The Complete Mitogenome of : Novel In-Sights into the Phylogenetics in Toxocaridae

Overview

Journal Animals (Basel)

Date 2022 Dec 23

PMID 36552470

Authors

Yue Xie

Lidan Wang

Yijun Chen

Zhao Wang

Pengchen Zhu

Zun Hu

Xinfeng Han

Zhisheng Wang

Xuan Zhou

Zhicai Zuo

Affiliations

Soon will be listed here.

Abstract

(Ascaridida: Nematoda) is one of the most common intestinal nematodes of cattle and buffalos and, therefore, represents a serious threat to their populations worldwide. Despite its significance in veterinary health the epidemiology, population genetics, and molecular ecology of this nematode remain poorly understood. The mitogenome can yield a foundation for studying these areas and assist in the surveillance and control of . Herein, the first whole mitogenome of was sequenced utilizing Illumina technology and characterized with bioinformatic pipeline analyses. The entire genome of was 15,045 bp in length and contained 12 protein-coding genes (PCGs), 22 transfer RNAs (tRNAs), and two ribosomal RNAs (rRNAs). The gene arrangement (GA) of was similar to those of other species under GA3. The whole genome showed significant levels of AT and GC skew. Comparative mitogenomics including sequence identities, Ka/Ks, and sliding window analysis, indicated a purifying selection of 12 PCGs with cox1 and nad6 having the lowest and highest evolutionary rate, respectively. Whole amino acid sequence-based phylogenetic analysis supported a novel sister-species relationship of with the congeneric species , , and in the family Toxocaridae. Further, 12 (PCGs) single gene-based phylogenies suggested that nad4 and nad6 genes shared same topological trees with that of the whole genome, suggesting that these genes were suitable as novel genetic markers for phylogenetic and evolutionary studies of Ascaridida species. This complete mitogenome of refined phylogenetic relationships in Toxocaridae and provided the resource of markers for population genetics, systematics, and epidemiology of this bovine nematode.

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