Mokola Virus in Domestic Mammals,South Africa

Claude T. Sabeta,*† Wanda Markotter,Debrah K. Mohale,* Wonderful Shumba,* Alexander I. Wandeler,‡ and Louis H. Nel

We recently identied 2 Mokola viruses from domestic mammals (a dog and a cat) in South Africa. These cases occurred 8 years after the last reported case of infection with this virus. Our ndings emphasize the endemicity of rabies-related lyssaviruses in South Africa and the need to better understand the epidemiology of Mokola viruses.

okola virus (MOKV) is classied as genotype (gt) 3 of the genus Lyssavirus in the family Rhabdoviridae (order Mononegavirales). Apart from MOKV, the genus Lyssavirus consists of 6 gts: classic rabies virus (gt1), Lagos bat virus (gt2), Duvenhage virus (gt4), European bat lyssavirus type 1 (gt5) and type 2 (gt6), and Australian bat lyssavirus (gt7). Some novel lyssaviruses identied in bat species in the former Soviet Union are considered putative gts within this genus (1).

Although gt1 viruses have a global distribution, gt5 and gt6 viruses are restricted to Europe and gt7 viruses are limited to Australia. Natural infections with gt2, gt3, and gt4 viruses have been found only in Africa. With the exception of MOKV, all lyssavirus gts and putative gts have been isolated exclusively or most frequently from chiropteran species. MOKV has never been isolated from these species, but only from terrestrial mammals. The rst MOKV was isolated from shrews (Crocidura sp.) in Nigeria in 1968. Since then, >20 isolates of this lyssavirus have been found throughout Africa (Cameroon, Central African Republic, Ethiopia, South Africa, and Zimbabwe) (212) (Table 1).

We report the identication and characterization of 2 cases of infection with MOKV in South Africa. The rst was in a domestic dog and is, to our knowledge, the rst such case in South Africa. The second was in a domestic cat, the host species in which all previous isolates were found. The cat MOKV isolate belonged to 1 of 2 previously identied South African MOKV phylogenetic lineages, but the dog MOKV isolate appeared to have a different lineage not previously encountered in South Africa or elsewhere in Africa.

*Agricultural Research Council–Onderstepoort Veterinary Institute, Pretoria, South Africa; †University of Pretoria, Pretoria, South Africa; and ‡Canadian Food Inspection Agency, Nepean, Ontario, Canada

The Study

In October 2004, a 3-month-old kitten (Felis domesticus) was adopted from the Society of the Prevention of Cruelty to Animals (East London, Eastern Cape Province, South Africa) and lived with its owner on a farm 23 km outside the city. It had been neutered and had been vaccinated at 10 months of age with an adjuvanted inactivated vaccine against rabies (Rabisin; Merial, Lyon, France), but no subsequent vaccinations were given. The cat spent most of the day indoors, but went out at night and returned in the morning. Unusual behavior was noticed in March 2006. It appeared dull and physically unbalanced and its pupils were dilated but it was not aggressive. The cat was humanely killed, and its brain was sent to the Onderstepoort Veterinary Institute for rabies testing.

On June 17, 2005, a 6-month-old puppy (Canis familiaris) was brought by its owner to a veterinarian in the rural town of Nkomazi (Mpumalanga Province, South Africa). The dog had a temperature of 39.8°C and no appetite. After symptoms were treated, the dog was discharged, but it was brought back 11 days later because it was paralyzed, dehydrated, and had a xed stare. This animal had never been aggressive to other pets or humans. The dog was humanely killed, and its brain was sent to the Onderstepoort Veterinary Institute for rabies testing.

Direct immunouorescent antibody test with an antirabies conjugate cross-reactive with African lyssaviruses showed numerous and strongly stained inclusion bodies in every eld of impression smears of both brain samples. Isolation of virus was attempted by suckling mouse brain passage and cell culture (neuroblastoma cells; Diagnostic Hybrids, Athens, OH, USA); both methods were successful for the cat sample. However, neither method yielded an isolate from the dog sample, despite a lyssavirus-specic reaction in the original brain sample by direct immunouorescent antibody test.

Subsequently, antigenic characterization was performed with a panel of 16 monoclonal antibodies to the nucleocapsid protein of rabies virus (Canadian Food Inspection Agency, Nepean, Ontario, Canada). Both samples showed reactivity patterns associated with MOKV (Table 2).

