Immunodeficiency-associated vaccine-derived poliovirus type 3 in infant, South Africa, 2011.
Persons born with primary immunodeficiency have been found to be persistently infected with VDPV after exposure to OPV. Immunocompetent persons excrete polio vaccine viruses for up to 2-3 months (2), whereas prolonged Author affiliation: National Institute for Communicable Diseases National Health Laboratory Service, Johannesburg, South Africa excretion of VDPV for 6 months to >10 years has been found in persons with primary humoral immunodeficiency (3-6). The risk for vaccine-associated paralytic poliomyelitis is >3,000-fold higher for these patients (7). We report a case of type 3 iVDPV in a child in South Africa who was born with X-linked immunodeficiency syndrome.
The patient, a 10-month-old boy, was born at term on October 28, 2010; X-linked immunodeficiency syndrome was diagnosed after he received 3 scheduled doses of polio vaccine (1 OPV dose at birth and 2 inactivated poliovirus vaccine doses at 10 and 14 weeks). On September 18, 2011, fever developed (38.5[degrees]C-40.0[degrees]C), and the next day, vomiting and 2 episodes of tonic-clonic convulsions occurred. A lumbar puncture was performed, and testing of cerebrospinal fluid (CSF) showed pleocytosis and mild increase of proteins. His condition deteriorated, and on day 5, acute flaccid paralysis developed, with generalized hypotonia and reduced power and reflexes in all limbs, more marked in the lower limbs. Respiratory distress developed, and some involvement of the facial nerve was manifested by left-sided eye drooping, mouth deviation, and drooling. A lumbar puncture was repeated on day 5, and CSF was positive by PCR for enterovirus and a pleocytosis. Stool samples taken on days 5 and 9 were positive for enterovirus, which was subsequently characterized as poliovirus type 3.
Beginning 15 days after the onset of paralysis, intravenous immunoglobulin (National Bioproducts Institute, KwaZulu-Natal, South Africa) with a titer for polio type 3 neutralizing antibodies of 4-8 IU was administered daily for 32 days, followed by alternate days to a total of 43 doses. The patient improved gradually, and strength was regained in all limbs, with the exception of residual paresis in the right lower limb. CSF became negative for poliovirus PCR 2 weeks after immunoglobulin therapy began, and stool excretion of poliovirus ceased on day 70, 55 days after initiation of immunoglobulin therapy.
Extracts of stool specimens were treated with chloroform and cultured on human rhabdomyosarcoma cell line, used for enterovirus isolation, and mouse L cells expressing the human poliovirus receptor, used specifically for poliovirus isolation (8). To distinguish whether the poliovirus isolates were of vaccine or wild origin, real-time PCR tests were performed, targeting the VP1 coding region (9). In addition, to detect mutant and recombinant poliovirus vaccine strains, a vaccine-derived, real-time screening assay was performed (David Kilpatrick, pers. comm.).
All Sabin 3 strains were sequenced at 3 regions of the genome: 5' untranslated region, VP1, and 3D. The sequence analysis of all viruses revealed a mutation at nt 472 of the 5' untranslated region ([U.sub.472] [right arrow] C), a critical attenuating mutation feature for Sabin 3. This substitution in the internal ribosomal site restores the original structure of the stem loop and permitting the initiation of translation of the poliovirus RNA template (10,11) The reversion at that site is under strong selection during replication in the human intestine and is associated with the attenuated phenotype in Sabin 3 (12). The VP1 region showed 2 reversions of the capsid determinant; [C.sub.2493] [right arrow] U appear to be the main determinants of the attenuated phenotype (1), and at position 54 for alanine amino acid mutated to valine ([Ala.sub.54] [right arrow] Val) that can act as a suppressor of the temperature sensitivity and attenuated phenotype (13). At the 3D region, the sequence analysis showed no recombinant.
Both stool samples showed mixed bases at 12 positions, consistent with the presence of at least 2 main genetic variants in the virus population (Table). Isolates with mixed bases are characteristic of iVDPVs, which suggests the existence of co-replicating poliovirus lineages within immunodeficient patients (1,5).
The relationships among the VP1 sequences of the 3 isolates were summarized in a tree constructed by using the neighbor-joining method (14) and rooted to the Sabin 3 sequence (Figure). The iVDVP isolates differed from the Sabin 3 OPV strain at 1.1% and from each other by 1.4% at a VP1 region, similar to the rate of nucleotide sequence evolution in poliovirus as described by Jorba et al. (15). The chronic iVDPV infection could have been initiated by the birth dose. The shallow branches correspond to 2 lineages (A, CSF, and B, stool). The extensive divergence of the two lineages was not surprising as the viruses originated from 2 sources (CSF and stool samples) taken 4 days apart. The VP1 sequence of lineage B was ambiguous at several positions, which suggests the virus population was of mixed variants. All sequences determined in this study were derived from Sabin 3 strain.
Cases of iVDPV are rare; especially rare is type 3. Only [approximately equal to] 50 cases had been reported in the literature as of March 2011 and, to our knowledge, none in sub-Saharan Africa. We characterized 2 separate lineages of type 3 poliovirus in this patient, demonstrating separate evolution of the virus. A relatively rapid clinical and virologic response to intravenous immunoglobulin averted chronic excretion of the virus. Persistent excretion of VDPV in primary immunodeficient patients remains a potential risk to the global eradication of polio, as long as OPV is still used.
