Trypanosoma vivax Adhesion to Red Blood Cells in Experimentally Infected Sheep

Trypanosomosis, a globally occurring parasitic disease, poses as a major obstacle to livestock production in tropical and subtropical regions resulting in tangible economic losses. In Latin America including Venezuela, trypanosomosis of ruminants is mainly caused by Trypanosoma vivax. Biologically active substances produced from trypanosomes, as well as host-trypanosome cellular interactions, contribute to the pathogenesis of anemia in an infection. The aim of this study was to examine with a scanning electron microscope the cellular interactions and alterations in ovine red blood cells (RBC) experimentally infected with T. vivax. Ovine infection resulted in changes of RBC shape as well as the formation of surface holes or vesicles. A frequent observation was the adhesion to the ovine RBC by the trypanosome's free flagellum, cell body, or attached flagellum in a process mediated by the filopodia emission from the trypanosome surface. The observed RBC alterations are caused by mechanical and biochemical damage from host-parasite interactions occurring in the bloodstream. The altered erythrocytes are prone to mononuclear phagocytic removal contributing to the hematocrit decrease during infection.This research was supported by Project G-98003462-Fondo Nacional de Ciencia, Tecnología e Innovación (FONACIT), Caracas, Venezuela, and the Instituto de Estudios Científicos y Tecnológicos from Universidad Nacional Experimental Simón Rodríguez. The authors thank Beatriz Cajade for critical reading of this paper.S

Clonación, expresión y evaluación inmunológica de la proteína Omp31 de Brucella melitensis y evaluación de su posible uso para el diagnóstico en brucelosis bovina

The serological diagnosis of brucellosis is carried out by the detection of antibodies generated against the liposaccharide «LPS» or bacterial extracts of whole cells by ELISA or agglutination tests. The objective of this study was to evaluate a recombinant protein that can be used in the serological diagnosis of bovine brucellosis. The Omp31 gene of Brucella melitensis 16M was chosen. The gene was cloned from DNA of B. melitensis; the expression of the Omp31r protein was performed in a prokaryotic expression system using the pET28a vector and purification by metal affinity chromatography (IMAC). An indirect ELISA was standardized using control sera from positive and negative bovines. The Omp31r protein reacted with the positive control sera and succeeded in discriminating against the negative sera. The sensitivity and specificity of the ELISA assay was 77.2% and 90.6%, respectively. This indirect ELISA system can be useful for the rapid diagnosis of large numbers of samples in the diagnosis of bovine brucellosis.El diagnóstico serológico de la brucelosis se lleva a cabo por la detección de anticuerpos generados contra el liposacárido “LPS” o extractos bacterianos de células enteras por ELISA o pruebas de aglutinación. El objetivo del trabajo fue evaluar una proteína recombinante que pueda ser usada en el diagnóstico serológico de la brucelosis bovina. Se escogió el gen de la Omp31 de Brucella melitensis 16M. El gen fue clonado a partir de ADN de B. melitensis. La expresión de la proteína Omp31r se realizó en un sistema de expresión procariota utilizando el vector pET28a y la purificación por cromatografía de afinidad a metales (IMAC). Un ELISA indirecto fue estandarizado utilizando sueros controles de bovinos positivos y negativos. La proteína Omp31r reaccionó con los sueros controles positivos y logró discriminarlos frente a los sueros negativos. La sensibilidad y especificidad del ensayo de ELISA fue de 77.2% y de 90.6%, respectivamente. Este sistema de ELISA indirecto puede ser útil para los diagnósticos rápidos de grandes números de muestras en el diagnóstico de la brucelosis bovina

Molecular identification of Trypanosoma theileri (Laveran, 1902) in cattle from two slaughterhouses in Ecuador and its relation with other haemotropic agents.

