Vaia Pliaka

Risks associated with the use of live-attenuated vaccine poliovirus strains and the strategies for control and eradication of paralytic poliomyelitis

The Global Polio Eradication Initiative was launched in 1988 with the aim to eliminate paralytic poliomyelitis. Two effective vaccines are available: inactivated polio vaccine (IPV) and oral polio vaccine (OPV). Since 1964, OPV has been used instead of IPV in most countries due to several economic and biological advantages. However, in rare cases, the live-attenuated Sabin strains of OPV revert to neurovirulence and cause vaccine-associated paralytic poliomyelitis in vaccinees or lead to emergence of vaccine-derived poliovirus strains. Attenuating mutations and recombination events have been associated with the reversion of vaccine strains to neurovirulence. The substitution of OPV with an improved new-generation IPV and the availability of new specific drugs against polioviruses are considered as future strategies for outbreak control and the eradication of paralytic poliomyelitis worldwide.

Retrospective Characterization of a Vaccine-Derived Poliovirus Type 1 Isolate from Sewage in Greece

ABSTRACT Retrospective molecular and phenotypic characterization of a vaccine-derived poliovirus (VDPV) type 1 isolate (7/b/97) isolated from sewage in Athens, Greece, in 1997 is reported. VP1 sequencing of this isolate revealed 1.87% divergence from the VP1 region of reference strain Sabin 1, while further genomic characterization of isolate 7/b/97 revealed a recombination event in the nonstructural part of the genome between a vaccine strain and a nonvaccine strain probably belonging to Enterovirus species C. Amino acid substitutions commonly found in previous studies were identified in the capsid coding region of the isolate, while most of the attenuation and temperature sensitivity determinants were reverted. The ultimate source of isolate 7/b/97 is unknown. The recovery of such a highly divergent derivative of a vaccine strain emphasizes the need for urgent implementation of environmental surveillance as a supportive procedure in the polio surveillance system even in countries with high rates of OPV coverage in order to prevent cases or even outbreaks of poliomyelitis that otherwise would be inevitable.

Recombination among human non-polio enteroviruses: implications for epidemiology and evolution

Human enteroviruses (EV) belong to the Picornaviridae family and are among the most common viruses infecting humans. They consist of up to 100 immunologically and genetically distinct types: polioviruses, coxsackieviruses A and B, echoviruses, and the more recently characterized 43 EV types. Frequent recombinations and mutations in enteroviruses have been recognized as the main mechanisms for the observed high rate of evolution, thus enabling them to rapidly respond and adapt to new environmental challenges. The first signs of genetic exchanges between enteroviruses came from polioviruses many years ago, and since then recombination has been recognized, along with mutations, as the main cause for reversion of vaccine strains to neurovirulence. More recently, non-polio enteroviruses became the focus of many studies, where recombination was recognized as a frequent event and was correlated with the appearance of new enterovirus lineages and types. The accumulation of multiple inter- and intra-typic recombination events could also explain the series of successive emergences and disappearances of specific enterovirus types that could in turn explain the epidemic profile of circulation of several types. This review focuses on recombination among human non-polio enteroviruses from all four species (EV-A, EV-B, EV-C, and EV-D) and discusses the recombination effects on enterovirus epidemiology and evolution.

Molecular identification and full genome analysis of an echovirus 7 strain isolated from the environment in Greece

Two enteroviruses from river water and four from sewage treatment plant were isolated in Larissa, Greece, that all shared the same sequence. A full genome analysis was conducted in an attempt to reveal the evolutionary pathways of one of the isolated strains (LR11F7). VP1 nucleotide and phylogenetic analysis revealed that the isolated strain had 78% homology with the echovirus 7 prototype strain Wallace. Full genome analysis revealed that LR11F7 P1 region is related to echoviruses 7 and that P2 and P3 regions are originating from contemporary enteroviruses isolated in South Asia. Two recombination events were shown to be involved into the evolutionary history of LR11F7, the one event concerning 3A, 3B, and 2C, and the other concerning 3D genomic region, both with new types of HEV-B. The contribution of recombination to enterovirus evolution is substantial, giving rise to new genetic lineages with unknown properties.

