Hostname: page-component-8448b6f56d-t5pn6 Total loading time: 0 Render date: 2024-04-23T05:33:53.864Z Has data issue: false hasContentIssue false
  • English
  • Français

Differentiation between wild-type and vaccines strains of varicella zoster virus (VZV) based on four single nucleotide polymorphisms

Published online by Cambridge University Press:  27 July 2017

L. JIN ,
S. XU ,
P. A. C. MAPLE ,
W. XU  and
K. E. BROWN
L. JIN*
Affiliation:
Virus Reference Department, National Infections Service, Public Health England, London, UK
S. XU
Affiliation:
Institute of Viral Disease Control and Prevention, Chinese Centers for Disease Control and Prevention, Beijing, China
P. A. C. MAPLE
Affiliation:
Virus Reference Department, National Infections Service, Public Health England, London, UK
W. XU
Affiliation:
Institute of Viral Disease Control and Prevention, Chinese Centers for Disease Control and Prevention, Beijing, China
K. E. BROWN
Affiliation:
Virus Reference Department, National Infections Service, Public Health England, London, UK
*
*Author for correspondence: Dr L. Jin, Virus Reference Department, National Infections Service, Public Health England, 61 Colindale Avenue, London NW9 5EQ, UK. (Email: li.jin@phe.gov.uk)
Rights & Permissions [Opens in a new window]

Summary

Varicella–zoster virus (VZV) infection (chickenpox) results in latency and subsequent reactivation manifests as shingles. Effective attenuated vaccines (vOka) are available for prevention of both illnesses. In this study, an amplicon-based sequencing method capable of differentiating between VZV wild-type (wt) strains and vOka vaccine is described. A total of 44 vesicular fluid specimens collected from 43 patients (16 from China and 27 from the UK) with either chickenpox or shingles were investigated, of which 10 had received previous vaccination. Four sets of polymerase chain reactions were set up simultaneously with primers amplifying regions encompassing four single nucleotide polymorphisms (SNPs), ‘69349-106262-107252-108111’. Nucleotide sequences were generated by Sanger sequencing. All samples except one had a wt SNP profile of ‘A-T-T-T’. The sample collected from a patient who received vaccine 7–10 days ago, along with VZV vaccine preparations, Zostavax and Baike-varicella gave a SNP profile ‘G-C-C-C’. The results show that this method can distinguish vaccine-derived virus from wt viruses from main four clades, (clades 1–4) and should be of utility worldwide.

Keywords

Four-SNPs profilevaricella–zoster virus (VZV)wild-type and vaccine strains
Type
Original Papers
Information
Epidemiology & Infection , Volume 145 , Issue 12 , September 2017 , pp. 2618 - 2625
Check for updates
Copyright
Copyright © Cambridge University Press 2017 

INTRODUCTION

Varicella–zoster virus (VZV) causes varicella (chickenpox), a contagious human infectious disease characterised by a generalised vesicular rash. Subsequent to primary infection, lifelong latency is established in the sensory nerve ganglia and reactivation may occur years or decades later to cause herpes zoster (shingles) under conditions of declining immunity and/or with increasing age [Reference Gnann and Whitley1, Reference Chen2].

VZV belongs to the family Herpesviridae, subfamily Alphaherpesvirinae. It is an enveloped virus and consists of an approximately 125 kb of linear, double stranded DNA genome enclosed by an icosahedral nucleocapsid, which contains 71 open reading frames (ORFs), three of which are duplicated in the inverted repeat regions. Two main coding regions, one unique long (U L) and one unique short (U S), each bounded by inverted repeat regions and five repeat regions (R1–R5) have been identified in the genome [Reference Davison and Scott3, Reference Stow and Davison4].

