Vertical transmission of Trypanosoma evansi in dromedary camels and studies on fetal pathology, diagnosis and treatment.

In the present study, a total of 14 (73.68%) cases of abortions and two (100%) cases of still births were detected positive for Trypanosoma evansi infection by wet and dry blood smear examination and fetal tissue PCR in camels of an organized farm. The abortions in infected dams were recorded from 8 to 11.5 month of gestation, however majority occurred during 9th to 10th month. The important laboratorial findings in infected dams were anemia, hypoglycemia, hyperproteinemia and leukocytosis. At necropsy the T. evansi infected aborted and still born fetuses showed subcutaneous edema, presence of moderate amount of dark red hemolysed blood in thoracic and abdominal cavity, bronchopneumonia, hepatic necrosis and acute congestion in all vital organs. Microscopically, there was severe congestion, thickening of bronchial and alveolar wall and mononuclear infiltration in the fetal lung, necrotic and degenerative changes in the liver, nephritis along with severe congestion and tubular necrosis in the kidneys and necrotic and degenerative changes and congestion of capillaries in the brain. The T. evansi DNA was detected by PCR from blood, lung, spleen, liver, kidney and brain of all the infected aborted and still born fetuses. The results of the study indicated that T. evansi can cross placental barrier and cause pathological events in the fetus resulting into abortion or still birth in pregnant camels.

Molecular analysis of the bacterial microbiome in the forestomach fluid from the dromedary camel (Camelus dromedarius).

Rumen microorganisms play an important role in ruminant digestion and absorption of nutrients and have great potential applications in the field of rumen adjusting, food fermentation and biomass utilization etc. In order to investigate the composition of microorganisms in the rumen of camel (Camelus dromedarius), this study delves in the microbial diversity by culture-independent approach. It includes comparison of rumen samples investigated in the present study to other currently available metagenomes to reveal potential differences in rumen microbial systems. Pyrosequencing based metagenomics was applied to analyze phylogenetic and metabolic profiles by MG-RAST, a web based tool. Pyrosequencing of camel rumen sample yielded 8,979,755 nucleotides assembled to 41,905 sequence reads with an average read length of 214 nucleotides. Taxonomic analysis of metagenomic reads indicated Bacteroidetes (55.5 %), Firmicutes (22.7 %) and Proteobacteria (9.2 %) phyla as predominant camel rumen taxa. At a finer phylogenetic resolution, Bacteroides species dominated the camel rumen metagenome. Functional analysis revealed that clustering-based subsystem and carbohydrate metabolism were the most abundant SEED subsystem representing 17 and 13 % of camel metagenome, respectively. A high taxonomic and functional similarity of camel rumen was found with the cow metagenome which is not surprising given the fact that both are mammalian herbivores with similar digestive tract structures and functions. Combined pyrosequencing approach and subsystems-based annotations available in the SEED database allowed us access to understand the metabolic potential of these microbiomes. Altogether, these data suggest that agricultural and animal husbandry practices can impose significant selective pressures on the rumen microbiota regardless of rumen type. The present study provides a baseline for understanding the complexity of camel rumen microbial ecology while also highlighting striking similarities and differences when compared to other animal gastrointestinal environments.