A colorimetric IsoPCR for the rapid and sensitive visual detection of high-risk HPV16 in clinical samples with hydroxynaphthol blue.

HPV16 infection is found in more than 50 % of cervical cancer cases worldwide, triggering the development of numerous molecular techniques for viral diagnosis. The present study focuses on the development of a colorimetric IsoPCR for HPV16 DNA detection. The methodology combines the advantages of PCR and LAMP, while the most significant aspect of the new established methodology is the visual detection of amplification products through hydroxynapthol blue dye, thus minimizing the time and labor needed. An experimental cut-off value was tested through reconstitution experiments, while the specificity was evaluated by assessing clinical samples. The analytical sensitivity of the new colorimetric IsoPCR was found to be 0.1 viral DNA copy per reaction, while the specificity was 100 % for the detection of HPV16 DNA. The assay enabled the amplification of viral DNA in cases with viral load lower than 1 copy. In conclusion, the new established colorimetric IsoPCR can be regarded as an attractive molecular tool that facilitates the specific, rapid and highly sensitive visual detection of HPV16 DNA even at the very early stages of viral infection.

WarmStart colorimetric RT-LAMP for the rapid, sensitive and specific detection of Enteroviruses A-D targeting the 5'UTR region.

AIMS: The aim of the present study was to develop a colorimetric LAMP assay for the detection of enteroviruses belonging to species A-D targeting the 5' untranslated region (5' UTR) of enteroviruses genome. METHODS AND RESULTS: The RNA was converted to cDNA by the reverse transcriptase and then amplified via LAMP by the WarmStart®Bst DNA polymerase, simultaneously in a single reaction tube, so we shortened the reaction time to 50 min. The sensitivity of the assay regarding Enterovirus B, C and D was determined to be 0·30 CCID50 assay-1 while the sensitivity for Enterovirus A was 3·00 CCID50 assay-1 . The assay demonstrated high specificity and sensitivity for the detection of 45 reference strains of Enteroviruses A-D and validated on 20 clinical isolates. CONCLUSIONS: This assay can be used as a diagnostic tool for the rapid, sensitive and specific detection of enteroviruses, easily implemented in small clinical and research laboratories since LAMP amplicons were visualized by colour changes eliminating the requirement for post-amplification processing steps. SIGNIFICANCE AND IMPACT OF THE STUDY: We developed a colorimetric assay ideal for field situations for the detection of enteroviruses, by targeting the 5' UTR. This assay demonstrated high specificity and sensitivity, based on its performance on 45 EV A-D reference strains, on 20 EV B clinical isolates and on three non-enteroviral RNA viruses.

Development of a reverse transcription loop-mediated isothermal amplification assay (RT-LAMP) that detects enteroviruses by targeting the highly conserved 5'-UTR region.

Enteroviruses are positive sense single-stranded RNA viruses. Most infections from enteroviruses are asymptomatic and can circulate "silently", increasing the risk of an outbreak. For preventing such outbreaks, a rapid, cost-effective, and simple assay for the detection of enteroviruses is of great importance. In this study, we developed a rapid, simple, sensitive, and specific isothermal reverse transcription assay (RT-Loop-Mediated Amplification, RT-LAMP) for the detection of EV-A, B, C, and D species of enteroviruses, by targeting the highly conserved 5'UTR region. The assay was designed and validated based on reference sequences of the four species and on clinical and environmental isolates. The limit of detection of the assay is 0.75 CCID50/assay for Enterovirus A, B, and D and 0.075 CCID50/assay for Enterovirus C. LAMP allows immediate diagnosis in just 30-50 min, instead of a minimum of 120 min needed for PCR with an equal or better sensitivity. Moreover, due to its isothermal nature, there is no need for expensive equipment, thus decreasing the cost of each reaction. Therefore, this assay is ideal for use in resource-limited settings such as primary care facilities and environmental and clinical laboratories in developing countries.