The VZV genome is highly conserved with an estimated mutation rate of 10−6–10−7/site/year [Reference Winsome, Richard Nichols and Breuer5]. Five clades (1–5) and two provisional clades (VI and VII) have been identified based on an internationally agreed genotyping scheme [Reference Breuer6]. The universal nomenclature enables the interchange and comparison of genotyping data worldwide. Genotypic differentiation of the clades can be achieved using a panel of 16 single nucleotide polymorphisms (SNPs) scattered across the whole genome [Reference Winsome, Richard Nichols and Breuer5]. It is known that historically clades 1 and 3 predominate in Europe, clade 2 is found in Japan, China and Korea, and clades 4 and 5 are found mainly in India, Nepal, Bangladesh and Africa [Reference Schmidt-Chanasit and Sauerbrei7Reference Loparev10]. Small numbers of possible novel genotypes have been designated as provisional clades: clade VI strains were found in France, Italy, USA and Australia [Reference Loparev10], a clade VII strain was isolated in the USA in 2002 [Reference Sergeev11] and clade VIII and IX strains have been reported in Germany [Reference Zell12]. All the VZV vaccine strains, apart from one formulation in Korea, are based on the Oka strain of VZV isolated from a child in Japan [Reference Takahashi13] and are clade 2 viruses.

Neither England nor China offers routine vaccination of children against varicella although the vaccine is licensed in both countries. Currently, in China, population-based varicella vaccination is not undertaken as national policy; however, vaccination is available on a private basis for children aged 12–18 months. From 1 September 2014 a shingles vaccination program for older adults has been launched in England with the aim of reducing the incidence and severity of shingles in those targeted. The English shingles vaccination program offers Zostavax (Sanofi Pasteur MSD, France), a live attenuated vaccine, to adults aged 70 and currently there is a catch up programme for those aged 78 and 79 [14, 15]. The Zostavax vaccine used is derived from the Oka strain of VZV (vOka) and has significantly higher antigen content than the Varivax (Sanofi Pasteur MSD, France) or Varilrix (GlaxoSmithKline, UK) varicella vaccine used for vaccination against chickenpox.

Cases of both local vaccine-related rash and disseminated rash have occurred following immunisation with both varicella or zoster vaccine, especially if inadvertently given to immunocompromised individuals and it has been shown that the vaccine virus can establish latency with subsequent reactivation [Reference Quinlivan16]. Therefore, as part of the roll out of the shingles vaccination programme it has been recommended that all cases of local or disseminated zoster following vaccination be forwarded to the national laboratory at Public Health England, Colindale to determine whether the VZV isolated is wild-type (wt) or vaccine derived [14].

Differentiation of VZV vaccine strains from wt strains has become important in VZV surveillance for mainly three reasons: monitoring side reactions of vaccination, e.g. rashes and shingles occurring in vaccinated individuals; assessing effectiveness of vaccination by measuring national incidences of varicella and shingles; and identifying the frequency that the attenuated vOka can establish latency and subsequently reactivate to cause disease. Characterisation of wt VZV and the Oka vaccine strains can be achieved only by molecular genotyping methods. In previous studies, the genotypic differentiations of vOka from wt VZV strains were based mainly on SNPs 69349 in ORF38 [Reference LaRussa17, Reference Hondo18] or 105705 or 106262 in ORF62 [Reference Harbecke19Reference Thiele24]. However, a number of studies have shown that vOka vaccine preparations contain a mixture of virus strains leading to the recommendation that a set of four-markers in ORF62 should be used for diagnostic differentiation of wt VZV and vaccine-type VZV [Reference Quinlivan25, Reference Quinlivan and Breuer26].

In this study, an amplicon-based approach for distinguishing vOka from all wt VZV strains has been developed using four SNPs including three in ORF62, which were recently recommended [Reference Quinlivan and Breuer26] and one in ORF38 that has proved useful in the USA [CDC SOP, Dr DS Schmid, personal communication]. The methodology established was verified using samples from clades 1 to 4 collected from patients in the UK and China and confirm that this approach should have worldwide utility.

METHODS

Study populations

In this study, 44 vesicular fluid/swab specimens were investigated. The 28 specimens from 27 UK patients were received, including 17 for the purpose of chickenpox or shingles diagnosis and 10 enrolled as part of Public Health England shingles surveillance in patients over 70 (Table 1). Most (25/27) UK patients presented with shingles and 10 of them had been vaccinated with Zostavax (Sanofi Pasteur MSD, France) and one, a child had been vaccinated with the Varivax (Sanofi Pasteur MSD, France). The 16 samples collected from Chinese patients comprised 11 chickenpox samples and five shingles samples. Nine of the samples had previously been genotyped [Reference Xu27] and belonged to clades 2 and 4 (Table 1). The vaccination histories of Chinese patients were unknown, but routine varicella and shingles vaccination is not offered in China.

