Abstract
Akabane virus (AKAV) is recognized as an important pathogen that causes abortions and congenital malformations in ruminants. However, it has not received adequate attention in Nigeria. Therefore, in investigating this disease, serum samples from 184 (abattoir and farm) head of cattle and 184 intensively reared sheep from two states in southwest Nigeria were screened for antibodies against AKAV using enzyme-linked immunosorbent assay. An overall seropositivity of 70.1% (129/184) was obtained with antibodies being detectable in 73.8% of abattoir (trade) cattle and 40.0% in farm cattle, while 4.3% (8/184) seropositivity was observed in sheep. All the age groups of cattle tested had seropositive animals, 0-1 year (1/7, 14.3%), 2-3 years (17/34, 50.0%), 4-5 years (92/121, 76.0%), and >5 years (19/22, 86.4%), while in sheep only the age groups of 2-3 and 4-5 years showed seropositivity of 4.1% (4/97) and 8.2% (4/49), respectively. The detection of antibody-positive animals among unvaccinated cattle and sheep provides evidence of AKAV infection in Nigeria. These findings call for continuous monitoring of the disease among ruminants in order to ascertain the actual burden and increase awareness of the disease. This will facilitate early detection and aid the development of appropriate control measures against the disease in Nigeria.
1. Introduction
The family Bunyaviridae is the largest virus family with over 350 member viruses that are classified into five genera, including the Orthobunyavirus genus which contains a large number of viruses that share common genetic features [1]. Based on serological relationships, viruses in this genus have been divided into serogroups with the Simbu serogroup being one of the largest. Several Simbu serogroup viruses isolated from domestic and wild animals as well as mosquito and Culicoides vectors have been found in Africa, Australia, Asia, and the Middle East [2–6]. This serogroup, which includes Akabane, Aino, and Shamonda viruses, plays a significant role as pathogens of ruminants with Akabane virus (AKAV) being the most recognized [7]. In particular, Akabane virus, a teratogenic, Culicoides-borne virus, replicates in many kinds of natural host species and in several experimental animals [8]. Based on serological evidence, cattle, horses, donkeys, sheep, goats, pigs, camels, and buffaloes appear to be infected in natural situations [9, 10]. AKAV has been identified as a cause of seasonal epizootics of reproductive disorders (abortions, premature births, and stillbirths) and congenital arthrogryposis, hydranencephaly, or microencephaly in cattle, sheep, and goats, sometimes resulting in significant economic losses [1, 6, 11].
Although virus isolation [2], histopathology, immunohistochemistry, serology, and genetic analysis [12] have been used for laboratory confirmation of AKAV infections, serology is the most practical and commonly used technique. Specific antibodies against AKAV have been detected using virus neutralization test (VNT) and enzyme-linked immunosorbent assay (ELISA) [13, 14]. In Africa, limited information based on virus isolation and/or serology revealed the presence of AKAV in Kenya [2, 10], Sudan [15, 16], South Africa [5, 17], Zimbabwe [18], and Tanzania [19] with limited information from Nigeria and perhaps West Africa. In Nigeria, although abortions and congenital malformations associated with AKAV such as arthrogryposis, kyphosis, and scoliosis have been reported in ruminants [20–22], the virus has not received adequate attention as a possible cause of these conditions. Therefore, as part of ongoing surveillance for Culicoides-borne arboviruses of livestock in Nigeria, we investigated the presence of specific antibodies against AKAV in cattle and sheep from Oyo and Ogun states, southwest Nigeria.
