Panayotis Markoulatos

Laboratory Diagnosis of Common Herpesvirus Infections of the Central Nervous System by a Multiplex PCR Assay

ABSTRACT A sensitive multiplex PCR assay for single-tube amplification that detects simultaneous herpes simplex virus type 1 (HSV-1), herpes simplex virus type 2 (HSV-2), varicella-zoster virus (VZV), human cytomegalovirus (CMV), and Epstein-Barr virus (EBV) is reported with particular emphasis on how the method was optimized and carried out and its sensitivity was compared to previously described assays. The assay has been used on a limited number of clinical samples and must be thoroughly evaluated in the clinical context. A total of 86 cerebrospinal fluid (CSF) specimens from patients which had the clinical symptoms of encephalitis, meningitis or meningoencephalitis were included in this study. The sensitivity of the multiplex PCR was determined to be 0.01 and 0.03 50% tissue culture infective doses/the reciprocal of the highest dilution positive by PCR for HSV-1 and HSV-2 respectively, whereas for VZV, CMV and EBV, 14, 18, and 160 ag of genomic DNA were detected corresponding to 48, 66, and 840 genome copies respectively. Overall, 9 (10.3%) of the CSF samples tested were positive in the multiplex PCR. HSV-1 was detected in three patients (3.5%) with encephalitis, VZV was detected in four patients (4.6%) with meningitis, HSV-2 was detected in one neonate (1.16%), and CMV was also detected in one neonate (1.16%). None of the samples tested was positive for the EBV genome. None of the nine positive CSF samples presented herpesvirus coinfection in the central nervous system. Failure of DNA extraction or failure to remove any inhibitors of DNA amplification from CSF samples was avoided by the inclusion in the present multiplex PCR assay of α-tubulin primers. The present multiplex PCR assay detects simultaneously five different herpesviruses and sample suitability for PCR in a single amplification round of 40 cycles with an excellent sensitivity and can, therefore, provide an early, rapid, reliable noninvasive diagnostic tool allowing the application of antiviral therapy on the basis of a specific viral diagnosis. The results of this preliminary study should prompt a more exhaustive analysis of the clinical value of the present multiplex PCR assay.

Sheep poxvirus identification by PCR in cell cultures

A simple, rapid and specific diagnostic polymerase chain reaction (PCR) method was developed for sheep poxvirus identification. The primers used were from the sequenced genomes of the capripox viruses KS-1 and InS-1. Six different sheep pox isolates were tested against two orf (parapox) and three animal herpesviruses as controls. Material from uninfected cell cultures was also used as control. The sensitivity of the PCR was approximately equivalent with each of the two primers and for the six sheep pox isolates. All the negative control virus DNAs were negative and differed clearly from those of the sheep pox strains.

Detection of sheep poxvirus in skin biopsy samples by a multiplex polymerase chain reaction.

The development of a multiplex polymerase chain reaction (PCR) method with amplification of capripoxvirus in a single-step procedure from skin biopsies using three primer pairs, two specific for capripoxvirus and one specific for alpha-tubulin is described. A sensitive multiplex PCR was achieved by optimization of parameters such as the primer concentrations, magnesium and dNTPs concentrations. False negative results that sometimes arise due to inhibitors of DNA amplification may be avoided by the inclusion in the assay of alpha-tubulin primers. The results reported on 42 skin biopsies from sheep suspected to have poxvirus infection, indicated that the assay could monitor simultaneously DNA extraction from skin biopsy samples and allow improved detection of capripoxvirus within 24 h of specimen receipt in the laboratory.

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.