Table 1. Patients and clinical specimens investigated in the study

a Patient with immunosuppression.

b Previous shingles.

c Genotype/clade result from previous study [Reference Xu27].

Vaccine preparations and control strains used

Wild-type Dumas strain was obtained from the European Collection of Cell Cultures (Porton Down, UK). ROD VZV qDNA with a known concentration of 6 × 105 genomic copies/ml was used as a positive control for the real-time polymerase chain reaction (PCR) and was purchased from Source Bioscience (Nottingham, UK). The vaccine preparations, Zostavax (Sanofi Pasteur MSD, France) and Baike-varicella (Changchun BCHT Biotechnology Co., China) were used as sources of vOka. The Zostavax vaccine contained 19 400 P PFU/dose and the Baike-varicella vaccine contained 3300–4000 PFU/dose. These control strains were reconstituted and diluted using sterile nuclease-free water before DNA extraction.

DNA extraction

DNA extraction was carried out directly from 100 µl diluted vesicle fluid or diluted control samples using the automated BioMerieux NucliSENSeasyMAG system (Biomérieux, France) for quantitative real-time PCR testing. For the purpose of genotyping 200 µl vesicle fluid was extracted using the QIAamp DNA Mini kit (Qiagen, Valencia, CA) according to the manufacturer's instruction. The eluted DNA (50 µl) was stored at −30 °C before PCR amplification.

Detection of VZV DNA

All patient samples were initially confirmed VZV DNA positive by real-time PCR, which targeted a 77-base pair (bp) region of ORF29 in the VZV genome [Reference Quinlivan28]. The assay was slightly modified; 2·5 µl of extracted sample was amplified with 12·5 µl of 2× QuantiTect Probe PCR Master Mix (Qiagen), 25 pmol of both forward and reverse primers and 5 pmol of the probe in a total reaction volume of 25 µl. The real-time PCR was performed using an ABI 7500 real-time PCR system (Applied Biosystems).

Genotypic discrimination of wt VZV and vOka vaccines

The genotyping methodology for distinguishing between vaccine and wt strains was based on four previously reported SNPs [Reference Quinlivan and Breuer26]. Three of the SNPs were located within ORF62 at positions 106262, 107252, 108111 and the fourth one at 69349 in ORF38. Four pairs of primers for the PCRs and sequencing were designed (Table 2) with software Primer 3 [Reference Rozen and Skaletsky29] and BLAST searched for confirmation. Four separate PCR reaction mixtures were set up simultaneously using Katara Ex Taq kit (RR001A). Each contained 5 µl of 10× Ex-Taq buffer, 4 µl of 2·5 mM Ex-dNTP mix and 0·25 µl of Ex-Taq polymerase, in addition to 20 pmol of each primer and 5–10 µl sample DNA to make up to 50 µl with sterile nuclease-free water. The reactions were processed for 30 cycles of 40 s at 94 °C, 40 s at 55 °C and 1·5 min at 72 °C after an initial denaturation step for 2 min at 95 °C, and followed by extension at 72 °C for 5 min. PCR products were visualised by electrophoresis in a 2% agarose E-gel (Invitrogen). A positive result should display amplicon bands of molecular size 339–360 bp depending on the primer pairs used (Table 2).

Table 2. Primers designed for detection of the four SNPs

Confirmation of VZV clades

To confirm that the assay could distinguish vaccine from all four major clades VZV clade identification was carried out as previously described [Reference Breuer6, Reference Schmidt-Chanasit and Sauerbrei7]. Five SNPs in positions 37902, 38019, 38055, 38081 and 38177 within a 447 bp region of ORF22 (Dumas, GenBank No. X04370) were detected to identify all clades except for the clades 1 and 3; then the 6th SNP in position 39394 of ORF22 were further sequenced to discriminate between clades 1 and 3 (Table 3).

