Molecular investigation of Ehrlichia spp. and Anaplasma platys in domestic cats: clinical signs, hematological and biochemical alterations

Ehrlichia sp. e Anaplasma platys são micro-organismos Gram negativos, parasitos intracelulares obrigatórios, residindo em vacúolos citoplasmáticos de leucócitos e plaquetas, encontrados no sangue periférico ou em tecidos. Poucos relatos têm sido feitos sobre erliquiose e anaplasmose em gatos no Brasil, os quais são baseados na presença de mórulas em leucócitos e plaquetas, ou pela detecção de anticorpos. O objetivo deste trabalho foi investigar a infecção natural por Ehrlichia sp. e A.platys em gatos no Município de Campos dos Goytacazes-RJ, através da hematoscopia e pela detecção do DNA desses agentes. Foram utilizadas amostras de sangue total e de soro de 91 gatos, independente de raça, sexo e idade. Realizaram-se hemograma, bioquímica sérica e PCR, utilizando oligonucleotídes para Ehrlichia sp. e A.platys. Os dados de hematoscopia mostraram que 9,89% dos gatos apresentaram mórulas em macroplaquetas. O DNA de A.platys foi detectado em 13,18% dos 91 animais e em 44,44% das amostras positivas à hematoscopia. O DNA de Ehrlichia sp. não foi detectado em nenhuma amostra. Nenhuma alteração foi observada nos sinais clínicos nem nos resultados laboratoriais nos animais estudados. Os dados sugerem que os felinos domésticos podem atuar como potenciais reservatórios para A. platys, como forma não sintomática das enfermidades relacionadasEhrlichia sp. and Anaplasma platys are Gram-negative micro-organisms, obligate intracellular parasites, residing in cytoplasmic vacuoles of leukocytes and platelets, found in peripheral blood or tissue. Few reports have been made about ehrlichiosis and anaplasmosis in cats in Brazil, which are based on the presence of morulae in leukocytes and platelets, or by detecting antibodies. The objective of this study was to investigate the natural infection with Ehrlichia sp. and A. platys in cats in Campos dos Goytacazes-RJ, by hematoscopia and DNA detection of these agents. Samples of whole blood and serum from 91 cats, regardless of race, gender and age. Blood count, serum biochemistry and PCR using primers for Ehrlichia sp. and A. platys were perfomed. Data from hematoscopia showed 9.89% of morulae only in platelets. The DNA of A. platys was detected in 13.18% of the 91 samples and 44.44% of the positive at hematoscopia. The DNA of Ehrlichia sp. was not detected in any sample. All animals studied did not show clinical signs neither positive laboratory results. The data suggest that domestic cats can serve as potential reservoirs for A. platys as asymptomatic form of related disease

Carbohydrate metabolic compensation coupled to high tolerance to oxidative stress in ticks

Abstract Reactive oxygen species (ROS) are natural byproducts of metabolism that have toxic effects well documented in mammals. In hematophagous arthropods, however, these processes are not largely understood. Here, we describe that Rhipicephalus microplus ticks and embryonic cell line (BME26) employ an adaptive metabolic compensation mechanism that confers tolerance to hydrogen peroxide (H2O2) at concentrations too high for others organisms. Tick survival and reproduction are not affected by H2O2 exposure, while BME26 cells morphology was only mildly altered by the treatment. Furthermore, H2O2-tolerant BME26 cells maintained their proliferative capacity unchanged. We evaluated several genes involved in gluconeogenesis, glycolysis, and pentose phosphate pathway, major pathways for carbohydrate catabolism and anabolism, describing a metabolic mechanism that explains such tolerance. Genetic and catalytic control of the genes and enzymes associated with these pathways are modulated by glucose uptake and energy resource availability. Transient increase in ROS levels, oxygen consumption, and ROS-scavenger enzymes, as well as decreased mitochondrial superoxide levels, were indicative of cell adaptation to high H2O2 exposure, and suggested a tolerance strategy developed by BME26 cells to cope with oxidative stress. Moreover, NADPH levels increased upon H2O2 challenge, and this phenomenon was sustained mainly by G6PDH activity. Interestingly, G6PDH knockdown in BME26 cells did not impair H2O2 tolerance, but generated an increase in NADP-ICDH transcription. In agreement with the hypothesis of a compensatory NADPH production in these cells, NADP-ICDH knockdown increased G6PDH relative transcript level. The present study unveils the first metabolic evidence of an adaptive mechanism to cope with high H2O2 exposure and maintain redox balance in ticks