A reliable RT-PCR/RFLP assay for the molecular classification of enterovirus reference and wild type strains to either of the two genetic clusters on the basis of 5'-UTR

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 reverse transcription-loop-mediated isothermal amplification (RT-LAMP) system for a highly sensitive detection of enterovirus in the stool samples of acute flaccid paralysis cases

Background

In the global eradication program for poliomyelitis, the laboratory diagnosis plays a critical role by isolating poliovirus (PV) from the stool samples of acute flaccid paralysis (AFP) cases. In this study, we developed a reverse transcription-loop-mediated isothermal amplification (RT-LAMP) system for a rapid and highly sensitive detection of enterovirus including PV to identify stool samples positive for enterovirus including PV.

Methods

A primer set was designed for RT-LAMP to detect enterovirus preferably those with PV-like 5'NTRs of the viral genome. The sensitivity of RT-LAMP system was evaluated with prototype strains of enterovirus. Detection of enterovirus from stool extracts was examined by using RT-LAMP system.

Results

We detected at least 400 copies of the viral genomes of PV(Sabin) strains within 90 min by RT-LAMP with the primer set. This RT-LAMP system showed a preference for Human enterovirus species C (HEV-C) strains including PV, but exhibited less sensitivity to the prototype strains of HEV-A and HEV-B (detection limits of 7,400 to 28,000 copies). Stool extracts, from which PV, HEV-C, or HEV-A was isolated in the cell culture system, were mostly positive by RT-LAMP method (positive rates of 15/16 (= 94%), 13/14 (= 93%), and 4/4 (= 100%), respectively). The positive rate of this RT-LAMP system for stool extracts from which HEV-B was isolated was lower than that of HEV-C (positive rate of 11/21 (= 52%)). In the stool samples, which were negative for enterovirus isolation by the cell culture system, we found that two samples were positive for RT-LAMP (positive rates of 2/38 (= 5.3%)). In these samples, enterovirus 96 was identified by sequence analysis utilizing a seminested PCR system.

Conclusions

RT-LAMP system developed in this study showed a high sensitivity comparable to that of the cell culture system for the detection of PV, HEV-A, and HEV-C, but less sensitivity to HEV-B. This RT-LAMP system would be useful for the direct detection of enterovirus from the stool extracts.

Direct extraction and molecular characterization of enteroviruses genomes from human faecal samples

Routine diagnosis of acute flaccid paralysis (AFP) is still based on classical virological procedures. Several enteroviruses serotypes are not easily isolated in cell cultures system used and routinely more than one passage in cell culture is performed. A total of 54 archived faecal samples were examined. The heterogeneous nature of faecal samples may contribute to variations in the yields of viral nucleic acids with different extraction methods and specimen types. PCR inhibitors are frequently encountered in stool specimens. From the three methods initially compared for extraction of viral RNA, QIAamp Viral RNA Mini Kit was retained as it yielded the highest amount of viral RNA without the interference of RT-PCR inhibitors. Evaluation of 54 archived stool specimens by RT-PCR and cell culture resulted in a higher frequency of detection by RT-PCR. With the use of RT-PCR we were able to detect two additional samples otherwise considered negative for enterovirus isolation if only the cell culture standard methodology was employed. RNA extraction with QIAamp Viral RNA Mini Kit coupled with RT-PCR in the 5'NCR (subgrouping into distinct genetic clusters of all enteroviruses) and VP1 (reliable serotyping by sequencing) is a rapid and sensitive technique of direct poliovirus/non-polio enteroviruses recovery and molecular characterization from human faecal specimens without further passage in cell culture, which may select for genetic variants that may not accurately reflect the virus composition in the original specimen.

Basic rationale, current methods and future directions for molecular typing of human enterovirus

Enterovirus is a genus of the Picornaviridae family including more than 80 serotypes belonging to four species designed Human enterovirus A to D. The antigens of the structural proteins support the subdivision of enteroviruses into multiple serotypes. Comparative phylogeny based on molecular typing methods has been of great help to classify former and new types of enterovirus, and to investigate the diversity of enteroviruses and the evolutionary mechanisms involved in their diversity. By now, molecular typing methods of enterovirus rely mainly on the sequencing of an amplicon targeting a variable part of the region coding for the capsid proteins (VP1 and, alternatively, VP2 or VP4), either from a strain recovered by cell culture or, more recently, by direct amplification of a clinical or environmental specimen. In the future, microarrays are thought to play a major role in enterovirus typing and in the analysis of the determinants of virulence that support the puzzling diversity of the pathological conditions associated with human infection by these viruses.

