments at about 147S. We propose that this modification could be the mechanism by which PV3 is able to establish persistent infections in HEp-2c cell cultures.

Molecular mechanisms of poliovirus persistence: key role of capsid determinants during the establishment phase.

As viral persistence is of major medical importance, well-characterized, simple models are needed to improve our understanding of persistent infections. We have chosen to study the molecular mechanisms of viral persistence with the poliovirus (PV), because this picornavirus is one of the best characterized animal viruses, it infects the central nervous system which is a target organ for viral persistence, and it belongs to the Picornaviridae family of viruses, which includes several naturally persisting viruses. We have developed models of PV persistence in neuronal and epidermoid cells, and the present review will focus on the latter one because both lytic and persistent PV strains can be used to study the PV-HEp-2 cell interactions. The viral determinants of persistence have been investigated with this model, and PV determinants have proven to be of crucial importance for the establishment of persistence in HEp-2 cells. Precise determinants of PV persistence have been identified for PV serotypes 1 and 3, in capsid proteins VP1 and VP2. These determinants modify the early steps of the PV cycle, and in particular, the conformational modifications of the capsid following virus adsorption onto its receptor. These results permit us to propose several hypotheses concerning PV persistence and the early steps of the PV cycle.

In vitro sensitization of the B16 murine melanoma cells to ganciclovir by different RNA and plasmid DNA constructions encoding HSVtk.

The antiviral drug ganciclovir (GCV) is toxic for mammalian cells transfected with the herpes simplex virus thymidine kinase (HSVtk) gene. To improve the results obtained by our group previously on nonviral transfection of tumor cells, we have examined here in vitro virus-free transfection of murine B16 melanoma cells via lipofectamine-nucleic acid complexes carrying either HSVtk gene transcripts or plasmid DNAs containing single and double copies of the HSVtk gene. The HSVtk gene transcripts as well as plasmids containing the HSVtk gene(s) rendered cells sensitive to GCV treatment. Tumor sensitivity to GCV conferred by the HSVtk gene transcripts was of the same level as the sensitivity conferred by plasmid DNAs containing a single copy of the HSVtk gene. However, when the plasmids containing double copies of the HSVtk gene were used, sensitivity to low GCV concentrations increased dramatically. One could appreciate this finding as an essential advantage of the plasmids containing double copies of the HSVtk gene since it allows use of the GCV concentration range which is common in clinical applications.

Persistent poliovirus infection of human fetal brain cells.

It has been suggested that poliovirus (PV), the causative agent of poliomyelitis, could persist in surviving patients. We have previously shown that PV can persistently infect some human cell lines in vitro, particularly neuroblastoma cell lines. We report here an ex vivo model in which PV can persistently infect primary cultures of human fetal brain cells. Two mutations involving capsid residues 142 of VP2 and 95 of VP1 were repeatedly selected during the persistent infections. These residues are located in capsid regions known to be involved in interactions between PV and its receptor. During the first week after infection, viral antigens were found in cells of both the neuronal and glial lineages. In contrast, 2 weeks after infection, viral antigens were detected almost exclusively in cells of the neuronal lineage. They were detected predominantly in cells expressing a marker of early commitment to the neuronal lineage, MAP-5, particularly in neuroblasts. Viral antigens were also found in immature progenitors expressing a neuroepithelium marker, nestin, and in cells expressing a marker of postmitotic neurons, MAP-2. The presence of viral antigens in postmitotic neurons suggests that PV can persist in neurons of patients who have survived poliomyelitis.

Virus-free transfer of the herpes simplex virus thymidine kinase gene followed by ganciclovir treatment induces tumor cell death.

We report virus-free transfer of a "suicide" gene into tumoral cells. The system can be used in vitro or in vivo to induce tumor cell death. A plasmid carrying the herpes simplex virus thymidine kinase (HSV-TK) gene with its 5'- and 3'-flanking regions was used both alone and in liposomes to transduce B16 cells. In vitro, a 5-day treatment with ganciclovir after transfection with the HSV-TK gene in liposomes induced a significant lysis of B16 melanoma cells as assessed by the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide test. The efficacy of transfection was determined using liposomes harboring the beta-galactosidase reporter gene and was around 10%. Thus, the cytotoxicity observed resulted presumably from a large bystander effect. In vivo, direct transfer of the TK DNA into established B16 melanoma tumors in C57B6 mice followed by i.p. ganciclovir treatment induced a 50% reduction of tumor weight after 8 days and an increased necrosis. Despite the use of the nonspecific strong TK promoter, no necrosis was detected in normal tissues surrounding the tumor or elsewhere. Thus, this system of tumor transfection, which does not involve any viral vector, is safe and straightforward and seems to be suitable for testing in clinical trials.