Table 3. SNP patterns for classification of VZV clades [Reference Breuer6, Reference Zell12]

Clean-up of PCR amplicons was performed using Agencourt AMPure XP PCR purification kit (Auto Q Biosciences Ltd, Berkshire, UK) and Sanger sequencing undertaken by the PHE Genomic Services Unit. Sequence data were analysed using an appropriate software program SeqMan (DNAStar).

RESULTS

Differentiation between vaccine and wt strains by the 4-SNPs method

The 4-SNPs assay for differentiation between vaccine and wt strains was evaluated by testing the wt Dumas and vaccine vOka strains from both Zostavax and Baike-varicella. The 4-SNPs, ‘69349–106262–107252–108111’ were confirmed as identical with those previously reported respectively, a wt SNP profile ‘A–T–T–T’ (GenBank accession number X04370 for Dumas strain and AB097933 for pOka strain) or vaccine SNP profile ‘G–C–C–C’ (GenBank accession number AB097932 for vOka strain). Whereas the results in a 1 : 1 mixture of wide: vaccine adjusted based on the real-time CT value showed a mixed profile ‘G–C–T–T’ repeatedly, targeted during PCR amplifications that two wt SNPs and two vaccine SNPs were detected (Table 4).

Table 4. Four SNPs detected for differentiation between wt and vaccine VZV strains

VZV characterisation in clinical specimens and Rod VZV DNA

All clinical specimens, except for UK-27 (Table 1) plus the Rod strain tested had the profile ‘A–T–T–T’, belonging to wt VZV. One sample from a HIV positive patient (case UK-23) who had two vesicular fluids tested, showed A–T–T–T whereas the second sample showed A–T–C–T. The SNP 107252 was identical to that of the vaccine strain; however, it became T after re-testing by PCR and sequencing. Sample UK-27 was collected from a 71-year-old patient who presented varicella like rash 7–10 days post-vaccination, showed vaccine SNP profile G–C–C–C. In addition to the 44 samples, five vesicular fluids collected from patients previously vaccinated with Zostavax were untypable by this approach due to their low DNA content (real-time PCR CT >30).

Identification of VZV clades

Due to the available volume of samples, 15 (eight from the UK and seven from China) specimens were further genotyped. Including the nine Chinese samples genotyped previously [Reference Xu27], there were six clade 1, 15 clade 2, two clade 3 and one clade 4 samples. All clade 1 and 3 samples were found in England and the clade 2 and 4 samples were found in China (Table 1).

DISCUSSION

Following the introduction of the vaccine programme, in order to determine the long-term consequences if vaccine strain persists and transmission from varicella vaccine recipients, a simple and reliable assay is needed, which reliably differentiates between wt VZV strains and vOka vaccine strains in clinical specimens as a part of the enhanced shingles in England. Recent studies reported that the wt allele has been shown to be present in a small percentage (2–6%) of genomes in the Oka vaccine preparation [Reference Quinlivan25, Reference Quinlivan and Breuer26] thus using just one of the loci is not reliable for discrimination between vOka and wt VZV and a minimum of three vaccine markers (106262, 107252 and 108111) in ORF62 must be used all together. In order to provide a simple and definitive assay for directly testing clinical specimens, we developed a PCR-Sanger sequencing-based approach, which targets the three markers recently recommended [Reference Quinlivan and Breuer26], and an additional one at position 69349 in ORF38. The fourth SNP 69349 in ORF38 was chosen because the nucleotide A creates a PstI restriction site in most wt strains, including clades 1, 3, 4, 5, IV and VII and 70% of clade 2 strains but the substitute G detected only in vOka and 30% of clade 2 strains abolishes this PstI site [Reference Hondo18, Reference Quinlivan and Breuer26, Reference LaRussa30].