WarmStart colorimetric LAMP for the specific and rapid detection of HPV16 and HPV18 DNA.

BACKGROUND AND OBJECTIVES: Persistent infection with High-Risk HPV genotypes is the principal cause for the development of cervical cancer with HPV16 and HPV18 to be the most frequently identified HPV genotypes observed in approximately 70% of cervical cancer cases worldwide. The present study focused on the development of a simple molecular methodology based on WarmStart colorimetric LAMP for the specific identification of HPV16 and HPV18. METHODS: The method was developed by designing LAMP type-specific primer sets that target the E6 gene. The assay was applied using HPV-positive clinical samples along with control cases in order to evaluate the specificity of the newly designed isothermal protocol. In addition, an experimental cutoff value was estimated through reconstitution experiments with HPV-DNA plasmids. LAMP amplicons were visualized by color changes, thus eliminating the requirement for post-amplification processing steps. RESULTS: The WarmStart colorimetric LAMP facilitates the isothermal amplification of 10 copies per reaction of both HPV16 and HPV18 DNA, while it exhibits 100% specificity for the detection of the corresponding genotypes in LSIL and HSIL cases. Moreover, the assay demonstrates 100% PPV and 100% NPV. Finally, the sensitivity of conventional PCR with the type-specific LAMP primer sets (B3/F3) for the HPV16, HPV18 DNA detection was 100 copies/reaction and 10 copies/reaction, respectively. CONCLUSIONS: The newly established WarmStart colorimetric LAMP can be considered as a powerful molecular tool that it can be easily implemented in small clinical and research laboratories for a rapid and efficient identification of the most tumorigenic HPV genotypes.

Α 2-stage, nested-like nucleic acid amplification method (IsoPCR) for the highly sensitive detection of HPV16 and HPV18 DNA.

Molecular detection of HPV DNA is considered as the gold standard for the diagnosis of cervical disease. Although the molecular assays for the identification of HPV16 and HPV18 have helped identify cervical cancer incidents, they are restricted to specialized laboratories. Thus, we developed a novel 2-stage, nested-like nucleic acid amplification method, named IsoPCR, to amplify the E6 gene of HPV16 and HPV18 with high analytical sensitivity and specificity. The performance of IsoPCR was compared to that of conventional PCR and LAMP. The analytical sensitivity of IsoPCR (1 copy/test) was 10-fold higher than conventional PCR and 25-fold higher than conventional LAMP. IsoPCR displayed significant amplification specificity (100%) and efficiency, as well. In conclusion, IsoPCR is a highly sensitive and specific diagnostic tool and it is suitable for the detection of low copy number of viral DNA in clinical specimens, providing critical information to healthcare providers.

Polymorphic variability in the exon 19 of the RB1 gene and its flanking intronic sequences in HPV16-associated precancerous lesions in the Greek population.

PURPOSE: The tumour suppressor protein RB plays a decisive role in negative control of the cell cycle, inhibiting tumour development. The present analysis investigated the prevalence of the nucleotide polymorphism A153104G, which is located at intron 18 of the RB1 gene, and investigated the impact of the polymorphic variability in the exon 19 and its flanking intronic sequences on the severity of cervical disease in HPV16-positive Greek women. METHODOLOGY: The nucleotide polymorphism A153104G was detected by PCR-RFLP assay, while the amplicons were further subjected to cloning and sequencing. Moreover, molecular evolutionary analysis was performed using the maximum-likelihood (ML) and empirical Bayesian (EB) methods in order to evaluate the selective pressure acting on exon 19 of the RB1 gene.Results/Key findings. The A153104G nucleotide polymorphism was only detected in one control case. Moreover, sequence analysis of the amplicons revealed that the polymorphic variability in the RB1 gene increased with the severity of the cervical dysplasia. The link between the observed polymorphic variability and the progress of cervical disease was reflected in the molecular evolutionary analysis that was performed on the exon 19 of the RB1 gene, since negative selective pressure was acting upon exon 19 in the control and low-grade squamous intraepithelial lesion (LSIL) cervical samples, while positive selective pressure was acting upon exon 19 in the high-grade squamous intraepithelial lesion (HSIL) specimens. CONCLUSIONS: The A153104G nucleotide polymorphism did not emerge as a potential biomarker for the development of precancerous lesions in the Greek patients, while the accumulation of sequence variations in RB1 gene might influence patients' susceptibility towards the progression of cervical neoplasia.