2. Materials and Methods
2.1. Study Area
This study was based on a cross-sectional design and conducted between May and September 2015 in Ogun and Oyo states of southwest Nigeria. The study area extended from latitudes 7°00′ to 8°00′ north and longitudes 3°35′ to 4°00′ east. Sera were collected in Oyo state from 184 head of trade cattle at the central municipal abattoirs in Bodija and Ogbomoso and a privately owned farm at Ido where they were kept semi-intensively. Cattle slaughtered at the abattoirs are sourced mainly from the northern part of the country and neighbouring countries, where they were reared on free-range management system that exposes them to insect vectors. Also, 184 sera were collected from semi-intensively reared sheep from farms and backyard flocks in Akinyele, Egbeda, Ido, Ibadan North, and Ona-Ara in Oyo state as well as from Imeko and Odeda in Ogun state. The semi-intensively managed cattle and sheep were allowed to graze on pastures during the day and kept indoors at night. However, the animal houses were not insect-proof.
2.2. Sample Collection
Blood (about 5 mL) was collected at slaughter from abattoir cattle while farm cattle and sheep were bled via the jugular vein into sterile plain bottles without anticoagulant. The blood was allowed to clot at room temperature after which sera were decanted into sterile Eppendorf tubes and stored at −20°C until tested.
2.3. Detection of AKAV Antibodies by Competitive ELISA
All the collected sera were analyzed using a commercially available ID Screen® competition ELISA kit (IDvet, Montpellier, France) that detects anti-G1 antibodies directed against AKAV in ruminant serum and plasma. The test, which was reported by the manufacturer to lack cross-reactivity with other viruses in the Bunyaviridae family, such as Schmallenberg virus (SBV), Rift Valley fever virus (RVFV), and Aino virus, and to have a high (96.52%) correlation with the VNT, was performed according to the kit protocol. For each sample, results were expressed as sample/negative percentage (S/N%) using the optical densities (OD) from the ELISA reader: S/N% = ODsample/ODnegative control × 100. Samples that presented S/N% lower than 30%, between 30% and 40%, and >40% were considered positive, doubtful, and negative, respectively.
2.4. Statistical Analysis
Results of serology were analyzed using the statistical package GraphPad Prism version 5.01 (San Diego, USA). Differences in AKAV antibody seroprevalence between cattle and sheep, abattoir and farm cattle, and male and female animals were evaluated using chi-square (χ 2) test. Furthermore, seroprevalence results based on breed, age group, and location were subjected to one-way ANOVA and subsequently to Tukey's posttest for performing multiple comparisons in order to assess statistically significant differences between all possible pairs of groups. The level of statistical significance was P < 0.05.
3. Results
Out of 184 sheep sera tested, 8 (4.4%), 22 (12.0%), and 154 (83.7%) were positive, doubtful, and negative, respectively, for AKAV anti-G1 antibodies while, of the 184 cattle sera tested, 129 (70.1%), 37 (20.1%), and 18 (9.8%) were positive, doubtful, and negative, respectively (Table 1). The prevalence of AKAV antibodies was significantly (P < 0.005) higher in abattoir cattle compared to farm cattle (Table 2). For the abattoir cattle, AKAV antibody prevalence was significantly higher in Bodija central abattoir compared to the Ogbomosho abattoir. Overall, based on cattle breed, AKAV antibody prevalence was 66.4% (75/113), 77.8% (28/36), 75.0% (3/4), 83.3% (10/12), and 76.5% (13/17) for White Fulani, Sokoto Gudali, Kuri, Red Bororo, and crossbreeds, respectively. However, comparison of the AKAV seroprevalence rates in sheep based on age, sex, breed, and location of sample collection revealed no significant differences.
Table 1.
Prevalence of AKAV antibodies in sheep and cattle in the study area.
| Number sampled | Positive (%) | Doubtful (%) | Negative (%) | |
|---|---|---|---|---|
| Sheep | 184 | 8 (4.4) | 22 (12.0) | 154 (83.7) |
| Cattle | 184 | 129 (70.1)∗ | 37 (20.1) | 18 (9.8) |
| Total | 364 | 137 (37.6) | 59 (16.2) | 172 (47.3) |
∗ P = 0.0001.
Table 2.
