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蜱虫的分子鉴定及毒素作为有效生物杀螨剂的应用

Molecular Identification of Ticks and Application of Toxins as an Effective Biological Acaricide.

作者信息

Noor Panhwer Sana, Ahmed Munir, Ansari Abdul Suboor, Gadahi Javaid Ali, Memon Shahar Bano, Tariq Mansoor, Laghari Zubair Ahmed, Soomro Feroza, Bhutto Bachal, Mari Noor-Un-Nisa, Chen Zhengli

机构信息

Department of Veterinary Parasitology Sindh Agriculture University, Tandojam, Pakistan.

Laboratory of Animal Disease Model College of Veterinary Medicine Sichuan Agricultural University, Chengdu, Sichuan 611130, China.

出版信息

J Parasitol Res. 2024 Sep 11;2024:9952738. doi: 10.1155/2024/9952738. eCollection 2024.

DOI:10.1155/2024/9952738
PMID:39296814
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11410401/
Abstract

() is considered one of the most important entomopathogenic microorganisms. It produces potent toxins against insects. Therefore, the present study investigates the bioacaricidal properties of on the tick species. Firstly, we identify ticks based on morphological screening and molecular characterization. The cytochrome C oxidase subunit I (COX1) gene was selected for the polymerase chain reaction (PCR) analysis, which resulted in the amplification of 656 bp. The amplified products were sequenced, and the isolated (COX1) gene of ticks was submitted to the gene bank of NCBI (Accession No. OR077934.1). The nucleotide sequences were retrieved from the NCBI data bank by BLASTn analysis, which confirmed that all obtained sequences belong to genus , and multiple alignments confirmed that the sequence of Tandojam-isolate (HA-TJ) 100% aligned with KP792577.1, KP792595.1, KX911989.1, and OQ449693.1. The generated phylogenetic tree confirmed that sequences of HA-TJ COX1 clustered with a single clad of , , and . The acaricidal effect of toxins spore crystal mix (SCM) and crystal proteins (cps) was evaluated against larvae and adult life stages of ticks in vitro. We applied cps and SCM separately with different concentrations and calculated the mortality percentage. Adult mortality was estimated at the 8th, 10th, 12th, and 15th days posttreatment and larval mortality after 24 h. During treatment of the adult life stage, at first, ticks were immersed in different concentrations of cps and SCM for 5 min after the treatments, and the samples were transferred to sterile containers and placed in an incubator with 80% humidity at 23°C. Furthermore, cps produced the highest mortality on Day 15, 89 ± 1.00% at a concentration of 3000 g/mL, followed by the 12th, 10th, and 8th days produced 83 ± 1.91%, 70 ± 1.15%, and 61 ± 1.00%, respectively. SCM produced mortality of 69 ± 1.91% on Day 15 at a concentration of 3000 g/mL, followed by the 12th, 10th, and 8th days at 57 ± 2.51%, 37 ± 1.91%, and 34 ± 2.00%. The present study revealed that toxins produced a significant ( < 0.05) increase in mortality rate in adults of ticks. Additionally, cps and SCM were used to treat the larval stage. The treatments were applied to calculate the mortality percentage via the Laravel packet test. At a 1500 g/mL concentration, cps resulted in the highest mortality of 98 ± 1.15%; this was followed by 1250 g/mL, 1000 g/mL, and 750 g/mL, which produced mortalities of 76 ± 1.63%, 60 ± 1.63%, and 56 ± 1.63%, respectively. In addition, SCM produced a mortality rate of 79 ± 2.51% at a concentration of 1500 g/mL. Furthermore, 75 ± 2.51%, 65 ± 1.91%, and 58 ± 1.15% mortality were observed at concentrations of 1250 g/mL, 1000 g/mL, and 750 g/mL, respectively. The results showed a significant ( < 0.05) increase in larval mortality compared to the control group. We conclude that toxins are applicable as a bioacaricide.

摘要

()被认为是最重要的昆虫病原微生物之一。它能产生针对昆虫的强效毒素。因此,本研究调查了()对(蜱种)的杀螨特性。首先,我们通过形态学筛选和分子特征鉴定(蜱种)。选择细胞色素C氧化酶亚基I(COX1)基因进行聚合酶链反应(PCR)分析,扩增出656 bp的片段。对扩增产物进行测序,并将分离得到的蜱(COX1)基因提交至NCBI基因库(登录号OR077934.1)。通过BLASTn分析从NCBI数据库中检索核苷酸序列,证实所有获得的序列均属于(属名)属,多重比对证实坦多Jam分离株(HA - TJ)的序列与KP792577.1、KP792595.1、KX911989.1和OQ449693.1 100%比对一致。生成的系统发育树证实,HA - TJ COX1的序列与(属名)属的一个单分支聚类。在体外评估了()毒素的芽孢晶体混合物(SCM)和晶体蛋白(cps)对(蜱种)幼虫和成虫阶段的杀螨效果。我们分别以不同浓度应用cps和SCM,并计算死亡率百分比。在处理后的第8天、第10天、第12天和第15天估计成虫死亡率,24小时后估计幼虫死亡率。在成虫阶段的处理中,首先,将蜱浸入不同浓度的cps和SCM中5分钟,处理后将样本转移至无菌容器中,置于湿度为80%、温度为23°C的培养箱中。此外,cps在第15天产生的死亡率最高,浓度为3000 g/mL时为89±1.00%,其次是第12天、第10天和第8天,分别为83±1.91%、70±1.15%和61±1.00%。SCM在浓度为3000 g/mL时第15天的死亡率为69±1.91%,其次是第12天、第10天和第8天,分别为57±2.51%、37±1.91%和34±2.00%。本研究表明,()毒素使(蜱种)成虫的死亡率显著(P<0.05)增加。此外,使用cps和SCM处理幼虫阶段。通过幼虫包试验应用这些处理来计算死亡率百分比。在浓度为1500 g/mL时,cps导致的死亡率最高,为98±1.15%;其次是1250 g/mL、1000 g/mL和750 g/mL,死亡率分别为76±1.63%、60±1.63%和56±1.63%。此外,SCM在浓度为1500 g/mL时的死亡率为79±2.51%。此外,在浓度为1250 g/mL、1000 g/mL和750 g/mL时观察到的死亡率分别为75±2.51%、65±1.91%和58±1.15%。结果表明,与对照组相比,幼虫死亡率显著(P<0.05)增加。我们得出结论,()毒素可作为一种杀螨剂应用。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a3a2/11410401/2da2cf88c436/JPR2024-9952738.005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a3a2/11410401/f6964cfa5635/JPR2024-9952738.006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a3a2/11410401/7749d1698326/JPR2024-9952738.007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a3a2/11410401/1cb87e05d4f7/JPR2024-9952738.008.jpg

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