Detection of negative and positive RNA strand of poliovirus Sabin 1 and echovirus E19 by a stem-loop reverse transcription PCR.

In this report a strand specific RT-PCR was established for the detection of the replicative negative RNA strand of poliovirus sabin 1 (Sabin1) and Echovirus 19 (E19) strains. The key for the successful conduction of the assay was the use of a specific reverse transcription primer targeting the 5'-UTR of enteroviruses that consisted of a stem-loop structure at the 5'-end and an enteroviral-specific sequence at the 3'-end. The stem loop RT-PCR was found to be an accurate and sensitive method, detecting even 10-2 CCID50 of poliovirus sabin 1 (Sabin1) and E19 strains 6 h postinfection (p.i.), while CPE appeared 3 days later. This assay was also validated in SiHa and Caski cell lines that are not used for the detection of enteroviruses. The negative RNA strand was detected 6 h and 12 h p.i. in SiHa and Caski cells, when these cell lines were inoculated with 105 and 1 CCID50 respectively, whereas CPE was observed 5 days p.i for SiHa cells and 8 days p.i for Caski cells and that only at 105 CCID50 . The results show that this approach may be used for replacing the time-consuming cell cultures in order to detect the active replication of enteroviruses. SIGNIFICANCE AND IMPACT OF THE STUDY: Enteroviruses are positive stranded RNA viruses that may cause severe diseases. The conventional method for detection of active viral replication involves virus isolation in sensitive cell cultures followed by titration and seroneutralization. In this report, we describe the use of a stem-loop secondary structured oligonucleotide in RT-PCR assay for the detection of the replicative negative strand of the positive-stranded RNA of poliovirus sabin 1 and E19 strains. This approach proved to be a useful tool that may be used for replacing the time-consuming cell culture assays in order to detect the active replication of enteroviruses.

Development of a multiplex RT-PCR assay for the identification of recombination types at different genomic regions of vaccine-derived polioviruses.

Polioviruses (PVs) are the causal agents of acute paralytic poliomyelitis. Since the 1960s, poliomyelitis has been effectively controlled by the use of two vaccines containing all three serotypes of PVs, the inactivated poliovirus vaccine and the live attenuated oral poliovirus vaccine (OPV). Despite the success of OPV in polio eradication programme, a significant disadvantage was revealed: the emergence of vaccine-associated paralytic poliomyelitis (VAPP). VAPP is the result of accumulated mutations and putative recombination events located at the genome of attenuated vaccine Sabin strains. In the present study, ten Sabin isolates derived from OPV vaccinees and environmental samples were studied in order to identify recombination types located from VP1 to 3D genomic regions of virus genome. The experimental procedure that was followed was virus RNA extraction, reverse transcription to convert the virus genome into cDNA, PCR and multiplex-PCR using specific designed primers able to localize and identify each recombination following agarose gel electrophoresis. This multiplex RT-PCR assay allows for the immediate detection and identification of multiple recombination types located at the viral genome of OPV derivatives. After the eradication of wild PVs, the remaining sources of poliovirus infection worldwide would be the OPV derivatives. As a consequence, the immediate detection and molecular characterization of recombinant derivatives are important to avoid epidemics due to the circulation of neurovirulent viral strains.

Identification of rearranged sequences of HPV16 DNA in precancerous and cervical cancer cases.

