Abstract
Trichuris muris, is the murine parasite and widely deployed model for the human whipworm Trichuris trichiura, a parasite that infects around 500 million people globally. Trichuriasis is a classical disease of poverty with a cycle of re-infection due to the continual exposure of humans, particularly children, to infective eggs, which contaminate the soil in endemic areas. Indeed, modelling studies of trichuriasis have demonstrated that the low efficacy rate of current anthelmintics combined with the high possibility of re-infection from the reservoir of infective eggs within the environment, mean that the elimination of morbidity due to trichuriasis is unlikely to occur. Despite the importance of the infective egg stage in the perpetuation of infections, understanding the biology of the Trichuris ova has been neglected for decades. Here we perform experiments to assess the impact of temperature on the embryonation process of T. muris eggs and describe in detail the stages of larval development within these eggs. In keeping with the early works performed in the early 1900s, we show that the embryonation of T. muris is accelerated by an elevation in temperature, up to 37°C above which eggs do not fully develop and become degenerate. We extend these data to provide a detailed description of T. muris egg development with clear images depicting the various stages of development. To the best of our knowledge we have, for the first time, described the presence of birefringent granules within egg-stage larvae, as well as providing a qualitative and quantitative description of a motile larval stage prior to quiescence within the egg. These experiments are the first step towards a better understanding of the basic biology which underlies the process of egg embryonation. With the threat of elevation in global temperatures, the accelerated embryonation rate we observe at higher temperatures may have important consequences for parasite transmission rates and prospective modelling studies. In addition, a deeper understanding of the Trichuris ova may allow the development of novel control strategies targeting the egg stage of Trichuris in the environment as an adjunct to MDA.
Highlights
Infections with the soil transmitted helminth Trichuris trichiura (T. trichiura) are highly prevalent with an estimated 465 million people infected worldwide in 2010, primarily in sub-saharan Africa [1]
The Rate of T. muris Egg Embryonation Is Altered by Temperature
The embryonation of T. muris eggs was investigated at several different temperatures to determine whether, akin to the published data in T. suis the rate of embryonation is impacted by the temperature of the eggs
Summary
Infections with the soil transmitted helminth Trichuris trichiura (T. trichiura) are highly prevalent with an estimated 465 million people infected worldwide in 2010, primarily in sub-saharan Africa [1] Infection with this nematode parasite causes the disease trichuriasis and occurs by the ingestion of embryonated eggs through contaminated soil or food. Whilst this strategy has been effective in targeting some of the other soil transmitted helminths e.g. Ascaris and hookworm, it has not been as successful in controlling trichuriasis especially in areas of Sub-Saharan Africa This is largely due to the poor efficacy of current anthelmintic treatment against Trichuris. A large barrier to elimination of trichuriasis is the environmental contamination with parasite eggs These eggs can persist in the soil for a long time and even following successful treatment of infected individuals, high reinfection rates occur. We provide a more detailed description on T. muris egg development than provided before, a description of a motile larval stage within the egg shell and the presence of birefringent granules
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