peer reviewedTrypanosoma theileri is a worldwide distributed haemoparasite that has been reported throughout the American continent in various species, including bovines, buffaloes and bats. In bovines, high incidence of T. theileri can be harmful when associated with other infections or under stress situations. There is little information on this hemoflagellate in Ecuador, which prompted the study and molecular identification of the trypanosomes collected in two slaughtering centers. Between February and April 2021, a total of 218 samples of bovine blood were collected in abattoirs located in the Andean region of Quito (n = 83) and in the coastal region, in Santo Domingo (n = 135). Quito public Slaughterhouse is the biggest in Ecuador, and for that, they receive animals from all country; on the other hand, Santo Domingo's Slaughterhouse is a small one where mainly females from the region are sacrificed and some males. The samples were evaluated using two molecular tests, the PCR cathepsin L-like (CatL) specific for T. theileri and for the positive samples, a Nested PCR that targets the ITS of the 18S gene. The corresponding PCR products were sequenced, analyzed by BLAST/NCBI and the sequences were used to build a concatenated phylogenetic tree, using the MEGA XI software. Overall, 34 out of the 218 samples, (15.6%) were positive to T. theileri by PCR CatL, resulting from 20/83 (24.1%) positives from the Quito abattoir and 14/135 (10.4%) from the Santo Domingo slaughterhouse. These prevalence rates were found to be significantly different (p = 0.006). According to the phylogenetic tree based on the CatL and ITS concatenated sequences (n = 13), the two novel Equatorial T. theileri isolates, ThI (n = 7) and ThII (n = 6) are closely related and associated to the IC, IB and IIB genotypes, present in Brazil, Venezuela and Colombia. Thirty-one out of the thirty-four T. theileri-positive bovines were co-infected with other haemotropic pathogens, Anaplasma marginale Babesia spp and T. vivax. This coinfection could be responsible for additional pathologies and harmful effects on the affected cattle. This study presents the molecular identification and genotypification of T. theileri isolated from cattle in Ecuador through the analysis of CAtL and ITS sequences, and the high frequency of coinfection of this hemoflagellate with other blood haemotropic organisms

Detection of Babesia spp. in High Altitude Cattle in Ecuador, Possible Evidence of the Adaptation of Vectors and Diseases to New Climatic Conditions

Background: Babesia species are intraerythrocytic protozoa, distributed in tropical and subtropical areas of the world, causing anemic diseases in many animals, including cattle. This disease, called babesisosis, is transmitted from one animal to another through ticks (Tick Borne-Disease or TBD). On the other hand, Ecuador has a tropical climate that allows the development of the vector Rhipicephalus microplus, and therefore favors the transmission of Babesia spp. in cattle. Methods and principal findings: We determined the presence of Babesia spp. by PCR using 18s ribosomal gene as target (18s PCR) in 20 farms in the area of El Carmen (zone below 300 m above sea level) and 1 farm in Quito (2469 m.a.s.l.). In addition, we analyzed parameters such as age, sex, and packed cell volume (PCV) as explanatory variable associated with the disease. Results: The 18s PCR test showed that 18.94% (14.77% Babesia bovis and 4.17% Babesia bigemina) and 20.28% (14.69% B. bovis and 5.59% B. bigemina) of the cattle were positive for Babesia spp in farms sampled in El Carmen and in Quito, respectively. Age influenced the presence of animals positive for Babesia spp., but sex and PCV did not. The phylogenetic analysis of sequences showed 4 isolates of B. bovis and 3 isolates of B. bigemina in the 2 study zones, with similarities between 99.73 and 100% with other sequences. One B. bovis isolate was similar in the zone of El Carmen and Quito. Conclusion and significance: This work is the first molecular characterization of B. bigemina and B. bovis in Ecuador, and it is also the first evidence of Babesia spp. in cattle in the area of Quito at an altitude of 2469 m.a.s.l., being the highest altitude reported for animals with babesiosis and for the tick R. microplus. Climatic factors as well as mobility of tick-carrying animals without any control allow the presence of Babesiosis outbreaks in new geographical areas