Although limited clinical specimens were tested, the approach reported here has been validated and shown to be capable of differentiating between vaccine and wt VZV strains from different geographical locations. In our study, 11 patients were recently vaccinated who presented with shingles (10 patients) or chickenpox (one patient). The samples were collected over a period of between 2 days and 20 months after vaccination. Only one vaccine-type VZV was detected (9·1%), of which the patient (UK-27, Table 1) received the vaccine 7–10 days prior to rash onset, while wt VZV was detected in 10 patients, confirming that vaccination was in most cases not the source of the illness. Rates of skin rash due to vaccination have been reported to be approximately 5% in healthy children and 10% in adults following varicella vaccination [Reference Breuer6, Reference Ampofo31]. Only a few studies have applied laboratory methods to distinguish between vaccine and wt, 33% (two of six) [Reference Chun32] and 48% of 83 vaccinated subjects (<18 years old) were attributable to the vaccine following varicella vaccination [Reference Weinmann33]. According to the national guidance [14,15], Zostavax since it is a live vaccine should not be given to patients who have a known primary or acquired immunodeficiency state or patients who are receiving current immunosuppressive therapy, including high-dose corticosteroids, biological therapies or combination therapies. Fourteen of the 27 (51·9%) of the UK patients investigated including four who had received the shingles vaccine (case UK-7, 10, 11 and 13) were immunocompromised or had shingles previously (Table 1). The methodology established would facilitate a broad investigation in countries where VZV vaccination has been launched and contribute to investigations determining whether shingles vaccination can reduce the frequency and severity of clinical symptoms in these patients.

VZV strains have been classified into seven clades including two preliminary ones [Reference Breuer6], in addition, clades VIII and IX were reported [Reference Zell12] (Table 3). Genotyping 15 of the 44 strains showed that samples from England were either clade 1 or 3, whilst the samples from China were clade 2 or in once case clade 4 (Table 1) confirming previous reports that clades 1 and 3 predominately circulate in Europe and the Americas, clade 2 is mainly found in Korea, Japan and China, and clades 4 and 5 are mainly detected in India, Nepal, Bangladesh and Africa [Reference Breuer6Reference Zell12, Reference Xu27, Reference Peters34]. To show that the technique could be used elsewhere for distinguishing between wt and vaccine VZV in various clades, especially clade 2 as vaccine Oka belongs to clade 2, it is important that this method was shown to work in representative clade 2 samples. It appears that the methodology, which we have established is suitable to support the epidemiological surveillance of VZV during the vaccination era. However, it is still possible that this method may not work for all clade 2 viruses and caution using fixed loci should be taken as there is not only the possibility that recombination episodes may be missed, but that there also may be mixed infections.

The PCR-dependent sequencing approach may randomly amplify the majority of existing virus genomes as we discovered that SNP107252 was detected as vaccine once in one of two samples of case UK-23, who was an unvaccinated HIV positive shingles patient suggesting that VZV genomic mutations may occur in immunocompromised individuals. A wt VZV strain with a characteristic vOka vaccine marker at position 107252 was previously reported, which caused a small outbreak in the USA [Reference Lopez35], suggesting that it is essential to differentiate wt VZV from vaccine strains using as a minimum the recommended panel of three vaccine markers within ORF 62 (at positions 106262, 107252 and 108111) and further monitoring the SNPs in larger numbers of patient groups is necessary. The safety and efficacy of varicella vaccination for susceptible individuals and zoster vaccination for immune individuals has been established [Reference Kenneth36Reference LaRussa38]. However, the continual monitoring of patients who have been recently vaccinated is important as potential acquisition in a mixture of vaccine and wt of VZV genomes may occur. The approach established in our study could contribute to such investigations. Deep sequencing directly from clinical specimens using next generation sequencing should identify all variants [Reference Depledge39] and recombination, but currently such an approach still remains expensive and may not have the required sensitivity for patients with low viral loads. The methodology established in our study contributes to VZV surveillance in the era of vaccination.

ACKNOWLEDGEMENTS

We thank Sonia Ribeiro, Gayatri Amirthalingam and Antoaneta Bukasa (Immunisation Department, PHE) for providing the patients’ demographic information for the English patients and Pravesh Dhanilall (Virus Reference Department, PHE) for technical support.

DECLARATION OF INTEREST

The authors declare that they have no competing interests.

Footnotes

These authors are co-first authors.

Current address: Division of Clinical Neuroscience, Queen's Medical Centre, University of Nottingham, Nottingham, UK.

