Viral Infectious Diseases Unit, RIKEN, 2-1 Hirosawa, Wako, Saitama 351-0198, Japan; Faculty of Veterinary Medicine, Okayama University of Science, Imabari, Ehime 794-8555, Japan.
Viral Infectious Diseases Unit, RIKEN, 2-1 Hirosawa, Wako, Saitama 351-0198, Japan; Laboratory of Global Infectious Diseases Control Science, Graduate School of Agricultural and Life Sciences, The University of Tokyo, 1-1-1 Yayoi, Bunkyo-ku, Tokyo 113-8657, Japan.
J Dairy Sci. 2023 Dec;106(12):9393-9409. doi: 10.3168/jds.2023-23524. Epub 2023 Aug 23.
Bovine leukemia virus (BLV) has spread worldwide and causes serious problems in the cattle industry owing to the lack of effective treatments and vaccines. Bovine leukemia virus is transmitted via horizontal and vertical infection, and cattle with high BLV proviral load (PVL), which is a useful index for estimating disease progression and transmission risk, are considered major infectious sources within herds. The PVL strongly correlates with highly polymorphic bovine lymphocyte antigen (BoLA)-DRB3 alleles. The BoLA-DRB3*015:01 and 012:01 alleles are known susceptibility-associated markers related to high PVL, and cattle with susceptible alleles may be at a high risk of BLV transmission via direct contact with healthy cows. In contrast, the BoLA-DRB3009:02 and *014:01:01 alleles comprise resistant markers associated with the development of low PVL, and cattle with resistant alleles may be low-risk spreaders for BLV transmission and disrupt the BLV transmission chain. However, whether polymorphisms in BoLA-DRB3 are useful for BLV eradication in farms remains unknown. Here, we conducted a validation trial of the integrated BLV eradication strategy to prevent new infection by resistant cattle and actively eliminate susceptible cattle in addition to conventional BLV eradication strategies to maximally reduce the BLV prevalence and PVL using a total of 342 cattle at 4 stall-barn farms in Japan from 2017 to 2019. First, we placed the resistant milking cattle between the BLV-positive and BLV-negative milking cattle in a stall barn for 3 yr. Interestingly, the resistant cattle proved to be an effective biological barrier to successfully block the new BLV infections in the stall-barn system among all 4 farms. Concomitantly, we actively eliminated cattle with high PVL, especially susceptible cattle. Indeed, 39 of the 60 susceptible cattle (65%), 76 of the 140 neutral cattle (54%), and 20 of the 41 resistant cattle (48.8%) were culled on 4 farms for 3 years. Consequently, BLV prevalence and mean PVL decreased in all 4 farms. In particular, one farm achieved BLV-free status in May 2020. By decreasing the number of BLV-positive animals, the revenue-enhancing effect was estimated to be ¥5,839,262 ($39,292.39) for the 4 farms over 3 yr. Our results suggest that an integrated BLV eradication program utilization of resistant cattle as a biological barrier and the preferential elimination of susceptible cattle are useful for BLV infection control.
牛白血病病毒(BLV)已在全球范围内传播,由于缺乏有效治疗和疫苗,给牛养殖业造成了严重问题。BLV 通过水平和垂直感染传播,病毒前病毒载量(PVL)高的牛是牛群中的主要传染源,而病毒前病毒载量是评估疾病进展和传播风险的有用指标。BLV 强相关与高度多态性的牛淋巴细胞抗原(BoLA)-DRB3 等位基因。BoLA-DRB3*015:01 和 012:01 等位基因是与高 PVL 相关的易感性相关标记,具有易感等位基因的牛可能通过与健康奶牛直接接触而处于 BLV 高传播风险中。相比之下,BoLA-DRB3009:02 和 *014:01:01 等位基因是与低 PVL 发展相关的抗性标记,具有抗性等位基因的牛可能是 BLV 传播的低风险传播者,并破坏 BLV 传播链。然而,BoLA-DRB3 中的多态性是否对农场 BLV 的根除有用仍然未知。在这里,我们在日本的 4 个畜舍农场进行了为期 3 年的综合 BLV 根除策略验证试验,除了常规 BLV 根除策略外,该策略还旨在通过抗性奶牛预防新的感染并积极消除易感奶牛,以最大限度地降低 BLV 流行率和 PVL。首先,我们将抗性泌乳牛置于 BLV 阳性和 BLV 阴性泌乳牛之间的畜舍中,为期 3 年。有趣的是,在所有 4 个农场的畜舍系统中,抗性牛被证明是一种有效的生物屏障,可以成功阻止新的 BLV 感染。同时,我们积极淘汰 PVL 高的牛,尤其是易感牛。实际上,在 4 个农场中,3 年中共淘汰了 60 头易感牛中的 39 头(65%)、140 头中性牛中的 76 头(54%)和 41 头抗性牛中的 20 头(48.8%)。因此,所有 4 个农场的 BLV 流行率和平均 PVL 均下降。特别是,一个农场在 2020 年 5 月达到 BLV 无感染状态。通过减少 BLV 阳性动物的数量,估计 4 个农场在 3 年内的增收额为 5839262 日元(39292.39 美元)。我们的研究结果表明,综合 BLV 根除计划利用抗性牛作为生物屏障和优先消除易感牛,对 BLV 感染控制是有效的。