Sabin Type 2 Polioviruses with Intertypic Vaccine/Vaccine Recombinant Genomes

Abstract. Attenuated strains of the Sabin oral poliovirus vaccine replicate in the human gut and, in rare cases, cause vaccine-associated paralytic poliomyelitis. In the present study, 15 vaccine-derived strains isolated from patients with vaccine-associated paralytic poliomyelitis and from healthy vaccinees were examined. Four distant sequences of the poliovirus genome (5′ NCR, VP3/VP1, VP1/2A, and 3DPol/3′ NCR) were targeted, and the reverse-transcribed segments were amplified by polymerase chain reaction followed by restriction fragment length polymorphism analysis with four restriction enzymes. Among the 15 isolates (11 Sabin type 2, 3 Sabin type 1, and 1 Sabin type 3), four Sabin type 2 isolates (36%) were found to be intertypic vaccine/vaccine recombinant in the 3DPol/3′ NCR region of the viral genome. The recombinant genotypes identified were S2/S2/S1 for two isolates and S2/S2/S2/S3 and S2/S2/S1/S2 for each of the other two isolates, respectively. Recombinant viruses with unmodified segments in the 5′ NCR and the VP3/VP1 regions of the viral genome, a modified segment in the VP1/2A region only for one strain, and an often recombinant segment in the 3DPol/3′ NCR parts of the genome were so identified. These findings provide strong evidence that recombination is a frequent phenomenon in type 2 poliovirus vaccine strains and suggest that recombination may be an important mechanism of the natural evolution of polioviruses of Sabin type 2 origin, perhaps even one of the mechanisms of reversion of attenuated vaccine strains toward neurovirulence.

Detection and typing of HSV-1, HSV-2, and VZV by a multiplex polymerase chain reaction.

The development of a multiplex polymerase chain reaction method for the rapid and accurate detection and typing of HSV‐1, HSV‐2, and VZV from clinical specimens is described. A sensitive multiplex polymerase chain reaction was achieved by optimization of parameters such as the primers, magnesium, and dNTPs concentrations. False‐negative results that sometimes arise due to inhibitors of DNA amplification or failure of DNA extraction procedure used may be avoided by assaying each specimen with α‐tubulin primers. Multiplex PCR amplified viral sequences from all 55 specimens obtained from patients with clinical evidence of HSV or VZV infection indicated 100% sensitivity. From 55 patients who were investigated by multiplex PCR, HSV‐1 was detected in 28, HSV‐2 in 20, and VZV in 7 specimens. The reported results indicate that the present multiplex PCR assay has a potential application in clinical diagnosis when a rapid and accurate detection and typing of involved viruses HSV‐1, HSV‐2, or VZV is needed. J. Clin. Lab. Anal. 14:214–219, 2000.

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

ABSTRACT 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 Α9 (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.

Genomic analysis of recombinant sabin clinical isolates.

Recombination in Poliovirus vaccine strains is a very frequent phenomenon. In this report 23 polio/Sabin strains isolated from healthy vaccinees or from VAPP patients after OPV administration, were investigated in order to identify recombination sites from 2C to 3D regions of the poliovirus genome. RT-PCR, followed by Restriction Fragment Length Polymorphism (RFLP) screening analysis were applied in four distant genomic regions (5′ UTR, VP1, 2C and 3C–3D) in order to detect any putative recombinant. The detected recombinants were sequenced from 2C to the end of the genome (3′ UTR) and the exact recombination sites were determined with computational analysis. Five of the 23 isolated strains were recombinant in one genomic region, two of them in 2C, isolates EP16:S3/S2, EP23:S3/S1, two in 3D isolates EP6:S2/S1, EP12:S2/S1 and one in 3A isolate EP9:S2/Sl. Point mutations were found in strains EP3, EP6, EP9 and EP12. Recombination specific types and sites re-occurrence along with point mutations are discussed concerning the polioviruses evolution.

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.

Molecular characterization of wild-type polioviruses isolated in Greece during the 1996 outbreak in Albania

ABSTRACT During the present study three type 1 poliovirus strains isolated in Greece during the 1996 poliomyelitis outbreak in Albania were retrospectively investigated and determination of their relationship with other epidemic strains isolated in Albania or elsewhere during previous epidemics was attempted. SimPlot analysis revealed that the three Greek strains are the result of a recombination event in the VP2 coding region.