MECANISMOS DE VARIACIÓN ANTIGÉNICA EN Anaplasma marginale

Anaplasma marginale (A. marginale), es una bacteria del orden de las Rickettsias que ocasiona la anaplasmosis bovina en regiones tropicales y subtropicales del mundo. Esta enfermedad, trasmitida principalmente por tábanos y garrapatas, se desarrolla típicamente en una etapa inicial aguda con manifestaciones clínicas caracterizadas principalmente por anemia y fiebre. Después de un par de meses, los animales  recuperan su condición física y se hacen asintomáticos, siendo incapaces de eliminar completamente la bacteria, convirtiéndose en animales persistentemente infectados. Esto se debe a la capacidad de A. marginale para evadir el sistema inmune. En este sentido, se ha demostrado la existencia de un mecanismo de variación antigénica en las proteínas MSP1, MSP2 y MSP3 de la bacteria. Al evaluar la familia multigénica que codifica para la MSP2, se determinó que está conformada por dos regiones conservadas que flanquean una región central hipervariable. De esta manera, al expresarse cada una de las 52 variables de la MSP2, se expresa un epítope diferente. Cuando se describió el genoma completo de este hemotrópico, se encontró también la presencia de 16 pseudogenes msp2, los cuales pueden ser recombinados dentro del sitio de expresión del operón de la MSP2, constituyendo un segundo mecanismo de variación. Además de ello, los fragmentos hipervaribles y los pseudogenes se pueden combinar entre sí, en un proceso denominado conversión génica, creando nuevos epítopes “recombinantes”, confiriendo una capacidad de variabilidad antigénica casi infinita al A. marginale (tercer mecanismo). Un cuarto mecanismo de variación antigénica, lo constituye la dimerización de la MSP2 sobre la superficie del A. marginale, debido a que la expresión simultánea de variantes conforman epítopes únicos. En conclusión, la recombinación génica de la MSP2 y su dimerización en la membrana, constituye un mecanismo muy eficiente de variación antigénica para eludir el sistema inmunológico del hospedador.Abstract   Anaplasma marginale (A. marginale) is a bacterium of the Rickettsiales order that causes bovine anaplasmosis in tropical and subtropical regions worldwide. This disease, mainly transmitted by ticks and horseflies, typically develops in an initial acute stage, with clinical signs characterized by anemia and fever. After two months, animals recover their original physical condition and become asymptomatic, being unable to completely eliminate the bacterium, turning into persistently infected animals. This is due to the ability of A.marginale to evade the immune system. In this regard, the existence of a mechanism for antigenic variation in proteins of the bacterium, such as MSP1, MSP2, and MSP3, has been demonstrated. When assessing the multigenic family which encodes for MSP2, it was determined that it consists of two conserved regions flanking a central hypervariable region. Thus, when expressing each of the 52 MSP2 variables, a different epitope is also expressed. When the entire genome of this parasite was decoded, the presence of 16 pseudogenes for MSP2 was also discovered. These pseudogenes can be recombined within the operon expression site of MSP2, providing a second mechanism of variation. Moreover, both the hypervariable fragments and pseudogenes can combine among them, in a process called gene conversion, creating new “recombinant” epitopes, conferring the A. marginale with an almost infinite capacity for antigenic variability (third mechanism). A fourth mechanism of antigentic variation consists of the dimerization of MSP2 on the surface of A. marginale, because the simultaneous expression of variants creates unique epitopes. In conclusion, gene recombination of MSP2 along with the dimerization of MSP2 on the membrane provides a very efficient mechanism for antigenic variation for evading the host’s immune system

Parasitological, Hematological, and Immunological Response of Experimentally Infected Sheep with Venezuelan Isolates of Trypanosoma evansi, Trypanosoma equiperdum, and Trypanosoma vivax

There are three trypanosoma species of veterinary importance in South America: (1) Trypanosoma evansi, the causative agent of derrengadera mechanically transmitted by bloodsucking insects such as tabanids, (2) Trypanosoma vivax, also mechanically transmitted by some dipteras hematophages as tabanids and/or Stomoxys, and (3) T. equiperdum, a tissue parasite adapted to sexual transmission and the causative agent of dourine, a distinctive disease that affects only Equidae. In order to evaluate the parasitological, hematological, and serological response of sheep infected with T. vivax, T. evansi, and T. equiperdum, four female sheep were experimentally infected with Venezuelan trypanosome field isolates: two T. evansi of differing virulences, one T. equiperdum; one T. vivax. Parasitemia and clinical parameters such as hematocrit, red blood cell count, hemoglobin, and body temperature were measured. T. evansi caused a chronic disease with undulant parasitemia alternating with some cryptic periods of at least 54 days, with no clinical signs. T. equiperdum, never described as infectious to ruminants, also caused a chronic disease with low undulant parasitemia. T. vivax caused an acute infection with severe anemia showing a drop of more than 70% of the hematocrit value, high fever, and rapid deterioration of physical condition, for 36 days of infection. Indirect ELISAs using crude extracts of the three species of trypanosomes as antigens were performed for detection of anti-trypanosome antibodies in sheep sera. Cross-reaction was observed between the three parasite species. These results show that sheep are susceptible to the three-trypanosome species and suggest they can act as a reservoir when sheep are raised and managed with other important livestock such as cattle, horses, buffalos, or goats. These findings are especially interesting for T. equiperdum, a species that has not been reported as infective to sheep