Final conrmation of MOKV in both case samples was obtained by reverse transcription–PCR, nucleotide sequencing, and phylogenetic analysis as described (12). Phylogenetic analysis (Figure) showed that the virus isolated from the cat sample (designated MOKV173/06) belonged to the same lineage of MOKV isolates that were recovered from cats in the same region of South Africa (12). However, the virus detected in the dog sample (designated MOKV404/05) appeared to represent a different South African MOKV lineage that was phylogenetically positioned between known South African and Zimbabwean lineages. This MOKV had nucleotide similarities of 88.1%–90.4%

Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 13, No. 9, September 2007

DISPATCHES

Table 1. Moloka virus isolates identified in Africa

Location Year of isolation Species of origin Reference
Ibadan, Nigeria 1968 Shrew (Crocidura sp.) (3 isolates) (2)
Ibadan, Nigeria 1968 Human (3,4)
Ibadan, Nigeria 1969 Shrew (Crocidura sp.) (3)
Umhlanga Rocks, Kwazulu Natal Province, South Africa 1970 (identified in the 1980s) Cat (12)
Ibadan, Nigeria 1971 Human (3)
Yaounde, Cameroon 1974 Shrew (Crocidura sp.) (5)
Bangui, Central African Republic 1981 Rodent (Lophuromys sikapusi) (6)
Bulawayo, Zimbabwe 1981 Dog (vaccinated) and cat (4 isolates) (7)
Bulawayo, Zimbabwe 1982 Cat (2 isolates) (7)
Addis Adaba, Ethiopia 19891990 Cat (8)
Selous, Zimbabwe 1993 Cat (11)
Mdantsane, Eastern Cape Province, South Africa 1995 Cat (9)
East London, Eastern Cape Province, South Africa 1996 Cat (10)
Yellow Sands, Eastern Cape Province, South Africa 1996 Cat (vaccinated) (10)
Pinetown, Kwazulu Natal Province, South Africa 1997 Cat (vaccinated) (2 isolates) (10,12)
Pietermaritzburg, Kwazulu Natal Province, South Africa 1998 Cat (vaccinated) (10,12)
Nkomazi, Mpumalanga Province, South Africa 2005 Dog This study
East London, Eastern Cape Province, 2006 Cat (vaccinated) This study
South Africa

and 85.3%–88.5% with viruses from Zimbabwe and South Africa, respectively.

Conclusions

Infections with MOKV are rare; only 23 isolates are known. During the past 2 decades, all MOKV isolates have been found in South Africa. Because these viruses are not exclusive to South Africa (212), lack of isolates from other regions of Africa indicates a lack of active surveillance and limited diagnostic capabilities in many African laboratories. To our knowledge, the 2 cases of infection with MOKV we report are the rst in 8 years from South Africa. These cases suggest that other cases may not have been recognized. Clinical signs in the dog and cat, including general neurologic manifestations with a lack of aggression, are often signs that warrant submitting samples for rabies testing.

We have identied regional variations in the antigenic composition of MOKV. Whether these variations are caused by neutral genetic drift or reect different epidemiologic features is not known. Phylogenetically, divergence of these viruses into different lineages indicates active

Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 13, No. 9, September 2007

Moloka Virus in Domestic Mammals, South Africa

Figure. Phylogenetic tree based on 267 nt of partial nucleoprotein gene sequences of Moloka virus (MOKV) identied with the N1N2 primer set as described (12). The tree shows phylogenetic positions of 2 recently identied cases of MOKV infection from South Africa (MOKV173/06 from a cat and MOKV404/05 from a dog) (in boldface) relative to previously characterized MOKV isolates from South Africa (SA) and Zimbabwe (ZIM) and Lagos bat virus (LBV) as the outgroup. GenBank accession nos. are shown in parenthesis. Bootstrap support values >70% are considered signicant and indicated. Scale bar shows nucleotide substitutions per site.

cycles and evolutionary changes that occur independently, but in close proximity (a few hundred kilometers apart).

Although the epidemiology of MOKV is incomplete, the case for a reservoir host(s) among small terrestrial animals of limited range is supported by our ndings. Together with recent isolations of rabies-related lyssaviruses in a human (13) and wild animals (14,15), these reports emphasize the endemicity of these lyssaviruses in South Africa. Public health implications of African rabies-related lyssaviruses should be recognized by laboratory workers, researchers, veterinarians, wildlife personnel, gamekeepers, and pet owners. A better understanding of the epidemiology of these viruses is vital and can only be achieved by improved surveillance and awareness.

This study was supported by the Rabies Diagnostic Project OVI 15/4/P001.

Dr Sabeta is a senior research scientist and head of the World Organisation for Animal Health Rabies Reference Laboratory in Onderstepoort, South Africa. His research interests include epidemiologic investigations of rabies and rabies-related viruses in southern Africa.

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Address for correspondence: Claude T. Sabeta, Rabies Unit, Agricultural Research Council–Onderstepoort Veterinary Institute, Private Bag X05, Onderstepoort 0110, Pretoria, South Africa; email: sabetac@arc.agric.za

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