Model Organisms: The Unholy Trinity: Crithidia fasciculata as a model for Kinetoplastid research by Cameron Jack Stockwell

This article was written by Scientist Cameron Jack Stockwell, PhD Candidate, Leeds Beckett University

Image 1 of T. brucei. (Credit: DPDx, CDC)

African Trypanosomiasis (sleeping sickness) is a disease caused by parasites. It is characterised by rash, enlarged lymph nodes, malaise and neurological problems caused by invasion of the central nervous system. Infections are caused by Trypanosoma brucei rhodesiense, which can kill within months, and T. b. gambiense which often kills within 3 years of infection. Currently there exists no cure for the diseases.

The parasites are transmitted through the bite of the Tsetse fly when it takes  blood meal and are difficult to treat due to their ability to hide within the skin but remain undetected in blood serum samples.

Another parasite related to T. brucei is Leishmania which causes Leishmaniasis.  Visceral leishmaniasis has up to 90,000 new cases a year and is fatal when untreated. Disease is characterised by fever, rapid weight loss, and swelling of the liver and spleen. One form of the disease causes lifelong scars and destruction of nasal, mouth and throat membranes. Although Leishmania is treatable, more effective treatments are still required.

Due to the infective and deadly nature of these organisms, non-human infective model organisms are often employed in research. Often, a parasite of mosquitos, Crithidia fasciculata that is closely related to both Leishmania and T. brucei is used to investigate the effects of novel drugs, DNA repair and the roles of proteins within the organism. Like T. brucei and Leishmania, Crithidia is a Kinetoplastid organism, named so due to the presence of a kinetoplast, the bundle of DNA, that sits within the mitochondrion.

Crithidia is much easier and cheaper to culture than Trypanosoma and Leishmania. The low cost is highly advantageous to smaller research groups and those testing a large range of new drugs. As it does not infect humans it is safer too, requiring Biosafety Level 1 or 2 compared to the more specialised level 3 labs used for parasitic Trypanosome research. The increased accessibility is great for research institutes that cannot facilitate specialist labs or expensive specialised equipment that is required for research.  The close biochemical and genetic relationships of the parasites mentioned make Crithidia an ideal model for investigation into mitochondrial DNA and repair mechanisms used within the Kinetoplastid parasites.

Although Crithidia is non-human infective and lacks many features that allow Trypanosoma and Leishmania to strive within humans, many other biochemical pathways are present. The low costs associated with the organism make it ideal for preliminary research and gives a faster throughput due to short generation times associated with it.

Image 2: Fluorescent images of C. fasciculata. (Credit: Cameron Jack Stockwell)

Cameron J. Stockwell

Several systems have already been developed to use C. fasciculata as a model organism. DNA vectors such as pNUS, have been produced to allow effective fluorescence analysis of proteins present within the organism. As the full genome is also sequenced, the study of Kinetoplastid genes is quicker in Crithidia than in its parasitic cousins as well. The use of Crithidia as a model organism is growing, and more advanced techniques are being continually developed.

Cameron is a PhD candidate in virology at Leeds Beckett University who has previously worked with Crithidia fasiculata. He can be found @ScienceManCam on twitter.

Sources & further reading:

https://link.springer.com/article/10.1007/s00415-019-09425-7

https://www.cdc.gov/parasites/sleepingsickness/diagnosis.html

https://research-repository.st-andrews.ac.uk/handle/10023/12217