Relationship between acaricide resistance and acetylcholinesterase gene polymorphisms in the cattle tick Rhipicephalus microplus.

In this study, we aimed to develop a comprehensive methodology for identifying amino acid polymorphisms in acetylcholinesterase transcript 2 (AChE2) in acaricide-resistant Rhipicephalus microplus ticks. This included assessing AChE2 expression levels through qPCR and conducting 3D modeling to evaluate the interaction between acaricides and AChE2 using docking techniques. The study produced significant results, demonstrating that acaricide-resistant R. microplus ticks exhibit significantly higher levels of AChE expression than susceptible reference ticks. In terms of amino acid sequence, we identified 9 radical amino acid substitutions in AChE2 from acaricide-resistant ticks, when compared to the gene sequence of the susceptible reference strain. To further understand the implications of these substitutions, we utilized 3D acaricide-AChE2 docking modeling to examine the interaction between the acaricide and the AChE2 catalytic site. Our models suggest that these amino acid polymorphisms alter the configuration of the binding pocket, thereby contributing to differences in acaricide interactions and ultimately providing insights into the acaricide-resistance phenomenon in R. microplus.

Title: Relations entre la résistance aux acaricides et les polymorphismes du gène de l'acétylcholinestérase chez la tique du bétail Rhipicephalus microplus. Abstract: Notre étude vise à développer une méthodologie complète pour identifier les polymorphismes d'acides aminés dans le transcrit 2 de l'acétylcholinestérase (AChE2) chez les tiques Rhipicephalus microplus résistantes aux acaricides. Cela comprend l'évaluation des niveaux d'expression d'AChE2 via qPCR et la réalisation d'une modélisation 3D pour évaluer l'interaction entre les acaricides et l'AChE2 à l'aide de techniques d'amarrage moléculaire. L'étude a produit des résultats significatifs, démontrant que les tiques R. microplus résistantes aux acaricides présentent des niveaux d'expression d'AChE significativement plus élevés que les tiques sensibles de référence. En termes de séquence d'acides aminés, nous avons identifié 9 substitutions d'acides aminés dans AChE2 provenant de tiques résistantes aux acaricides par rapport à la séquence génétique de la souche sensible de référence. Pour mieux comprendre les implications de ces substitutions, nous avons utilisé la modélisation de l'amarrage acaricide-AChE2 pour examiner l'interaction entre l'acaricide et le site catalytique AChE2. Nos modèles suggèrent que ces polymorphismes d'acides aminés modifient la configuration de la poche de liaison, contribuant ainsi aux différences dans les interactions acaricides et fournissant finalement un aperçu du phénomène de résistance aux acaricides chez R. microplus.

Efficacy of Entomopathogenic Staphylococcus Bacteria as a Biocontrol Agent against Rhipicephalus microplus Ticks: Assessing Reproductive Inhibition and Mortality Rates.

Rhipicephalus microplus is a persistent ectoparasite of cattle that causes bovine anaplasmosis and babesiosis, causing economic losses worldwide. Chemical treatment is the primary method for tick control, but the emergence of pesticide-resistant ticks is a major challenge. Alternative biocontrol strategies utilizing entomopathogenic microorganisms are being explored. This study aimed to validate the species identification and assess the efficacy of four strains of Staphylococcus bacteria (S. shinii S1 and S-2, S. succinus, and S. xylosus) previously reported as being entomopathogenic to R. microplus ticks. According to the bioassays, S. shinii S-1 exhibited the greatest degree of reproductive inhibition (47%), followed by S. succinus (44.3%) at a concentration of 1 × 108 cfu/mL. S. xylosus displayed decreased reproductive inhibition (6.3%). In an additional bioassay, S. shinii S-1 exhibited a significant larval mortality of 67.63%, followed by S. succinus with 66.75%, S. shinni S-2 with 64.61%, and S. xylosus with 28.18% mortality. The common signs of infection observed on these ticks included swelling, yellowish exudate on the hypostome, and reduced limb mobility and color change, except for S. succinus, which did not cause color changes. These bacteria were naturally found on bovine skin. However, further studies are needed to confirm their potential as promising alternatives or complementary agents to existing acaricidal compounds.