Integration of HPV16 DNA into the host chromosome is considered to be a crucial step towards genomic instability and cervical cancer development. Aim of the present study was to investigate the presence of HPV16 rearranged intra-viral sequences in HPV16-positive normal, precancerous and cervical cancer samples using the method of Restriction Site-PCR (RS-PCR). Sequence analysis of HPV16 integrants revealed for the first time in clinical samples two distinct rearranged intra-viral sequences, concerning the conjunction of E2 and L1 genes and the conjunction of E1 and L1 genes with inverted orientation. Furthermore mapping analysis of the E1 and E2 genes in cervical samples with rearranged intra-viral sequences of HPV16 genome was conducted in order to determine the integrity of viral genes. The identification of intra-viral rearrangements provides valuable information regarding the HPV16 DNA integration, and may be a significant biomarker for the presence of chromosomal instability and DNA damages in clinical samples.

Sites of disruption within E1 and E2 genes of HPV16 and association with cervical dysplasia.

Integration of HPV16 DNA into the host chromosome usually disrupts the E1 and/or E2 genes. The present study investigated the disruption of E1, E2 genes in a total of eighty four HPV16-positive precancerous and cervical cancer specimens derived from Greek women (seventeen paraffin-embedded cervical biopsies and sixty seven Thin Prep samples). Complete E2 and E1 genes were amplified using three and nine overlapping primer sets respectively, in order to define the sites of disruption. Extensive mapping analysis revealed that disruption/deletion events within E2 gene occurred in high grade and cervical cancer samples (x(2) test, P < 0.01), while no evidence of E2 gene disruption was documented among low grade cervical intraepithelial neoplasias. In addition, disruptions within the E1 gene occur both in high and low grade cervical intraepithelial neoplasia. This leads to the assumption that in low grade cervical intraepithelial neoplasias only E1 gene disruption was involved (Fisher's exact test, P < 0.05), while in high grade malignancies and cervical cancer cases deletions in both E1 and E2 genes occurred. Furthermore, the most prevalent site of disruption of E1 gene was located between nucleotides 1059 and 1323, while the most prevalent deleted region of the E2 gene was located between nucleotides 3172 and 3649 (E2 hinge region). Therefore, it is proposed that each population has its own profile of frequencies and sites of disruptions and extensive mapping analysis of E1 and E2 genes is mandatory in order to determine suitable markers for HPV16 DNA integration analysis in distinct populations.

Duplex Real-time PCR assay and SYBR green I melting curve analysis for molecular identification of HPV genotypes 16, 18, 31, 35, 51 and 66.

Long-term infection with high-risk HPV genotypes is the leading cause of cervical cancer. In the present study a Duplex Real-time PCR assay was developed in order to identify HPV types 16, 18, 31, 35, 51 and 66 in three reactions, through SYBR green I melting curve analysis. The method utilizes type-specific primer sets that allowed the amplification of highly conserved regions of L1 gene. Reconstitution experiments were conducted by using HPV DNA plasmids in order to determine the sensitivity of the assay. The newly designed assay has a limit of detection of 10 copies per reaction. The most prevalent HPV genotype in single and in multiple HPV infections was HPV16 followed by HPV18, HPV51, HPV31, HPV35 and HPV66. The proposed method is a simple, specific, sensitive and cost-effective assay that can be easily incorporated in small and medium size laboratories for the rapid identification of the most clinically important HPV genotypes.

Multiplex PCR assay for the rapid identification of human papillomavirus genotypes 16, 18, 45, 35, 66, 33, 51, 58, and 31 in clinical samples.