Cell clones cured of persistent poliovirus infection display selective permissivity to the wild-type poliovirus strain Mahoney and partial resistance to the attenuated Sabin 1 strain and Mahoney mutants.

We report the isolation and characterization of HEp-2c cell clones obtained after two successive persistent poliovirus (PV) infections. Once cured, some of the cell clones displayed selective permissivity toward the wild-type Mahoney strain and partial resistance to particular mutants of this strain, including the Sabin 1 strain. Two cell clones, CI 4 and CI 10, were studied in greater detail. The cytopathic effects of Mahoney infection were comparable in the cell clones and in HEp-2c cells. The cytopathic effects of infection by Sabin 1 or Mahoney mutants were greatly delayed in CI 4 and CI 10. In the genomic region encoding the capsid proteins, determinants involved in the resistance of the cell clones to the Mahoney mutants were localized in the amino-terminal part of VP1 (amino acids 22 and 43), the B-C loop of VP1 (amino acids 94-102), and the loop of VP3 connecting its amino-terminal to beta strand B (amino acid 60). These genomic regions are thought to be involved in the early steps of viral infection. Virus adsorption was slower and less efficient on CI 10 cells than on parental HEp-2c cells. Virus adsorption was faster on CI 4 than on HEp-2c cells, and at least as efficient, but there was less receptor-induced structural modification of the capsid, a step that is required for decapsidation. Furthermore, infection of CI 4 by a Mahoney mutant in which the B-C loop of VP1 has been deleted was affected in the later steps of infection. These results indicate that, in cells cured of persistent PV infection, poliovirus multiplication was restricted at several stages and particularly at two steps of virus entry: adsorption and/or the uncoating transitions following adsorption onto the receptor.

Substitutions in the capsids of poliovirus mutants selected in human neuroblastoma cells confer on the Mahoney type 1 strain a phenotype neurovirulent in mice.

Poliovirus (PV) type 1 mutants selected in human neuroblastoma cells persistently infected (PVpi) with the wild-type Mahoney strain exhibited a mouse-neurovirulent phenotype. Four of the five substitutions present in the capsid proteins of a PVpi were demonstrated to extend the host range of the Mahoney strain to mice. These new mouse-neurovirulent determinants were located in the three-dimensional structure of the viral capsid; two of them (residues 142 of VP2 and 60 of VP3) were located in loops exposed at the surface of the protein shell, whereas the other two (residues 43 of VP1 and 62 of VP4) were located on the inside of the capsid. VP1 residue 43 and VP2 residue 142 substitutions were also selected in a PVpi derived from the attenuated Sabin strain. We suggest that the selective pressure of human neuroblastoma cell factor(s) involved in early steps of PV multiplication could be responsible for the arising of amino acid substitutions which confer adaptation to the mouse central nervous system to PV.

Identification of a region of the poliovirus genome involved in persistent infection of HEp-2 cells.

Poliovirus mutants were selected during the persistent infection of human neuroblastoma cells. These viruses could establish secondary persistent infections in HEp-2 nonneural cells. We report the identification of a region of the genome of a persistent virus (S11) that was sufficient to confer to a recombinant virus the phenotype that causes persistent infection in HEp-2 cells. This region, between nucleotides 1148 and 3481, contained 11 missense mutations mapping exclusively in the genes of capsid proteins VP1 and VP2. Because recombinant viruses carrying only one of these two mutated genes were not able to cause persistent infection, it seems very probable that two or more mutations in these genes are required for expression of the phenotype that causes persistent infection.

Precise missense and silent point mutations are fixed in the genomes of poliovirus mutants from persistently infected cells.

Poliovirus mutants selected in persistently infected human neuroblastoma cells have a modified cell tropism and can establish a secondary persistent infection in nonneural cells, such as HEp-2c cells. Nucleotide sequence analysis revealed that the genome of a persistent mutant, S11, differed from that of the parental lytic Sabin 1 poliovirus strain by 31 point mutations. Three mutations occurred in the noncoding regions. The other mutations resulted in 12 amino acid substitutions; 1 substitution occurred in a nonstructural protein (3A), while the other 11 substitutions were clustered in the capsid proteins VP2 and VP1. The same missense mutations, as well as many of the silent mutations that we observed in mutant S11, also accumulated in the genome of two other persistent viruses isolated from independent infections. This finding indicates that both missense and silent mutations are selected during the persistent infection of neuroblastoma cells and suggests that the secondary structure of RNA in the coding region may play a role in viral infection.