New Haplotypes of Trypanosoma evansi Identified in Dromedary Camels from Algeria

The one-humped camel: The animal of future, potential alternative red meat, technological suitability and future perspectives

The 2020 world population data sheet indicates that world population is projected to increase from 7.8 billion in 2020 to 9.9 billion by 2050 (Increase of more than 25%). Due to the expected growth in human population, the demand for meats that could improve health status and provide therapeutic benefits is also projected to rise. The dromedary also known as the Arabian camel, or one-humped camel ( Camelus dromedarius), a pseudo ruminant adapted to arid climates, has physiological, biological and metabolic characteristics which give it a legendary reputation for surviving in the extreme conditions of desert environments considered restrictive for other ruminants. Camel meat is an ethnic food consumed across the arid regions of Middle East, North-East Africa, Australia and China. For these medicinal and nutritional benefits, camel meat can be a great option for sustainable meat worldwide supply. A considerable amount of literature has been published on technological aspects and quality properties of beef, lamb and pork but the information available on the technological aspects of the meat of the one humped camel is very limited. Camels are usually raised in less developed countries and their meat is as nutritionally good as any other traditional meat source. Its quality also depends on the breed, sex, age, breeding conditions and type of muscle consumed. A compilation of existing literature related to new technological advances in packaging, shelf-life and quality of camel meat has not been reviewed to the best of our knowledge. Therefore, this review attempts to explore the nutritional composition, health benefits of camel meat, as well as various technological and processing interventions to improve its quality and consumer acceptance. This review will be helpful for camel sector and highlight the potential for global marketability of camel meat and to generate value added products.

Assessment of genetic diversity of Trypanosoma evansi in the domestic animal populations through ITS-1 gene sequence analysis

Trypanosoma evansi infects domestic animals, causing a debilitating and occasionally fatal disease. The disease leads to significant economic losses to farmers and poses a substantial impediment to the growth of livestock production in developing nations, including India. Considering the challenges associated with managing this infection, there is an urgent need to enhance our understanding of the molecular and genetic diversity of T. evansi. Therefore, this study was planned to analyze the genetic diversity of T. evansi using available internal transcribed spacer-1 (ITS-1) gene sequences from India and compare them with sequences from around the globe. Blood samples used in this study were collected from naturally infected animals including dogs, cattle, and buffaloes in the Indian state of Madhya Pradesh. Using the ITS-1 gene, we amplified a 540 base pairs (bp) segment using polymerase chain reaction (PCR), sequenced it, and identified intra-specific variations. Phylogenetic analysis of 90 sequences, including 27 from India, revealed three distinct clusters with high bootstrap support values. A haplotype network analysis identified 34 haplotypes, with H7 being the most prevalent, indicating a complex evolutionary history involving multiple countries. The genetic analysis of the Indian population revealed distinct characteristics. Despite low nucleotide diversity, there was high haplotype diversity in comparison to other populations. Tajima's D, Fu and Li's D, and Fu and Li's F exhibited non-significant negative values, indicating potential stability. Additionally, the slightly positive values in Fu's Fs, Raggedness (r), and Ramos-Onsins and Rozas (R2) statistics suggested a lack of recent significant selective pressures or population expansions. Furthermore, the presence of genetic differentiation and gene flow among T. evansi populations highlighted ongoing evolutionary processes. These findings collectively depicted a complex genetic landscape, suggesting both stability and ongoing evolutionary dynamics within the Indian population of T. evansi. The findings of this study are important for understanding the evolutionary history and population dynamics of T. evansi, and they may help us develop effective control strategies.

Molecular prevalence, associated risk factors and genetic characterization of Trypanosoma evansi in camels

Surra is a major infectious disease of camels being caused by Trypanosoma evansi (T. evansi) in developing countries, including Egypt. However, the identification of changes in the T. evansi prevalence in Egypt is important. In this study, the prevalence of T. evansi and its associated risk factors as well as the genetic characterization of the parasite were estimated. Blood samples were collected from 163 camels from two governorates in Lower Egypt. PCR targeting RoTat 1.2VSG was used for the detection of T. evansi and internal transcribed spacer 1 (ITS-1) was used for sequencing analysis and genetic characterization. Overall prevalence was 19.6% using RoTat 1.2VSG. The risk of the infection in females was 4 times higher than in males (P = 0.0004, OR = 4; 95% CI = 0.79-8.96) and in camels with a history of clinical signs it was 2.3 times higher than camels without clinical signs (P = 0.04, OR = 2.3, 95% CI = 1.035-5.15). Analysis of the ITS-1 sequences of four T. evansi isolates showed little heterogeneity compared to similar sequences in the database. Sequence and phylogenetic analysis, based on the ITS-1 region, confirmed the presence of two distinct genotypes of T. evansi in Egyptian camels with more than 99% similarity with T. evansi isolates from different countries across the ITS-1 region and were closely related to Filipino and Chinese isolates. The results of the study can be used for the observation and prevention of disease and updating the epidemiological data.

Molecular Analysis of Trypanosome Infections in Algerian Camels

PURPOSE

Surra is an economically important livestock disease in many low- and middle-income countries, including those of Northern Africa. The disease is caused by the biting fly-transmitted subspecies Trypanosoma brucei evansi, which is very closely related to the tsetse-transmitted subspecies T. b. brucei and the sexually transmitted subspecies T. b. equiperdum. At least two phylogenetically distinct groups of T. b. evansi can be distinguished, called type A and type B. These evolved from T. b. brucei independently. The close relationships between the T. brucei subspecies and the multiple evolutionary origins of T. b. evansi pose diagnostic challenges.

METHODS

Here we use previously established and newly developed PCR assays based on nuclear and mitochondrial genetic markers to type the causative agent of recent trypanosome infections of camels in Southern Algeria.

RESULTS/CONCLUSION

We confirm that these infections have been caused by T. b. evansi type A. We also report a newly designed PCR assay specific for T. b. evansi type A that we expect will be of diagnostic use for the community.