Import of a constitutively expressed protein into mitochondria from procyclic and bloodstream forms of Trypanosoma brucei.

Trypanosoma brucei developmentally regulates mitochondrial function during its life cycle. Numerous nuclear encoded mitochondrial proteins undergo posttranslational regulation in a developmental fashion, but exactly how that regulation is achieved is unclear. We are interested in mitochondrial import as a potential regulatory step for nuclear encoded mitochondrial proteins. Previously, an in vitro import system was developed for the procyclic lifestage. We report here the development of an in vitro import system for bloodstream trypanosomes using a crude mitochondrial preparation. NADH dehydrogenase subunit K (NdhK) is a nuclear encoded mitochondrial protein that is constitutively expressed in bloodstream and procyclic trypanosomes. We examined the import of NdhK into procylic and bloodstream mitochondria in vitro. In both lifestages import of NdhK requires a membrane potential across the inner mitochondrial membrane, mitochondrial matrix ATP, and is time dependent. The precursor protein is processed by a matrix associated metalloprotease in a single cleavage step to mature protein.

Protein stability regulates the expression of cytochrome c during the developmental cycle of Trypanosoma brucei.

The expression of cytochrome c is developmentally regulated during the life cycle of Trypanosoma brucei. The level of regulation appears to be post-transcriptional since cytochrome c mRNA is present in all life stages of the parasite. We have used RNA from each life stage to prime in vitro translation systems and found that the cytochrome c mRNAs are equally translatable. Continuous labeling experiments conducted in vivo indicate that cytochrome c is synthesized at similar rates in both bloodstream and procyclic trypanosomes. Western blots, however, confirm that steady-state levels of cytochrome c are severely depressed in bloodstream forms. In a series of pulse/chase experiments we demonstrate that the half-life of cytochrome c is approximately 1 h in the bloodstream form and no detectable turnover occurred in the procyclic form. We conclude that a major step in the developmental regulation of cytochrome c expression in T. brucei occurs post-translationally due to rapid turnover of the protein in the bloodstream trypanosomes.

Modification of Trypanosoma brucei mitochondrial rRNA by posttranscriptional 3' polyuridine tail formation.

Trypanosoma brucei mitochondrial transcripts can be posttranscriptionally processed by uridine addition or deletion. With editing of mRNAs, uridine addition and deletion create precisely altered reading frames. The addition of nonencoded uridines to mitochondrial guide RNAs results in a less precise modification. Although uridines are specifically added to the 3' termini, their number varies, which results in heterogeneous oligo(U) tails on guide RNAs. In this paper, we show that the mitochondrial 9S and 12S rRNAs are also modified by uridine addition. These modifications appear to have aspects in common with both RNA editing and oligo(U) tail formation. Metabolic labeling studies with intact mitochondria and [alpha-32P]UTP, in the absence of transcription, demonstrated the posttranscriptional timing of the event. T1 RNase comparison analyses of cytidine 3',5'-[5'-32P]biphosphate 3'-end-labeled and [alpha-32P]UTP metabolically labeled rRNAs, along with direct RNA sequencing of the 3' termini, identified the site of uridine addition and revealed the creation of an oligo(U) tail for both rRNAs. 12S and 9S rRNAs hybrid selected from total cell RNA exhibited the same modification, demonstrating the presence of this processing in vivo. Moreover, only 3'-poly(U)-tailed 9S and 12S rRNAs were detected in total cellular and mitochondrial RNAs, which suggests that they are the most abundant and probable mature forms. The 12S and 9S rRNA oligo(U) tails differed significantly from each other, with the 12S having a heterogeneous tail of 2 to 17 uridines and the 9S having a tail of precisely 11 uridines. The mechanism of formation and the function of the rRNA poly(U) tails remain to be determined.