Correlation between recombination junctions and RNA secondary structure elements in poliovirus Sabin strains

In order to test the hypothesis that RNA structural elements promote the distribution of certain types of recombination junctions in each one of the 2C and 3D poliovirus genomic regions (Sabin 3/Sabin 2 or Sabin 1 in 2C and Sabin 2/Sabin 1 or Sabin 3 in 3D), we searched in 2C and 3D regions of reference Sabin strains for high probability RNA structural elements that could promote recombination. Recombination junctions that were identified in clinical strains of this study, as well as in clinical strains of previous studies, were superimposed on RNA secondary structure models of 2C and 3D genomic regions. Furthermore, we created an in vitro model, based on double infection of cell-culture with two poliovirus strains, for the production and identification of recombinant Sabin strains in 2C and 3D regions. Our intention was to compare the results that refer to the correlation of recombination junctions and RNA secondary structures in 2C and 3D regions of clinical strains, with the respective results of the in vitro model. Most of the recombination junctions of the clinical strains were correlated with RNA secondary structure elements, which were identical between recombining Sabin strains, and also presented high predictive value. In consensus were, the respective results originated from the in vitro model. We propose that the distribution of specific types of recombination junctions in certain regions of Sabin strains is not fortuitous and is correlated with RNA secondary structure elements identical to both recombination partners. Furthermore, results of this study highlight an important role for the stem region of the RNA structure elements in promoting recombination.

Full-Genome Sequence Analysis of a Multirecombinant Echovirus 3 Strain Isolated from Sewage in Greece

ABSTRACT An echovirus 3 (Echo3) strain (strain LR31G7) was isolated from a sewage treatment plant in Greece in 2005. Full-genome molecular, phylogenetic, and SimPlot analyses were conducted in order to reveal the evolutionary pathways of the isolate. Nucleotide and phylogenetic analyses of part of the VP1 genomic region revealed that the isolated strain correlates with Echo3 strains isolated during the same year in France and Japan, implying that the same virus circulated in Europe and Asia. LR31G7 was found to be a recombinant that shares the 3′ part of its genome with an Echo25 strain isolated from asymptomatic infants in Norway in 2003. Nucleotide and SimPlot analyses of the VP1-2A junction, where the recombination was located, revealed the exact recombination breakpoint (nucleotides 3357 to 3364). Moreover, there is evidence that recombination events had occurred in 3B-3D region in the evolutionary history of the isolate. Our study indicates that recombination events play major roles in enterovirus evolution and that the circulation of multirecombinant strains with unknown properties could be potentially dangerous for public health.

Molecular characterization of a new intergenotype Norovirus GII recombinant.

Human noroviruses (NoVs) of the Caliciviridae family are a major cause of epidemic gastroenteritis. The NoV genus is genetically diverse and recombination of viral RNA is known to depend upon various immunological and intracellular constraints that may allow the emergence of viable recombinants. In the present study, we report the development of a broadly reactive RT-PCR assay, which allowed the characterization of strain A6 at molecular level, established its genetic relationship at the sub-genogroup level and classified A6 strain at the sub-genotype level. The detection was carried out initially by enzyme-linked immunosorbent assay (ELISA) and the subsequent detection and molecular characterization of NoV strain was achieved by reverse transcription-PCR and sequencing. Based on the sequence analysis, A6 strain was revealed to belong to the GII genogroup of NoVs. Partial ORF1 gene sequencing analysis and complete ORF2 gene sequencing revealed that ORF1 and ORF2 belonged to two distinct genotypes GII/9 and GII/6, respectively, making obvious that A6 strain is a rare intergenotypic recombinant within the genogroup GII between GII.9 and GII.6 genotypes. A6 strain represents the first human NoV from Greece, whose genome has been partially (ORF1&ORF3) and completed (ORF2) sequenced. To our knowledge the recombination event GII.9/GII.6 in RdRp and capsid gene, respectively, that was revealed in the present study is reported for the first time.

