Center for Marine Environmental Studies (CMES), Ehime University, Matsuyama, Ehime 790-8577, Japan; Graduate School of Science and Engineering, Ehime University, Matsuyama, Ehime 790-8577, Japan.
Graduate School of Health Sciences, Niigata University, Niigata 951-8518, Japan.
Infect Genet Evol. 2021 Oct;94:104999. doi: 10.1016/j.meegid.2021.104999. Epub 2021 Jul 10.
Ixodid ticks (Acari:Ixodidae) are essential vectors of tick-borne diseases in Japan. In this study, we characterized the population genetic structure and inferred genetic divergence in two widespread and abundant ixodid species, Ixodes ovatus and Haemaphysalis flava. Our hypothesis was that genetic divergence would be high in I. ovatus because of the low mobility of their small rodent hosts of immature I. ovatus would limit their gene flow compared to more mobile avian hosts of immature H. flava. We collected 320 adult I. ovatus from 29 locations and 223 adult H. flava from 17 locations across Niigata Prefecture, Japan, and investigated their genetic structure using DNA sequences from fragments of two mitochondrial gene regions, cox1 and the 16S rRNA gene. For I. ovatus, pairwise F and analysis of molecular variance (AMOVA) analyses of cox1 and 16S sequences indicated significant genetic variation among populations, whereas both markers showed non-significant genetic variation among locations for H. flava. A cox1 gene tree and haplotype network revealed three genetic groups of I. ovatus. One of these groups consisted of haplotypes distributed at lower altitudes (251-471 m.a.s.l.). The cox1 sequences of I. ovatus from Japan clustered separately from I. ovatus sequences reported from China, suggesting the potential for cryptic species in Japan. Our results support our hypothesis and suggest that the host preference of ticks at the immature stage may influence the genetic structure of the ticks. This information may be important for understanding the tick-host interactions in the field to better understand the tick-borne disease transmission and in designing an effective tick control program.
硬蜱(蜱螨目:硬蜱科)是日本蜱传疾病的重要媒介。在这项研究中,我们对两种广泛且丰富的硬蜱物种,即日本璃眼蜱和全沟硬蜱的种群遗传结构和遗传分化进行了特征描述。我们的假设是,由于未成熟的日本璃眼蜱的小型啮齿动物宿主移动性低,其基因流动将受到限制,而未成熟的全沟硬蜱的鸟类宿主移动性较高,因此日本璃眼蜱的遗传分化程度会较高。我们在日本新潟县的 29 个地点采集了 320 只成年日本璃眼蜱,在 17 个地点采集了 223 只成年全沟硬蜱,并使用来自两个线粒体基因区域(cox1 和 16S rRNA 基因)片段的 DNA 序列调查了它们的遗传结构。对于日本璃眼蜱,cox1 和 16S 序列的成对 Fst 分析和分子方差分析(AMOVA)表明种群间存在显著的遗传变异,而两个标记均表明全沟硬蜱的种群间不存在显著的遗传变异。cox1 基因树和单倍型网络揭示了日本璃眼蜱的三个遗传群体。其中一个群体由分布在较低海拔(251-471 米)的单倍型组成。来自日本的日本璃眼蜱的 cox1 序列与来自中国的日本璃眼蜱序列聚类分开,表明日本可能存在隐存种。我们的结果支持我们的假设,并表明蜱在未成熟阶段的宿主偏好可能影响蜱的遗传结构。这些信息对于理解现场中的蜱-宿主相互作用、更好地了解蜱传疾病的传播以及设计有效的蜱控制计划可能很重要。
