\u3ci\u3eRickettsia parkeri\u3c/i\u3e Infection Modulates the Sialome and Ovariome of the Gulf Coast Tick, \u3ci\u3eAmblyomma maculatum\u3c/i\u3e

The Gulf Coast tick, Amblyomma maculatum, is a vector of several tick-borne pathogens, including Rickettsia parkeri. The ability of R. parkeri to persist within the tick population through transovarial and transstadial transmission, without apparently harming the ticks, contributes to the pathogen’s perpetuation in the tick population. Previous studies have shown that the R. parkeri load in A. maculatum is regulated by the tick tissues’ oxidant/antioxidant balance and the non-pathogenic tick microbiome. To obtain further insights into the interaction between tick and pathogen, we performed a bulk RNA-Seq for differential transcriptomic analysis of ovaries and salivary glands from R. parkeri-infected and uninfected ticks over the feeding course on a host. The most differentially expressed functional category was of bacterial origin, exhibiting a massive overexpression of bacterial transcripts in response to the R. parkeri infection. Candidatus Midichloria mitochondrii and bacteria from the genus Rickettsia were mainly responsible for the overexpression of bacterial transcripts. Host genes were also modulated in R. parkeri-infected tick organs. A similar number of host transcripts from all analyzed functional categories was negatively and positively modulated, revealing a global alteration of the A. maculatum transcriptome in response to pathogen infection. R. parkeri infection led to an increase in salivary transcripts involved in blood feeding success as well as a decrease in ovarian immune transcripts. We hypothesize that these transcriptional alterations facilitate pathogen persistence and transmission within tick population

Antígenos de metaloprotease ou peptídeos derivados para o controle do carrapato

Universidade Federal do Rio Grande do SulCiências Básicas da SaúdeVeterináriaDepositad

Coxiella endosymbiont of Rhipicephalus microplus modulates tick physiology with a major impact in blood feeding capacity

In the past decade, metagenomics studies exploring tick microbiota have revealed widespread interactions between bacteria and arthropods, including symbiotic interactions. Functional studies showed that obligate endosymbionts contribute to tick biology, affecting reproductive fitness and molting. Understanding the molecular basis of the interaction between ticks and their mutualist endosymbionts may help to develop control methods based on microbiome manipulation. Previously, we showed that Rhipicephalus microplus larvae with reduced levels of Coxiella endosymbiont of R. microplus (CERM) were arrested at the metanymph life stage (partially engorged nymph) and did not molt into adults. In this study, we performed a transcriptomic differential analysis of the R. microplus metanymph in the presence and absence of its mutualist endosymbiont. The lack of CERM resulted in an altered expression profile of transcripts from several functional categories. Gene products such as DA-P36, protease inhibitors, metalloproteases, and evasins, which are involved in blood feeding capacity, were underexpressed in CERM-free metanymphs. Disregulation in genes related to extracellular matrix remodeling was also observed in the absence of the symbiont. Taken together, the observed alterations in gene expression may explain the blockage of development at the metanymph stage and reveal a novel physiological aspect of the symbiont-tick-vertebrate host interaction

Metabolismo energético na embriogênese do carrapato Rhipicephalus (Boophilus) Microplus

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A comparison of Illumina and PacBio methods to build tick salivary gland transcriptomes confirms large expression of lipocalins and other salivary protein families that are not represented in available tick genomes

Tick saliva helps blood feeding by its antihemostatic and immunomodulatory activities. Tick salivary gland transcriptomes (sialotranscriptomes) revealed thousands of transcripts coding for putative secreted polypeptides. Hundreds of these transcripts code for groups of similar proteins, constituting protein families, such as the lipocalins and metalloproteases. However, while many of these transcriptome-derived protein sequences matches sequences predicted by tick genome assemblies, the majority are not represented in these proteomes. The diversity of these transcriptome-derived transcripts could derive from artifacts generated during assembly of short Illumina reads or derive from polymorphisms of the genes coding for these proteins. To investigate this discrepancy, we collected salivary glands from blood-feeding ticks and, from the same homogenate, made and sequenced libraries following Illumina and PacBio protocols, with the assumption that the longer PacBio reads would reveal the sequences generated by the assembly of Illumina reads. Using both Rhipicephalus zambeziensis and Ixodes scapularis ticks, we have obtained more lipocalin transcripts from the Illumina library than the PacBio library. To verify whether these unique Illumina transcripts were real, we selected 9 uniquely Illumina-derived lipocalin transcripts from I. scapularis and attempted to obtain PCR products. These were obtained and their sequences confirmed the presence of these transcripts in the I. scapularis salivary homogenate. We further compared the predicted salivary lipocalins and metalloproteases from I. scapularis sialotranscriptomes with those found in the predicted proteomes of 3 publicly available genomes of I. scapularis. Results indicate that the discrepancy between the genome and transcriptome sequences for these salivary protein families is due to a high degree of polymorphism within these genes