A Novel Receptor Binding Progesterone, a Possible Transregulation Mechanism in the Rhipicephalus microplus-Host Interaction.

BACKGROUND: Hormone receptors exert their function through binding with their ligands, which results in cellular signaling activation mediated by genomic or non-genomic mechanisms. The intrinsic molecular communication of tick Rhipicephalus microplus and its host Bos taurus comprises an endocrine regulation involving hormones. In the present study, we performed a molecular and in silico analysis of a Membrane Associated Progesterone Receptor in R. microplus (RmMAPRC). METHODS: The RmMAPRC protein sequence was analyzed with bioinformatics tools, and its structure was characterized by three-dimensional (3D) modeling and molecular docking. A semi-quantitative reverse transcription and polymerase chain reaction (sqRT-PCR) assessed the RmMAPRC gene presence and relative expression in tick organs and embryonic cells. RESULTS: RmMAPRC relative expression in salivary glands, ovaries, and embryonic cells showed overexpression of 3%, 13%, and 24%, respectively. Bioinformatic analysis revealed that RmMAPRC corresponded to a Progesterone Receptor Membrane Component 1 (RmPGRMC1) of ~23.7 kDa, with an N-terminal transmembrane domain and a C-terminal Cytochrome b5-like heme/steroid binding domain. The docking results suggest that RmPGRMC1 could bind to progesterone (P4), some progestins, and P4 antagonists. The phylogenetic reconstruction showed that Rhipicephalus spp. MAPRC receptors were clustered in a clade that includes R. appendiculatus, R. sanguineus, and R. microplus (RmMAPRC), and mammals and helminths MAPRC receptors clustered in two separated clades away from ticks. CONCLUSIONS: The presence of RmPGRMC1 highlights the importance of transregulation as a conserved adaptive mechanism that has succeeded for arthropod parasites, making it a target for tick control.

Transcriptomic dataset of the development and maturation of the Rhipicephalus microplus ovary.

To conduct differential gene expression analysis, ovaries from the cattle tick Rhipicephalus microplus were dissected at three distinct developmental stages (preingurgitated, immature ingurgitated, and mature ingurgitated). Additionally, undissected intact mature males and complete ingurgitated female ticks without ovaries (carcasses) were also collected to serve as reference samples for analysis. To perform total RNA purification, tissue from ten individuals representing each of the five previously described conditions was pooled. mRNA was isolated from the purified total RNA using the oligo (dT) method. Following fragmentation, double stranded cDNA was synthesized and ligated to sequencing adapters. Suitable-sized fragments were subsequently used for PCR amplification. Libraries were analyzed and quantified using an Agilent 2100 Bioanalyzer and an ABI StepOnePlus Real-Time PCR System. A total of 45.64 Gb bases were sequenced using the Illumina HiSeq sequencing platform. After assembling the samples and correcting for abundance, we obtained 82,877 unigenes. The total length, average length, N50, and GC content of the unigenes were 89,754,828 bp,1,082 bp,2,068 bp and 49.04 % respectively. For functional annotation, the unigenes were aligned with 7 functional databases. The number of unigenes identified in the functional databases were as follows: 32,518 (NR:39.24 %), 10,259 (NT:12.38 %), 23,624 (Swissprot:28.50 %), 22,203 (KOG:26.79 %), 25,072 (KEGG:30.25 %), 17,435(GO:21.04 %), and 23,220 (InterPro:28.02 %). Unigene candidate coding regions (CDS) among the unigenes were predicted using TransDecoder software and 42,143 CDS were detected. We also detected 10,522 simple sequence repeats (SSRs) distributed on 8,126 unigenes, and predicted 4,672 transcription factors (TF) coding unigenes. Our data can be used to identify genes that are important for male and female tick and arachnid reproduction and tick general physiology.