The causal association between persistent human papillomavirus (HPV) infection and cervical cancer has lead to the development of a variety of molecular assays for HPV detection. The present study focused on the development of a simple, sensitive and cost-effective HPV genotyping method based on multiplex PCR methodology that could be easily performed in small laboratories. Three multiplex PCR assays were developed to identify the HPV genotypes 16, 18, 45, 35, 66, 33, 51, 58, and 31 together with an internal control. The method was established by designing nine type-specific primer sets that target conserved regions of the L1 gene. The assay was applied using HPV-positive cervical specimens, and cloning and sequencing of all of the amplicons that were generated were performed to examine the specificity of the newly designed primers. Moreover, an experimental cutoff value was determined through reconstitution experiments using HPV DNA plasmids. Amplicons of expected size were obtained, while cloning and sequencing of PCR products confirmed the genomic specificity of the amplicons. The sensitivity of this method was determined to be 10 copies of each individual HPV genotype per test. Multiple and single HPV infections were documented in 42.2 % and 57.8 % of cervical specimens, respectively. The most prevalent HPV genotype was HPV16, followed by HPV18, HPV66 and HPV51. The present multiplex PCR assay is a simple method with high specificity and sensitivity that can be applied in clinical or epidemiological analyses for rapid identification of the most clinically important HPV genotypes present in cervical intraepithelial neoplasias.

Characterization of novel intergenogroup and intergenotype recombinant noroviruses from central Greece.

Noroviruses (NoVs) are a major causative agent of acute gastroenteritis in humans. They are members of the Caliciviridae family and based on the genetic analysis of the RdRp and capsid regions, human NoVs are divided into three genogroups (Gs), GI, GII, and GIV. The three genogroups further segregate into distinct lineages called genotypes. 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 this study, three Noroviral strains detected in clinical samples revealed two hitherto unobserved recombination events between GII.9/GII.4 and GII.9/GI.7 genogroups. To our knowledge, these intergenotype and intergenogroup recombination events of GII.9/GII.4 and GII.9/GI.7, in ORF1 and ORF2 genes respectively are reported for the first time and highlight the ongoing evolution of noroviruses.

Prevalence of HPV16 E1-137463nt variants in Greek women.

Recent studies have focused on sequence variation of the HPV16 E1 gene. The present study investigates the prevalence of E1-1374^63nt duplication in the Greek population, and the sequence variation at the 5' end of the E1 and E6 genes from samples that harbored this genetic alteration. Fifty HPV16 positive cervical samples, derived from Greek patients were investigated. The 5' end of the E1 gene was amplified through PCR and the variant amplicons were cloned, sequenced, and bioinformatically analyzed for selective pressure. The E1-1374^63nt duplication was identified in 24% of the examined samples, with the same prevalence in both high and low-grade cervical malignancies. The E1-1374^63nt duplication was linked to the European variant lineage (x² = 5.076, P < 0.024) and it was significantly associated with the nucleotide variation A1053C (x² = 23.102, P < 0.0001). Molecular evolution analyses anticipate that the E1-1374^63nt duplication induces functional constraints on the 5' end of E1 gene, and it is proposed that this duplication might not affect negatively the function or structure of the E1 protein. The E1-1374^63nt duplication is prevalent in the Greek population, whereas the A1053C variation might constitute a significant marker for the characterization of the E1-1374^63nt variant in the Greek population, thus providing significant information about viral pathogenicity.

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.

Nucleotide polymorphisms of the human papillomavirus 16 E1 gene.

The E1 ORF is one of the most conserved regions in the human papillomavirus (HPV) genome. The complete E1 gene of the HPV16 genome was amplified with four overlapping primer sets in 16 high-grade (CIN II, III) and 13 low-grade cervical (CIN I) intraepithelial neoplasias as well as in one cervical cancer case. Sequence analysis of the E6 and E7 genes was also carried out in the same cervical samples in order to confirm the association between nucleotide sequence variations in the HPV16 E1 ORF and HPV16 variant lineages. Analysis of the E1 ORF revealed 27 nucleotide changes, and these changes were correlated with those found in HPV16 Asian American and African type II variants. Of these nucleotide variations, A1668G, G2073A, T2169C, T2189C, A2453T, C2454T, A2587T and G2650A were identified only in high-grade dysplasia cases. A phylogenetic tree of the E1 ORF and nucleotide sequence analysis of the E1, E6 and E7 genes revealed that intratypic nucleotide sequence polymorphisms located in the E1 ORF can be used to identify the major phylogenetic branch to which a HPV16 genome belongs. Moreover, amplification of the E1 ORF revealed a disruption between nucleotides 878 and 1523 in five high- and two low-grade cervical cases, indicating that integration of HPV DNA occurs at an early stage of viral infection.

