AI Article Synopsis
- Bovine trichomonosis (BT) is a disease caused by the protozoan Tritrichomonas foetus, leading to infertility and economic losses in cattle due to its effects on the urogenital tract.
- Researchers isolated and performed proteomic profiling on six Tf isolates, identifying 662 proteins, with 121 common across all isolates and significant portions being uncharacterized.
- Immunoassays demonstrated the antigenic potential of the supernatant proteins, notably highlighting Grp78 and Ap65, potentially aiding in developing new diagnostics and treatments for BT.
Article Abstract
Bovine trichomonosis (BT), a disease of the bovine urogenital tract, is caused by the protozoan Tritrichomonas foetus (Tf). Tf causes endometritis, infertility, and premature death of the embryo, which generates considerable economic losses. The proteins released can mediate fundamental interactions between the pathogen and the host, triggering factors associated with the symptomatology, immune evasion and pathogenesis characteristic of the species. However, little is known about the profile of the proteins released by Tf. In order to contribute to their knowledge, we performed an isolation protocol and a proteomic profiling of the supernatant (SN) content of six Tf isolates. A total of 662 proteins present in the SN of Tf were detected, out of which 121 were shared by the six isolates, while the remaining 541 were found in at least one of the isolates studied. The comparative analyses using the databases of Tf strain genome K revealed 32.9% of uncharacterized proteins. The bioinformatic analyses showed that the main molecular functions predicted were binding (47.9%) and catalytic activity (38.2%). Additionally, we performed immunodetection assays to evidence the antigenic potential of SN proteins. Interestingly, we observed great ability to detect SN proteins from all six isolates using serum from immunized mice and infected bulls. A complementary mass spectrometry assay allowed us to determine that the proteins that showed the strongest signal intensity in the immunoassays were Grp78 (A0A1J4IZS3) and Ap65 (A0A1J4JSR1). This work represents the first proteomic characterization of Tf SN proteins and their antigenic potential, which might be interesting for the future design of new diagnosis and treatment methods for BT.
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| http://dx.doi.org/10.1016/j.vetpar.2023.109890 | DOI Listing |
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