References

REFERENCES

1. Gnann, JW Jr., Whitley, RJ. Clinical practice. Herpes zoster. New England Journal of Medicine 2002; 347: 340346.CrossRefGoogle ScholarPubMed
2. Chen, SY, et al. Incidence of herpes zoster in patients with altered immune function. Infection 2014; 42: 325334.Google Scholar
3. Davison, AJ, Scott, JE. The complete DNA sequence of varicella-zoster virus. Journal of General Virology 1986; 67: 17591816.CrossRefGoogle ScholarPubMed
4. Stow, ND, Davison, AJ. Identification of a varicella-zoster virus origin of DNA replication and its activation by herpes simplex virus type 1 gene products. Journal of General Virology 1986; 67: 16131623.CrossRefGoogle ScholarPubMed
5. Winsome, B-M, Richard Nichols, R, Breuer, J. Phylogenetic analysis of Varicella-Zoster virus: evidence of intercontinental spread of genotypes and recombination. Journal of Virology 2002; 76: 19711979.Google Scholar
6. Breuer, J, et al. A proposal for a common nomenclature for viral clades that form the species varicella-zoster virus: summary of VZV nomenclature meeting 2008, Barts and the London School of Medicine and Dentistry, 24–25 July 2008. Journal of General Virology 2010; 91: 821828.Google Scholar
7. Schmidt-Chanasit, J, Sauerbrei, A. Evolution and world-wide distribution of varicella-zoster virus clades. Infection, Genetics and Evolution 2011; 11: 110.CrossRefGoogle ScholarPubMed
8. Kim, KH, et al. Genotype of varicella-zoster virus isolates in South Korea. Journal of Clinical Microbiology 2011; 49: 19131916.Google Scholar
9. Liu, J, et al. Genotyping of clinical varicella-zoster virus isolates collected in China. Journal of Clinical Microbiology 2009; 47: 14181423.Google Scholar
10. Loparev, VN, et al. Global identification of three major genotypes of varicella-zoster virus: longitudinal clustering and strategies for genotyping. Journal of Virology 2004; 78: 83498358.CrossRefGoogle ScholarPubMed
11. Sergeev, N, et al. New mosaic subgenotype of varicella-zoster virus in the USA: VZV detection and genotyping by oligonucleotide-microarray. Journal of Virology Methods 2006; 136: 816.Google Scholar
12. Zell, R, et al. Sequencing of 21 varicella-zoster virus genomes reveals two novel genotypes and evidence of recombination. Journal of Virology 2012; 86: 16081622.Google Scholar
13. Takahashi, M, et al. Live vaccine used to prevent the spread of varicella in children in hospital. Lancet 1974; 304: 12881290.CrossRefGoogle Scholar
14. Public Health England. Shingles: guidance and vaccination programme (https://www.gov.uk/government/collections/shingles-vaccination-programme).Google Scholar
15. Department of Health. Green Book: Chapter 28a Shingles (Herpes zoster) (https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/503773/2905109_Green_Book_Chapter_28a_v3_0W.PDF).Google Scholar
16. Quinlivan, ML, et al. Rashes occurring after immunization with a mixture of viruses in the Oka vaccine are derived from single clones of virus. Journal of Infectious Diseases 2004; 190: 793796.Google Scholar
17. LaRussa, P, et al. Restriction fragment length polymorphism of polymerase chain reaction products from vaccine and wild-type varicellazoster virus isolates. Journal of Virology 1992; 66: 10161020.CrossRefGoogle ScholarPubMed
18. Hondo, R, et al. Distribution of varicella-zoster virus strains carrying a Pst1 site-less mutation in Japan and DNA change responsible for the mutation. Japanese Journal of Experimental Medicine 1989; 59: 233237.Google Scholar
19. Harbecke, R, et al. A real time PCR assay to identify and discriminate among wild-type and vaccine strains of Varicella Zoster virus and Herpes Simplex virus in clinical specimens, and comparison with the clinical diagnoses. Journal of Medical Virology 2009; 81: 13101322.Google Scholar
20. Higashimoto, Y, et al. Discriminating between varicella-zoster virus vaccine and wild-type strains by loop-mediated isothermal amplification. Journal of Clinical Microbiology 2008; 46: 26652670.Google Scholar
