Live imaging of the Cryptosporidium parvum lifecycle reveals direct development of male and female gametes from type one meronts

Abstract

AbstractCryptosporidium is a leading infectious cause of diarrhea around the world associated with waterborne outbreaks, community spread, or zoonotic transmission. The parasite has significant impact on early childhood mortality, and infection is both consequence and cause of malnutrition and stunting. There is currently no vaccine, and treatment options are very limited. Cryptosporidium is a member of the Apicomplexa, and as typical for this protist phylum relies on asexual and sexual reproduction. In contrast to other Apicomplexa, like malaria parasite Plasmodium, Cryptosporidium’s entire lifecycle unfolds in a single host in less than three days. Here we establish a model to image lifecycle progression in living cells, and observe, track, and compare nuclear division of asexual and sexual stage parasites. We establish the length and sequence of the cell cycles of all stages and map the developmental fate of parasites across multiple rounds of invasion and egress. We determine that the parasite executes an intrinsic program of three generations of asexual replication, followed by a single generation of sexual stages that is independent of environmental stimuli. We find no evidence for a morphologically distinct intermediate stage (the tetraploid type II meront) but demonstrate direct development of gametes from 8N type I meronts. The progeny of each meront is collectively committed to either asexual or sexual fate, but importantly, meronts committed to sexual fate give rise to both males and females. We define a Cryptosporidium lifecycle matching Tyzzer’s original description and inconsistent with the coccidian lifecycle now shown in many textbooks.