Exploring the Genetic Basis of Wild Boar (Sus scrofa) and Its Connection to Classical Swine Fever Spread

IF 3.5 2区农林科学 Q2 INFECTIOUS DISEASES

Transboundary and Emerging Diseases Pub Date : 2025-05-07 DOI:10.1155/tbed/9881511

Rie Saito, Natsuko Ito Kondo, Yui Nemoto, Toshimasa Takeda, Kosuke Kanda, Nobuyoshi Nakajima, James C. Beasley, Masanori Tamaoki

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Abstract

Classical swine fever (CSF) is the one of the most devastating contagious diseases in domestic swine and wild boar/pigs (Sus scrofa). Population genetics is often used to estimate animal dispersal and can also help evaluate host population connectivity, which is crucial for understanding pathogen dispersal. We surveyed genetic population structure of boars using MIG-seq analysis to clarify the geographic barriers that influence boar dispersal in north-central Japan and to demonstrate the relationship between the spread of CSF infection among boars and their population structure. We obtained 382 single-nucleotide polymorphisms from 348 wild boar samples, and the results of STRUCTURE analysis indicated that the highest ΔK value was at K = 2, followed by K = 4. Based on these results, it is evident that the Abukuma river, a major river within north-central Japan, does not act as a barrier to the gene flow of boars, but rather that human infrastructure hinders their dispersal. Further, according to the time series change in the capture site of CSF-infected wild boar and the sum of the probability of belonging to each of the four clades in individual CSF-infected wild boar, our results indicated that the genetic structure of boar populations was correlated with the outbreak pathway of CSF across our study region. Our study suggests that predictions of disease spread, especially for widely distributed host species, is challenging because of the risk of cryptic breaks and changes in wide range connectivity; however, understanding the genetic population structure of wild boar can be a useful tool for predicting the spread of CSF. We concluded that genetic analysis of host population structure may have the possibility to improve predictions of the future dynamics of disease spread.

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探讨野猪（Sus scrofa）的遗传基础及其与猪瘟传播的关系

猪瘟（CSF）是家猪和野猪/猪（Sus scrofa）中最具破坏性的传染病之一。群体遗传学通常用于估计动物的传播，也可以帮助评估宿主群体的连通性，这对理解病原体的传播至关重要。我们使用MIG-seq分析调查了公猪的遗传群体结构，以澄清影响日本中北部公猪传播的地理障碍，并证明猪瘟感染在公猪之间的传播与其群体结构之间的关系。从348个野猪样本中获得382个单核苷酸多态性，结构分析结果表明，ΔK值在K = 2时最高，K = 4时次之。基于这些结果，很明显，日本中北部的一条主要河流Abukuma河并没有成为公猪基因流动的障碍，而是人类的基础设施阻碍了它们的扩散。此外，根据感染CSF的野猪捕获地点的时间序列变化以及个体感染CSF的野猪属于四个支系的概率之和，我们的结果表明，野猪群体的遗传结构与我们研究区域内CSF的爆发途径相关。我们的研究表明，疾病传播的预测，特别是对于广泛分布的宿主物种，是具有挑战性的，因为存在隐断的风险和大范围连通性的变化；然而，了解野猪的遗传群体结构可能是预测脑脊液传播的有用工具。我们的结论是，寄主种群结构的遗传分析可能有可能改善对未来疾病传播动态的预测。

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来源期刊

Transboundary and Emerging Diseases 农林科学-传染病学

CiteScore

8.90

自引率

9.30%

发文量

350

审稿时长

1 months

期刊介绍： Transboundary and Emerging Diseases brings together in one place the latest research on infectious diseases considered to hold the greatest economic threat to animals and humans worldwide. The journal provides a venue for global research on their diagnosis, prevention and management, and for papers on public health, pathogenesis, epidemiology, statistical modeling, diagnostics, biosecurity issues, genomics, vaccine development and rapid communication of new outbreaks. Papers should include timely research approaches using state-of-the-art technologies. The editors encourage papers adopting a science-based approach on socio-economic and environmental factors influencing the management of the bio-security threat posed by these diseases, including risk analysis and disease spread modeling. Preference will be given to communications focusing on novel science-based approaches to controlling transboundary and emerging diseases. The following topics are generally considered out-of-scope, but decisions are made on a case-by-case basis (for example, studies on cryptic wildlife populations, and those on potential species extinctions): Pathogen discovery: a common pathogen newly recognised in a specific country, or a new pathogen or genetic sequence for which there is little context about — or insights regarding — its emergence or spread. Prevalence estimation surveys and risk factor studies based on survey (rather than longitudinal) methodology, except when such studies are unique. Surveys of knowledge, attitudes and practices are within scope. Diagnostic test development if not accompanied by robust sensitivity and specificity estimation from field studies. Studies focused only on laboratory methods in which relevance to disease emergence and spread is not obvious or can not be inferred (“pure research” type studies). Narrative literature reviews which do not generate new knowledge. Systematic and scoping reviews, and meta-analyses are within scope.