Developmental regulation of Trypanosoma brucei cytochrome c reductase during bloodstream to procyclic differentiation.

The bloodstream forms of the protozoan parasite Trypanosoma brucei lack spectrally detectable cytochromes and satisfy energy requirements mainly by glycolysis. When infected blood is ingested by the tse-tse fly vector, the bloodstream form cells differentiate to procyclic forms that have fully functional mitochondria. Procyclic cells have cyanide-sensitive, cytochrome-mediated electron transport and the full complement of TCA cycle enzymes. The developmental regulation of the cytochrome c reductase complex was examined at the RNA and protein levels. RNase T1 protection studies and Northern blot analyses demonstrated that bloodstream and procyclic form cells constitutively expressed the genes for two nuclear encoded cytochrome c reductase subunits, cytochrome c1 and subunit 4. Polyadenylated transcripts of both genes were present in bloodstream form cells at up to 20% of the procyclic cell levels. These levels were significantly up-regulated sometime after the onset of differentiation to the procyclic form. Despite the presence of subunit mRNAs in bloodstream form cells, subunit proteins were not detected until the cells had been allowed to differentiate in vitro for 6 h. Procyclic cell levels of subunit proteins and holocytochromes were reached by 48 h. Our results suggest that cytochrome c reductase is developmentally regulated at multiple levels, some involving post-transcriptional mechanisms.