Seroprevalence of AKAV in cattle in the study area.
| Variable | Group | Number sampled | Positive (%) |
|---|---|---|---|
| Sex | Female | 131 | 92 (70.2) |
| Male | 53 | 37 (69.8) | |
|
| |||
| Age (years) | 0-1 | 7 | 1 (14.3)∗ |
| 2-3 | 34 | 17 (50.0) | |
| 4-5 | 121 | 92 (76.0) | |
| >5 | 22 | 19 (86.4)∗ | |
|
| |||
| Source | Abattoir | 164 | 121 (73.8)∗ |
| Farm | 20 | 8 (40.0) | |
∗ P = 0.0001.
4. Discussion
Akabane virus has been shown to be an important pathogen causing abortions and congenital malformations in ruminants [23]. Antibodies to this Culicoides-borne, Simbu serogroup virus have been found in ruminants from countries of Australia, Asia, Southeast Asia, the Middle East, and Africa [6, 10, 16, 24, 25]. However, since the initial isolation of Simbu group viruses from cattle and Culicoides biting midges in Nigeria [26, 27], there has been no report on the presence of AKAV in Nigeria. In the present study, which is part of ongoing surveillance for Culicoides-borne arboviruses in Nigeria [28, 29], AKAV antibody prevalence of 70.1% and 4.3%, respectively, was obtained for cattle and sheep in two states (Ogun and Oyo) of southwest Nigeria using a competition ELISA. According to the internal validation report of the kit manufacturer on the assay, known SBV-, RVFV-, and Aino virus-positive sera produced negative results with the AKAV ELISA kit, demonstrating the absence of cross-reactions with antisera against these viruses. To our knowledge, this is the first report of AKAV antibody-positive animals in Nigeria. As AKAV vaccines are currently not administered to livestock in the country, the detection of seropositive cattle and sheep in this study suggests natural exposure of these animals to AKAV. The higher seroprevalence obtained for cattle, which is similar to the findings of a recent study in Sudan [16], is an indication that they were more likely to be infected with AKAV than sheep. This possibility is buttressed by the knowledge that cattle are allowed to graze more extensively, thus making them more exposed to the Culicoides vectors of AKAV than sheep. Moreover, it has previously been reported [30] that some Culicoides species have distinct feeding preference for cattle over sheep even when kept in the same vicinity.
Furthermore, it was observed in this study that AKAV antibodies were more prevalent in trade cattle from abattoirs than in farm cattle. This higher seroprevalence may be due to the fact that, compared to farm cattle which are domiciled in one location, trade cattle for slaughter at these abattoirs are sourced from different parts of Nigeria and neighbouring countries where they are kept mostly on free-range. This makes the abattoirs convergence points for animals from diverse geographical locations where they could have had contact with infected Culicoides vectors. Since there is unregulated transborder movement of ruminants from neighbouring West African countries into Nigeria, it is possible that some of the seropositive cattle could have imported the disease into the country. Also, the detection of seropositive animals among trade cattle of different breeds suggests that the disease is not breed-restricted.
Previous reports of congenital malformations in cattle and sheep in Nigeria suggested that these defects have no clearly established cause [20–22, 31]. However, the increased prevalence of AKAV antibodies observed with increasing age of cattle and sheep in this study (Table 2) suggests AKAV as a possible cause of these conditions. Since it has been reported that inapparent Akabane infection in adults can lead to abortions, stillbirth, and congenital defects in newborns [10, 32], this finding suggests that AKAV may significantly increase abortion risk among adult cattle and sheep, thus constituting a potential health risk to the animals. Therefore, the findings of this study corroborate the fact that AKAV is endemic in sub-Saharan Africa and underscore the need for large-scale surveillance of the virus in Nigeria in order to establish its role as a possible cause of economic losses in ruminants through abortions, stillbirths, and congenital malformations and develop effective prevention and control strategies. Additionally, virus isolation and genetic characterization of isolates will be essential for understanding the molecular epidemiology and evolution of AKAV in Nigeria.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
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