Study of salivary proteome and immunoproteome of cattle tick, Rhipicephalus (Boophilus) microplus, for identification and characterization of silent antigens

Infestation with Rhipicephalus microplus, the cattle tick, causes huge economic losses to livestock. Ticks are developing resistance to acaricides that, besides this disadvantage, leave residues in meat and milk. The anti tick vaccines represent a sustainable alternative of the infestations control, but the currently available has partial and transient effects. Thus arises the need to identify new vaccine antigens. To achieve this goal, this work explores the fact that cattle exhibit contrasting phenotypes and inheritable of infestations that are specific to certain breeds. Furthermore, the level of immunity of the host affects gene transcription tick salivary gland, organ that produces proteins that mediate the parasitism. The working hypothesis is that different levels of anti tick immunity of host affect also the salivary composition of the parasite. So in ticks feeding on resistant hosts the proteins that are crucial to parasitism may be absent or deficient in their saliva, and by this the ticks do not finish your meal blood. The neutralization of these same proteins by humoral immunity can have the same effect and by this, these proteins are good vaccine antigens. So, the aim of the study was to identify new vaccine antigens in saliva from females and salivary glands of nymphs, males and females of ticks fed on resistant and susceptible hosts as well as in unfed larvae originating from eggs of females fed on these same hosts. To this, were employed sequencing approaches of new generation \"RNA-Seq\" (454) and proteomic approaches, such as differential analysis in gel (DIGE) and Western Blots (immunoproteomics) followed by sequencing mass, besides the Multidimensional Protein Identification Technology (MudPIT) to describe the proteome of the salivary glands and saliva of females. The transcriptomics analysis identified 11,676 coding sequences (CDS), many of which (3,600 CDS) contain predicted signal peptide indicative of secretion, therefore may be present in saliva and provide an important function in blood feeding. Through MudPIT, we identify 321 different salivary proteins, besides 126 proteins in DIGE and 266 proteins in immunoproteomics. Many of these proteins may be considered as potential antigens to be associated with the blood meal/ parasitism, such as proteases, nucleases, protease inhibitors, antimicrobial peptides, proteins of attachment, among Abstract Gustavo Rocha Garcia others, including proteins not yet characterized. Most of the genes encoding of these proteins are more expressed in ticks fed on susceptible hosts, especially in male ticks. Moreover, many of these proteins are not recognized by bovine sera, including sera from infested hosts, although sera from infested and resistant host to tick present the most reactivities. The overall results suggest that in protein level, the composition of saliva is also affected by the different levels of immunity of the host, besides vary with the tick life cycle. Thus, we conclude that the research strategies employed were satisfactory to identify a set of tick salivary antigens from R. microplus that represent target proteins for composing anti tick multicomponent vaccines. (AU)