21. Ihira, M, et al. Cycling probe technology to quantify and discriminate between wild-type varicella-zoster virus and Oka vaccine strains. Journal of Virology Methods 2013; 193: 308313.Google Scholar
22. Loparev, VN, et al. Improved identification and differentiation of varicella-zoster virus (VZV) wild-type strains and an attenuated varicella vaccine strain using a VZV open reading frame 62-based PCR. Journal of Clinical Microbiology 2000; 38: 31563160.Google Scholar
23. Kaushik, KS, et al. Differentiation of wild-type varicella-zoster strains from India and the Oka vaccine strain using a VZV open reading frame-62 based PCR-RFLP technique. Brazil Journal Infectious Disease 2008; 12: 313315.Google Scholar
24. Thiele, S, et al. Molecular analysis of varicella vaccines and varicella-zoster virus from vaccine-related skin lesions. Clinical Vaccine Immunology 2011; 18: 10581066.Google Scholar
25. Quinlivan, ML, et al. Novel genetic variation identified at fixed loci in ORF62 of the Oka varicella vaccine and in a case of vaccine-associated herpes zoster. Journal of Clinical Microbiology 2012; 50: 15331538.Google Scholar
26. Quinlivan, M, Breuer, J. Clinical and molecular aspects of the live attenuated Oka varicella vaccine. Review in Medical Virology 2014; 24: 254273.Google Scholar
27. Xu, S, et al. Nationwide distribution of varicella-zoster virus clades in China. BMC Infectious Diseases 2016; 16: 542.Google Scholar
28. Quinlivan, M, et al. Effect of viral load on the outcome of herpes zoster. Journal of Clinical Microbiology 2007; 45: 39093914.CrossRefGoogle ScholarPubMed
29. Rozen, S, Skaletsky, HJ. Primer3. 1998. Code available at (http://wwwgenome.wi.mit.edu/genome_software/other/primer3.html).Google Scholar
30. LaRussa, P, et al. Restriction fragment length polymorphism of polymerase chain reaction products from vaccine and wild-type varicella-zoster virus isolates. Journal of Virology 1992; 66: 10161020.CrossRefGoogle ScholarPubMed
31. Ampofo, K, et al. Persistence of immunity to live attenuated varicella vaccine in healthy adults. Clinical Infectious Diseases 2002; 34: 774779.CrossRefGoogle ScholarPubMed
32. Chun, C, et al. Laboratory characteristics of suspected herpes zoster in vaccinated children. Pediatric Infectious Disease Journal 2011; 30: 719721.Google Scholar
33. Weinmann, S, et al. Incidence and clinical characteristics of herpes zoster among children in the varicella vaccine era, 2005–2009. Journal of Infectious Diseases 2013; 208: 18591868.Google Scholar
34. Peters, GA, et al. A full-genome phylogenetic analysis of varicella-zoster virus reveals a novel origin of replication-based genotyping scheme and evidence of recombination between major circulating clades. Journal of Virology 2006; 80: 98509860.CrossRefGoogle ScholarPubMed
35. Lopez, AS, et al. Transmission of a newly characterized strain of varicella-zoster virus from a patient with herpes zoster in a long-term-care facility, West Virginia, 2004. Journal of Infectious Diseases 2008; 197: 646653.CrossRefGoogle Scholar
36. Kenneth, E, et al. Efficacy, safety, and tolerability of herpes zoster vaccine in persons aged 50–59 years. Clinical Infectious Diseases 2012; 54: 922928.Google Scholar
37. Marietta, V, et al. The effectiveness of the varicella vaccine in clinical practice. New England Journal of Medicine 2001; 344: 955960.Google Scholar
38. LaRussa, P, et al. Viral strain identification in varicella vaccines with disseminated rashes. Pediatric Infectious Disease Journal 2000; 19: 10371039.Google Scholar
39. Depledge, DP, et al. Viral genome sequencing proves nosocomial transmission of fatal varicella. Journal of Infectious Diseases 2016; 214: 13991402.Google Scholar
Figure 0

Table 1. Patients and clinical specimens investigated in the study

Figure 1

Table 2. Primers designed for detection of the four SNPs

Figure 2

Table 3. SNP patterns for classification of VZV clades [6, 12]

Figure 3

Table 4. Four SNPs detected for differentiation between wt and vaccine VZV strains