Circulation of intergenotype recombinant noroviruses GII.9/GII.6 from 2006 to 2011 in central Greece.

Noroviruses (NoVs) are members of the Caliciviridae family and are recognized as a worldwide cause of acute nonbacterial gastroenteritis. Based on the genetic analysis of the RdRp and capsid regions, human NoVs are divided into three genogroups (Gs), GI, GII, and GIV, which further segregate into distinct lineages called genotypes. In this study, in an attempt to discern the circulation of an intergenotypic recombinant GII.9/GII.6, which was previously reported by our group in central Greece, we investigated NoVs in raw sewages from 2006 to 2011 and compared the results with the viruses detected from clinical samples in the same area and in the same time period. Two specific primer pairs for NoVs were designed which amplified in a single PCR fragment from polymerase to capsid gene covering the widespread recombination point in ORF1/ORF2 junction. Based on the genetic analysis, recombinant NoV strains GII.9/GII.6 were identified. Fourteen out of 15 environmental and eight out of ten clinical samples that were used in the present study were positive, with both primer pairs, confirming that the intergenotypic recombinant GII.9/GII.6 was circulating in the population of central Greece from 2006 to 2011. The crossover point was identified to be within the overlapping region of ORF1/ORF2 (GII.9/GII.6, respectively) and was determined by Simplot at nucleotide position 5,032 bp.

Molecular and evolutionary analysis of HPV16 E6 and E7 genes in Greek women.

Human papillomavirus type 16 (HPV16) non-European variants have been associated with persistent infection and cervical cancer development, while the L83V variant of the E6 gene has been correlated with the progression of cervical malignancy. The present study investigated the presence of the HPV16 L83V variant in Greek women. Molecular evolutionary analysis of the HPV16 E6 and E7 oncogenes was conducted in order to estimate the evolution of the HPV16 genome in the Greek population. The E6 L83V variant was found in 78.2 % of high- and 64.28 % of low-grade specimens. Moreover, the prototype and E6 L83V variants were both prevalent in high- and low-grade malignancies in Greek women. Selective pressure analysis of the individual amino acid residues of HPV16 sequences from the Greek population indicates that codon 83 of the E6 protein, as well as codon 85 of the E7 protein, are undergoing positive selection. Novel sequence variations were recorded within the E6 and E7 genes in cervical samples, characterized as (T350G) European variants. However, no signal of intratypic recombination event was identified within the E6-E7 region. Molecular and evolutionary analyses of HPV16 genomes from distinct geographical locations might provide valuable information about viral evolution and oncogenecity.

Identification of novel E6-E7 sequence variants of human papillomavirus 16.

The rate of evolution of the human papillomavirus 16 (HPV16) genome is low. However, the ability of the E6 oncoprotein to interact with distinct p53 variants causes selective pressure on the E6 gene. In addition, intratypic recombination events in the HPV16 E6 and E7 genes have been characterized as extraordinary phenomena during the evolutionary history of virus. In the present study, we identified two new sequence variants through nucleotide analysis of the E6-E7 region of the HPV16 genome. Maximum-likelihood and empirical Bayesian methods were used in order to identify positive selection at particular residues of the E6 and E7 genes. Using the single recombination breakpoint (SBP) method, we found evidence of recombination events in the E6 ORF. Nucleotide sequence analysis showed that the new sequence variants are phylogenetically distant from the other members of the population. Our results indicate that new evolutionary intermediates of HPV16 might be formed either though positive selective pressure or through recombination events by multiple infections with distinct HPV16 variants.