Modeling of signaling pathways in chondrocytes based on phosphoproteomic and cytokine release data.

OBJECTIVE: Chondrocyte signaling is widely identified as a key component in cartilage homeostasis. Dysregulations of the signaling processes in chondrocytes often result in degenerative diseases of the tissue. Traditionally, the literature has focused on the study of major players in chondrocyte signaling, but without considering the cross-talks between them. In this paper, we systematically interrogate the signal transduction pathways in chondrocytes, on both the phosphoproteomic and cytokine release levels. METHODS: The signaling pathways downstream 78 receptors of interest are interrogated. On the phosphoproteomic level, 17 key phosphoproteins are measured upon stimulation with single treatments of 78 ligands. On the cytokine release level, 55 cytokines are measured in the supernatant upon stimulation with the same treatments. Using an Integer Linear Programming (ILP) formulation, the proteomic data is combined with a priori knowledge of proteins' connectivity to construct a mechanistic model, predictive of signal transduction in chondrocytes. RESULTS: We were able to validate previous findings regarding major players of cartilage homeostasis and inflammation (e.g., IL1B, TNF, EGF, TGFA, INS, IGF1 and IL6). Moreover, we studied pro-inflammatory mediators (IL1B and TNF) together with pro-growth signals for investigating their role in chondrocytes hypertrophy and highlighted the role of underreported players such as Inhibin beta A (INHBA), Defensin beta 1 (DEFB1), CXCL1 and Flagellin, and uncovered the way they cross-react in the phosphoproteomic level. CONCLUSIONS: The analysis presented herein, leveraged high throughput proteomic data via an ILP formulation to gain new insight into chondrocytes signaling and the pathophysiology of degenerative diseases in articular cartilage.

PCR assays for the identification of rare recombination types from VP1 to 3D genomic region of vaccine derived poliovirus strains.

Poliomyelitis has been effectively controlled by the use of inactivated poliovirus vaccine (IPV) or trivalent live attenuated oral poliovirus vaccine (OPV). Since 1964, the use of OPV in mass vaccinations has resulted in drastic reductions of the number of poliomyelitis cases caused by wild-type polioviruses. However, the characterization of OPV derivatives with increased neurovirulence, constituted a real problem with respect to OPV safety. Mutations at attenuating sites of the genome and recombination events between Sabin strains of the trivalent OPV vaccine have been correlated with the loss of the attenuated phenotype of OPV strains and the acquisition of traits characteristic of wild polioviruses. In consequence, early detection and characterization of recombinant evolved derivatives of vaccine strains is highly important. In this report, ten PCR assays are described which allow for the identification of rare recombination events located in VP1, 2A, 2C, 3A, 3C and 3D genomic regions and predominant recombination events located in 2C and 3D genomic regions of OPV derivatives. These assays could be readily implemented in diagnostics laboratories lacking sequencing facilities as a first approach for the early detection and characterization of recombinant OPV derivatives.

Molecular and phylogenetic analysis of the HPV 16 E4 gene in cervical lesions from women in Greece.

The HPV16 E1(∧)E4 protein is thought to contribute to the release of newly formed viral particles from infected epithelia. In order to investigate amino acid mutations in the HPV16 E1(∧)E4 protein, the complete E4 ORF was amplified by PCR in 27 HPV16-positive cervical samples, and the amplicons were cloned. Fifteen nucleic acid variations were identified in the E4 ORF, including seven silent nucleic acid mutations. In addition, nine amino acid mutations (A7V, A7P, L16I, D45E, L59I, L59T, Q66P, S72F, H75Q) were detected in the E1(∧)E4 protein, and these were associated with the severity of cervical malignancy. A maximum-likelihood phylogenetic tree was constructed based on the E4 ORF, and nucleotide sequence analysis of the E4, E6 and E7 genes from the same samples was conducted in order to determine the phylogenetic origin of the cloned sequences from the amplified HPV16 E4. Based on the nucleotide sequence and phylogenetic analysis it was revealed that even though E4 ORF constitutes a small polymorphic portion of the viral genome (288 bp), it could provide valuable information about the origins of the HPV16 genome. In addition, molecular evolutionary analysis of the E4 coding region revealed that neutral selection is dominant in the overlapping region of the E4 and E2 ORFs.

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.

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.

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.

Retrospective molecular and phenotypic analysis of poliovirus vaccine strains isolated in Greece.

The live oral poliovirus vaccine (OPV) strains are genetically unstable, causing, in rare cases, vaccine-associated paralytic poliomyelitis. Reversions of the known attenuating mutations in OPV strains and intertypic recombination have been identified as the underlying causes of the increased neurovirulence of poliovirus isolates. In this study, three OPV isolates (one non-recombinant and two recombinants) were tested in order to correlate phenotypic traits such as temperature sensitivity (Rct test) and growth kinetics (one-step growth curve test) with mutations and recombination events of the viral genome. Moreover, the immunity level of the western Greek population aged 1-40 years was evaluated against OPV isolates and Sabin vaccine strains, with a microneutralization assay. Members of the 1-40-year age group (both pooled and individual sera) showed no significant differences in neutralization test (NT) titres against OPV isolates in comparison with the Sabin vaccine strains. However, all three OPV isolates showed reverted phenotypic traits in Rct or one-step growth curve assays. The results of our study revealed a significant decrease in immunity level from the 1-10-year age group to the 21-30-year age group (pooled sera) for both poliovirus types 1 and 3. For both poliovirus types, the highest NT titres were observed in the 1-10-year age group, and the lowest NT titre was observed in the 21-30-year age group, towards poliovirus type 3. Our study underlines the need for immunological studies in all age groups, in order to allow reconsideration of the current vaccination policies and to avoid epidemics caused by the circulation of highly evolved OPV derivatives.