Nucleotide analysis and phylogenetic study of the homology boundaries of coxsackie A and B viruses

Modern molecular methods use VP1 coding region as a target for RT-PCR assays followed by sequencing, in order to identify new untyped enteroviruses' strains. In the present study, two different genomic portions of VP1 and the full length of 2A coding region of 53 clinical isolates, mostly belonging to HEV-B species, were amplified and sequenced. Nucleotide analysis of the produced sequences revealed that the values that define an unknown strains serotype vary according to the serotype and the specific part of VP1, which is investigated. The correlation, however, with the serotype was affirmed in both VP1 portions that were studied, as well as in the first 20 bases of 2A region. In the rest of 2A, no correlation with the serotype and disruption of monophyly was observed. Phylogenetic analysis of the same sequences confirmed, in most cases, the results of the nucleotide analysis.

Classification and Structure of Echovirus 5′-UTR Sequences

Enteroviruses are classified into two genetic clusters on the basis of 5'-UTR and all echoviruses (ECV) are classified together with coxsackie B viruses (CBV), coxsackie A viruses (CAV) types 2-10, 12, 14 and 16, and enteroviruses (EV) 68, 69, 71 and 73. During the present study, 5'-UTR-derived sequences constituting the largest part of the Internal Ribosome Entry Site (IRES) of ECVs were studied with respect to their possible secondary structures, which were predicted following the phenomenon of "covariance", i.e. the existence of evolutionary pressure in favour of structural conservation in the light of nucleotide sequence variability. In this and previous studies, no correlation between overall 5'-UTR identity and the currently recognised Human Enterovirus species was found, implying that notwithstanding their divergent protein-encoding regions, these species are free to exchange 5'-UTRs by recombination. Secondary structure features which are known to be highly conserved amongst enteroviruses and specifically the GNRA tetraloop in secondary structure domain IV, involved in long-term tertiary interactions and loop B in secondary structure domain V with an as yet unknown function were also conserved in ECVs. In contrast, the C(NANCCA)G motif, which is considered to be important in virus transcription and translation, was not conserved in all ECVs and sequence patterns observed in other enterovirus groups and rhinoviruses were recorded.

Echovirus 30, Jiangsu Province, China

An outbreak of aseptic meningitis occurred in the northern area of Jiangsu Province in China from January to July in 2003. A total of 1,681 cases were involved in this outbreak, and 99% of patients were <15 years of age. To identify the etiologic agent, 66 cerebrospinal fluid specimens were tested by cell culture. Eighteen showed an enteroviruslike cytopathic effect on MRC-5 human fetal diploid lung cells. An enterovirus primer-mediated reverse transcriptase-polymerase chain reaction, a standard neutralization assay, and sequencing of the complete capsid-encoding (VP1) gene identified the 18 isolates (FDJS03) as echovirus 30. At least a 10% difference was seen in nucleotide sequences of VP1 between FDJS03 isolates and other global strains of echovirus 30. Phylogenetic analysis based on complete sequences of VP1 was performed to further characterize the FDJS03 isolates. This report is the first to identify a distinct lineage of echovirus 30 as a probable cause of this outbreak.

Membrane adsorption with direct cell culture combined with reverse transcription-PCR as a fast method for identifying enteroviruses from sewage

We present a new approach for the detection and identification of enteroviruses concentrated and isolated from sewage. Samples were collected from two study sites located at Nicosia and Limassol sewage treatment plants in Cyprus. Viruses were adsorbed to cellulose nitrate membrane filters, cultured directly from the membrane filters by using the VIRADEN method, and identified by reverse transcription-PCR, followed by 5' untranslated region (5'-UTR) restriction fragment length polymorphism (RFLP) analysis and partial sequencing of the VP1 protein coding region. Initial subgrouping based on the HpaII restriction profile showed that all of the isolates except one belonged to the same genetic subcluster. Partial VP1 sequencing revealed that most isolates belonged to serotypes coxsackie B4 (42.5%) and coxsackie Alpha9 (30%), whereas coxsackie B2 (17.5%) and coxsackie B1 (3%) isolates were less frequently observed. One poliovirus type 2 isolate (2.5%) of vaccine origin was also found. The HpaII digests predicted the genetic subcluster for all isolates. They also accurately differentiated the isolates as nonpolio or polio isolates. This approach seems to be very promising for environmental surveillance of enterovirus circulation and epidemiology, with all of the significant effects that this entails for public health. Partial VP1 sequencing is efficient for molecular serotyping of enteroviruses, while 5'-UTR RFLP analysis with HpaII can also be considered an asset for the initial subclassification of enterovirus isolates.