We thank the National Institute for Communicable Diseases Polio Working Group for excellent technical assistance and M. Kriel for clinical information.
Ms Gumede is a medical scientist pursuing a PhD at the University of Pretoria, South Africa. Her research interests include disease epidemiology, clinical research, and polioviruses.
(1.) Kew OM, Sutter RW, de Gourville EM, Dowdle WR, Pallansch MA. Vaccine-derived polioviruses and the endgame strategy for global polio eradication. Annu Rev Microbiol. 2005;59:587-635. http:// dx.doi.org/10.1146/annurev.micro.58.030603.123625
(2.) Alexander JP Jr, Gary HE Jr, Pallansch MA. Duration of poliovirus excretion and its implications for acute flaccid paralysis surveillance: a review of the literature. J Infect Dis. 1997;175(Suppl 1):S176-82. http://dx.doi.org/10.1093/infdis/175.Supplement_1.S176
(3.) Kew OM, Sutter RW, Nottay BK, McDonough MJ, Prevots DR, Quick L, et al. Prolonged replication of a type 1 vaccine-derived poliovirus in an immunodeficient patient. J Clin Microbiol. 1998;36:2893-9.
(4.) Misbah SA, Lawrence PA, Kurtz JB, Chapel HM. Prolonged faecal excretion of poliovirus in a nurse with common variable hypogammaglobulinaemia. Postgrad Med J. 1991;67:301-3. http://dx.doi. org/10.1136/pgmj.67.785.301
(5.) Martin J, Dunn G, Hull R, Patel V, Minor PD. Evolution of the Sabin strain of type 3 poliovirus in an immunodeficient patient during the entire 637-day period of virus excretion. J Virol. 2000;74:3001-10. http://dx.doi.org/10.1128/JVI.74.7.3001-3010.2000
(6.) Bellmunt A, May G, Zell R, Pring-Akerblom P, Verhagen W, Heim A. Evolution of poliovirus type I during 5.5 years of prolonged enteral replication in an immunodeficient patient. Virology. 1999;265:178-84. http://dx.doi.org/10.1006/viro.1999.0003
(7.) Shahmahmoodi S, Mamishi S, Aghamohammadi A, Aghazadeh N, Tabatabaie H, Gooya MM, et al. Vaccine-associated paralytic poliomyelitis in immunodeficient children, Iran, 1995-2008. Emerg Infect Dis. 2010;16:1133-6. http://dx.doi.org/10.3201/eid1607.091606
(8.) World Health Organization. Polio laboratory manual, 4th ed. Geneva: The Organization; 2004. WHO/IVB/04.10.
(9.) Kilpatrick DR, Yang CF, Ching K, Vincent A, Iber J, Campagnoli R, et al. Rapid group-, serotype-, and vaccine strain-specific identification of poliovirus isolates by real-time reverse transcription-PCR using degenerate primers and probes containing deoxyinosine residues. J Clin Microbiol. 2009;47:1939-41. http://dx.doi.org/10.1128/ JCM.00702-09
(10.) Gromeier M, Bossert B, Arita M, Nomoto A, Wimmer E. Dual stem loops within the poliovirus internal ribosomal entry site control neurovirulence. J Virol. 1999;73:958-64.
(11.) Haller AA, Stewart SR, Semler BL. Attenuation stem-loop lesions in the 5' noncoding region of poliovirus RNA: neuronal cell-specific translation defects. J Virol. 1996;70:1467-74.
(12.) Dunn G, Begg NT, Cammack N, Minor PD. Virus excretion and mutation by infants following primary vaccination with live oral poliovaccine from two sources. J Med Virol. 1990;32:92-5. http:// dx.doi.org/10.1002/jmv.1890320205
(13.) Minor PD, Dunn G, Evans DM, Magrath DI, John A, Howlett J, et al. The temperature sensitivity of the Sabin type 3 vaccine strain of poliovirus: molecular and structural effects of a mutation in the capsid protein VP3. J Gen Virol. 1989;70:1117-23. http://dx.doi. org/10.1099/0022-1317-70-5-1117
(14.) Saitou N, Nei M. The neighbor-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol. 1987;4:406-25.
(15.) Jorba J, Campagnoli R, De L, Kew O. Calibration of multiple poliovirus molecular clocks covering an extended evolutionary range. J Virol. 2008;82:4429-40. http://dx.doi.org/10.1128/JVI.02354-07
Author affiliation: National Institute for Communicable Diseases National Health Laboratory Service, Johannesburg, South Africa
Author for correspondence: Nicksy Gumede, National Institute for Communicable Diseases, No. 1 Modderfontein Road, Sandringham, Johannesburg, 2131, South Africa; email: email@example.com
Table. Mixed bases at various positions of immunodeficiency- associated vaccine-derived polioviruses Mixed bases Viral protein 1 Sabin 3 position Stool sample 1 Stool sample 2 G 175 G/A G/A A 231 A/G A/G T 261 C/T C/T G 295 G/A G/A C 420 C/T C C 426 T/C T/C A 444 G/A G/A A 658 A/G A/G A 659 A/G G/A G 661 G/A G/A G 666 A/G G/A C 684 T/C T/C
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|Author:||Gumede, Nicksy; Muthambi, Vongani; Schoub, Barry D.|
|Publication:||Emerging Infectious Diseases|
|Date:||Jun 1, 2012|
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