Correlation of mutations and recombination with growth kinetics of poliovirus vaccine strains.

Attenuated strains of Sabin poliovirus vaccine replicate in the human gut and, in rare cases, may cause vaccine-associated paralytic poliomyelitis (VAPP). The genetic instability of Sabin strains constitutes one of the main causes of VAPP, a disease that is most frequently associated with type 3 and type 2 Sabin strains, and more rarely with type 1 Sabin strains. In the present study, the growth phenotype of eight oral poliovirus vaccine (OPV) isolates (two non-recombinants and six recombinants), as well as of Sabin vaccine strains, was evaluated using two different assays, the reproductive capacity at different temperatures (Rct) test and the one-step growth curve test in Hep-2 cells at two different temperatures (37°C and 40°C). The growth phenotype of isolates was correlated with genomic modifications in order to identify the determinants and mechanisms of reversion towards neurovirulence. All of the recombinant OPV isolates showed a thermoresistant phenotype in the Rct test. Moreover, both recombinant Sabin-3 isolates showed significantly higher viral yield than Sabin 3 vaccine strain at 37°C and 40°C in the one-step growth curve test. All of the OPV isolates displayed mutations at specific sites of the viral genome, which are associated with the attenuated and temperature-sensitive phenotype of Sabin strains. The results showed that both mutations and recombination events could affect the phenotype traits of Sabin derivatives and may lead to the reversion of vaccinal strains to neurovirulent ones. The use of phenotypic markers along with the genomic analysis may shed additional light on the molecular determinants of the reversed neurovirulent phenotype of Sabin derivatives.

A seroprevalence study of poliovirus antibody against a collection of recombinant and non-recombinant poliovirus vaccine strains in the population of southern Greece.

In this study, the serological status of the southern Greek population in the 1­10-year, 11­20-year, 21­30-year and 31­40-year age groups with regard to Sabin vaccine strains and a collection of 15 recombinant and four non-recombinant poliovirus vaccine strains was determined. For all three poliovirus types, the highest neutralization test (NT) titres were observed in the 1­10- year age group, indicating a good response to vaccination. In general, the serological status of the population of southern Greece with regard to poliovirus is better for types 1 and 2 than for type 3. The presence of the lowest NT titre in the 21­ 30-year age group against poliovirus type 3 suggests the need for a booster dose of monovalent Sabin3 vaccine to ensure personal and herd immunity.

A new RT-PCR assay for the identification of the predominant recombination types in 2C and 3D genomic regions of vaccine-derived poliovirus strains.

In the post-eradication era of wild polioviruses, the only remaining sources of poliovirus infection worldwide would be the vaccine-derived polioviruses (VDPVs). As the preponderance of countries certified to be polio-free has switched from OPV (oral poliovirus vaccine) to IPV (inactivated poliovirus vaccine), importation of recombinant evolved derivatives of vaccinal strains would have serious implication for public health. To test the robustness of the proposed RT-PCR screening analysis, eleven recombinant vaccine-derived polioviruses that were characterized previously by sequencing by our group, in addition to three recently identified recombinant environmental isolates were assayed. Although the most definitive characterization of VDPVs is by genomic sequencing, in this study we describe a new, inexpensive and broadly applicable RT-PCR assay for the identification of the predominant recombination types S3/Sx in 2C and S2/Sx in 3D genomic regions respectively of VDPVs, that can be readily implemented in laboratories lacking sequencing facilities as a first approach for the early detection of vaccine-derived poliovirus (VDPVs).

Use of mutational pattern in 5'-NCR and VP1 regions of polioviruses for molecular diagnosis.

Polioviruses are members of the enterovirus genus, belonging to the Picornaviridae family. They are the causative agents of poliomyelitis, a paralytic and sometimes fatal disease in humans. The number of poliomyelitis cases caused by wild poliovirus infections has been dramatically reduced by the extensive use of two available vaccines: the inactivated poliovirus vaccine (IPV) and the oral poliovirus vaccine (OPV). Despite the importance of OPV in the reduction of poliomyelitis cases, one of the disadvantages associated with this vaccine is the rare occurrence of vaccine-associated paralytic poliomyelitis (VAPP) in vaccinees or their healthy contacts through the accumulation of mutations and/or recombination in Sabin strains genome. Thirteen clinical isolates originating from healthy vaccinees and VAPP cases were investigated in order to identify genomic modifications in 5' non-coding region (5'-NCR) and VP1 genomic regions. The analysis of samples was conducted by RT-PCR, RFLP, sequencing and bioinformatics analysis. All clinical isolates were characterized as OPV-like viruses. Our results showed that analysis of 5'-NCR and VP1 regions of Poliovirus Sabin strains is important in order to identify mutations that increase the neurovirulence conducting to the eventuality of emergence of VAPP cases.