A comparative amplification of five different genomic regions on Coxsackie A and B viruses. Implications in clinical diagnostics

Modern molecular approaches in Human Enterovirus detection rely on the designing of generic and often degenerate primers in order to amplify specific sequences within the enterovirus genome. In the present study a comparative application of primer sets targeting 5'UTR, the VP1 region, the 3D region as well as a long genomic fragment including the 3'end of VP1, the full length of 2A and 2B, and the 5' moiety of the 2C-coding region was attempted, in order to evaluate their specificity and suitability. The best amplification results from the investigation of 21 CAV reference strains, all six CBV reference strains and 44 clinical strains varying in origin and time of isolation, arose using primer sets 292-222 and UC53-UG52. Based on the above results we conclude that some of the published protocols need to be improved so as to fulfill the demands of an accurate detection and typing of Coxsackie A and B viruses. Contrarily, two of the protocols applied were proved to be more accurate in terms of specificity and general applicability, suggesting that RT-PCR followed by a simple RFLP assay in the case of primer pair UC53-UG52 or by sequencing and sequence analysis in the case of primer set 292-222 should constitute alternative means of modern typing and diagnostics against conventional immunological classification methods.

Amplification of Echoviruses genomic regions by different RT-PCR protocols--a comparative study

In the present report, the results of a comparative study in the detection of all Echoviruses reference strains as well as of 38 clinical isolates are presented. Using RT-PCR with already published primer pairs (UG(52)-UC(53), 292-222, 012-011 and EUG2a, 2b, 2c-EUC2) from the 5'UTR, the VP1 region as well as a long genomic fragment including the VP1 3' end, the entire coding sequence of 2A, 2B, and the 5' moiety of the 2C-coding region amplification was effective with all reference and clinical Echovirus isolates with primer pair UG(52)-UC(53) while with 292-222 and 012-011 were amplified 27/28 reference Echovirus strains and all clinical isolates. As far as EUG2a,2b,2c-EUC2 is concerned, the RT-PCR gave a positive result for 26/28 reference Echovirus strains and 34/38 clinical isolates. The sequence analysis of a large part of the 5'UTR has revealed that there is no correlation between 5'UTR identity and the currently recognized human enterovirus species. It has been suggested that part of VP1 coding sequence would correlate well with serotype since a number of important neutralization epitopes, as well as receptor recognition sequences, lie within the VP1 coding sequence. Therefore, UG(52)-UC(53) and 292-222 primer pairs seem to be the most appropriate for Echovirus detection and, moreover, UG(52)-UC(53) is useful for the classification of enteroviruses into genetic clusters (sub-groups) while 292-222 for the identification of enteroviruses by amplicon sequencing.

Molecular sub-grouping of enterovirus reference and wild type strains into distinct genetic clusters using a simple RFLP assay

RFLP analysis and sequencing of RT-PCR amplicons in previous studies revealed the existence of intra-serotypic variability in the 5'-UTR of human enteroviruses, complicating the use of this method to serotype isolates. During the present study, the available sequences of many enterovirus reference and wild type strains were analysed in an attempt to discover restriction sites that would rapidly and reliably aid the classification of human enteroviruses into specific sub-groups on the basis of their 5'-UTR for diagnostic and/or epidemiological purposes. Despite intratypic genetic variability in the 5'-UTR, the results of the sequence analysis, as well as data from the RFLP analysis of 61 enterovirus reference strains from 60 different serotypes and 123 clinical isolates showed that one restriction endonuclease, HpaII, may contribute to a reliable sub-classification of CAVs and the rest of enteroviruses, on the basis of 5'-UTR, into five genetic groups, which could be particularly useful in clinical and epidemiological studies. Although more sequence data from enterovirus reference and wild type strains may be required for the elaboration of a precise molecular identification system, the more possible genotypic classification into distinct clusters, as shown with the restriction enzyme HpaII, and the determination of the biological significance of this grouping (pathogenesis, epidemiology) might constitute an alternative means of enterovirus identification against conventional classification into distinct serotypes.