Sequence variation analysis of the E2 gene of human papilloma virus type 16 in cervical lesions from women in Greece

The E2 gene of human papilloma virus is expressed at the early stage of the viral life cycle, encoding the E2 transcription factor, and regulates the expression of E6 and E7 oncogenes. Disruption of E2 gene due to viral integration inhibits the transcriptional suppression of the HPV oncogenes, inducing cell proliferation. In the present study, a total of 22 HPV16-positive cytological specimens derived from high- and low-grade cervical intraepithelial lesions were investigated in order to identify sequence variations in the HPV16 E2 ORF. The E2 gene was amplified by PCR using external and internal overlapping sets of primers. Amplicons were cloned and sequenced. Disruption sites were detected in cervical samples diagnosed as high-grade cervical intraepithelial lesions. Moreover, sequence variations were identified in the E2 ORF and specific variations were associated with non-European variants such as African type I, African type II and Asian American. A total of three new sequence variations were identified at positions 2791, 2823 (transactivation domain) and 3361 (hinge region). Distinct phylogenetic branches were formed according to E2 analysis that characterized the different HPV16 variants. It was ascertained that non-European variants are circulating in the Greek population.

Complete nucleotide sequence analysis of the VP1 genomic region of Echoviruses 6 isolated from sewage in Greece revealed 98% similarity with Echoviruses 6 that were characterized from an aseptic meningitis outbreak 1 year later

The molecular characterization of two enterovirus strains (LR51A5 and LR61G3) isolated from the sewage treatment plant unit in Larissa, Greece, in May and June 2006 and the investigation of their relationship with enteroviruses of the same serotype isolated in Greece in 2001 and 2007 were performed by complete VP1 sequence analysis of the isolates. The close phylogenetic relationship and the high nucleotide similarity (98%) led to the conclusion that the virus isolated from sewage in 2006 was associated with that isolated from an aseptic meningitis outbreak 1 year later. Bootscan analysis of the VP1 genomic region revealed that intraserotypic multi-recombination events might have been involved in the evolutionary past history of the LR51A5 and LR61G3 isolates.

Genome analysis of two type 6 echovirus (E6) strains recovered from sewage specimens in Greece in 2006.

Echovirus 6 (E6) is one of the main enteroviral serotypes that was isolated from cases of aseptic meningitis and encephalitis during the last years in Greece. Two E6 (LR51A5 and LR61G3) were isolated from the sewage treatment plant unit in Larissa, Greece, in May 2006, 1 year before their characterization from aseptic meningitis cases. The two isolates were initially found to be intra-serotypic recombinants in the genomic region VP1, a finding that initiated a full genome sequence analysis. In the present study, nucleotide, amino acid, and phylogenetic analyses for all genomic regions were conducted. For the detection of recombination events, Simplot and bootscan analyses were carried out. The continuous phylogenetic relationship in 2C–3D genomic region of strains LR51A5 and LR61G3 with E30 isolated in France in 2002–2005 indicated that the two strains were recombinants. SimPlot and Bootscan analyses confirmed that LR51A5 and LR61G3 carry an inter-serotypic recombination in the 2C genomic region. The present study provide evidence that recombination events occurred in the regions VP1 (intraserotypic) and non-capsid (interserotypic) during the evolution of LR51A5 and LR61G3, supporting the statement that the genomes of circulating enteroviruses are a mosaic of genomic regions of viral strains of the same or different serotypes. In conclusion, full genome sequence analysis of circulating enteroviral strains is a prerequisite to understand the complexity of enterovirus evolution.