Trypanosoma brucei mitochondrial ribosomal RNA synthesis, processing and developmentally regulated expression

Identification of a unique conserved region from a kinetoplastid genome of Leishmania orientalis (formerly named Leishmania siamensis) strain PCM2 in Thailand

Mitochondrial DNAs (mtDNAs) appear in almost all eukaryotic species and are useful molecular markers for phylogenetic studies and species identification. Kinetoplast DNAs (kDNAs) are structurally complex circular mtDNA networks in kinetoplastids, divided into maxicircles and minicircles. Despite several kDNAs of many Leishmania species being examined, the kDNAs of the new species, Leishmania orientalis (formerly named Leishmania siamensis) strain PCM2, have not been explored. This study aimed to investigate the maxicircle and minicircle DNAs of L. orientalis strain PCM2 using hybrid genome sequencing technologies and bioinformatic analyses. The kDNA sequences were isolated and assembled using the SPAdes hybrid assembler from the Illumina short-read and PacBio long-read data. Circular contigs of the maxicircle and minicircle DNAs were reconstructed and confirmed by BLASTn and rKOMICs programs. The kDNA genome was annotated by BLASTn before the genome comparison and phylogenetic analysis by progressiveMauve, MAFFT, and MEGA programs. The maxicircle of L. orientalis strain PCM2 (18,215 bp) showed 99.92% similarity and gene arrangement to Leishmania enriettii strain LEM3045 maxicircle with variation in the 12s rRNA gene and divergent region. Phylogenetics of the whole sequence, coding regions, divergent regions, and 12s rRNA gene also confirmed this relationship and subgenera separation. The identified 105 classes of minicircles (402-1177 bp) were clustered monophyletically and related to the Leishmania donovani minicircles. The kinetoplast maxicircle and minicircle DNAs of L. orientalis strain PCM2 contained a unique conserved region potentially useful for specific diagnosis of L. orientalis and further exploration of this parasite population genetics in Thailand and related regions.

Lexis and Grammar of Mitochondrial RNA Processing in Trypanosomes

Trypanosoma brucei spp. cause African human and animal trypanosomiasis, a burden on health and economy in Africa. These hemoflagellates are distinguished by a kinetoplast nucleoid containing mitochondrial DNAs of two kinds: maxicircles encoding ribosomal RNAs (rRNAs) and proteins and minicircles bearing guide RNAs (gRNAs) for mRNA editing. All RNAs are produced by a phage-type RNA polymerase as 3' extended precursors, which undergo exonucleolytic trimming. Most pre-mRNAs proceed through 3' adenylation, uridine insertion/deletion editing, and 3' A/U-tailing. The rRNAs and gRNAs are 3' uridylated. Historically, RNA editing has attracted major research effort, and recently essential pre- and postediting processing events have been discovered. Here, we classify the key players that transform primary transcripts into mature molecules and regulate their function and turnover.

Separating the Wheat from the Chaff: RNA Editing and Selection of Translatable mRNA in Trypanosome Mitochondria

In the mitochondria of trypanosomes and related kinetoplastid protists, most mRNAs undergo a long and sophisticated maturation pathway before they can be productively translated by mitochondrial ribosomes. Some of the aspects of this pathway (identity of the promotors, transcription initiation, and termination signals) remain obscure, and some (post-transcriptional modification by U-insertion/deletion, RNA editing, 3'-end maturation) have been illuminated by research during the last decades. The RNA editing creates an open reading frame for a productive translation, but the fully edited mRNA often represents a minor fraction in the pool of pre-edited and partially edited precursors. Therefore, it has been expected that the final stages of the mRNA processing generate molecular hallmarks, which allow for the efficient and selective recognition of translation-competent templates. The general contours and several important details of this process have become known only recently and represent the subject of this review.

The 27 kDa Trypanosoma brucei Pentatricopeptide Repeat Protein is a G-tract Specific RNA Binding Protein

Pentatricopeptide repeat (PPR) proteins, a helical repeat family of organellar RNA binding proteins, play essential roles in post-transcriptional RNA processing. In Trypanosoma brucei, an expanded family of PPR proteins localize to the parasite’s single mitochondrion, where they are believed to perform important roles in both RNA processing and translation. We studied the RNA binding specificity of the simplest T. brucei PPR protein (KRIPP11) using electrophoretic mobility shift assays, fluorescence anisotropy, circular dichroism spectroscopy, and in vitro selection. We found KRIPP11 to be an RNA binding protein with specificity for sequences of four or more consecutive guanosine residues (G-tracts). Such G-tracts are dramatically enriched in T. brucei mitochondrial transcripts that are destined for extensive uridine insertion/deletion editing but are not present in mRNAs following editing. We further found that the quadruplex oligoguanosine RNA conformation is preferentially recognized by KRIPP11 over other conformational forms, and is bound without disruption of the quadruplex structure. In combination with prior data demonstrating association of KRIPP11 with the small ribosomal subunit, these results suggest possible roles for KRIPP11 in bridging mRNA maturation and translation or in facilitating translation of unusual dual-coded open reading frames.

Transcription initiation defines kinetoplast RNA boundaries

Mitochondrial genomes are often transcribed into polycistronic RNAs punctuated by tRNAs whose excision defines mature RNA boundaries. Although kinetoplast DNA lacks tRNA genes, it is commonly held that in Trypanosoma brucei the monophosphorylated 5' ends of functional molecules typify precursor partitioning by an unknown endonuclease. On the contrary, we demonstrate that individual mRNAs and rRNAs are independently synthesized as 3'-extended precursors. The transcription-defined 5' terminus is converted into a monophosphorylated state by the pyrophosphohydrolase complex, termed the "PPsome." Composed of the MERS1 NUDIX enzyme, the MERS2 pentatricopeptide repeat RNA-binding subunit, and MERS3 polypeptide, the PPsome binds to specific sequences near mRNA 5' termini. Most guide RNAs lack PPsome-recognition sites and remain triphosphorylated. The RNA-editing substrate-binding complex stimulates MERS1 pyrophosphohydrolase activity and enables an interaction between the PPsome and the polyadenylation machinery. We provide evidence that both 5' pyrophosphate removal and 3' adenylation are essential for mRNA stabilization. Furthermore, we uncover a mechanism by which antisense RNA-controlled 3'-5' exonucleolytic trimming defines the mRNA 3' end before adenylation. We conclude that mitochondrial mRNAs and rRNAs are transcribed and processed as insulated units irrespective of their genomic location.

Tail characteristics of Trypanosoma brucei mitochondrial transcripts are developmentally altered in a transcript-specific manner

The intricate life cycle of Trypanosoma brucei requires extensive regulation of gene expression levels of the mtRNAs for adaptation. Post-transcriptional gene regulatory programs, including unencoded mtRNA 3' tail additions, potentially play major roles in this adaptation process. Intriguingly, T. brucei mitochondrial transcripts possess two distinct unencoded 3' tails, each with a differing functional role; i.e., while one type is implicated in RNA stability (in-tails), the other type appears associated with translation (ex-tails). We examined the degree to which tail characteristics differ among cytochrome c oxidase subunits I and III (CO1 and CO3), and NADH dehydrogenase subunit 1 (ND1) transcripts, and to what extent these characteristics differ developmentally. We found that CO1, CO3 and ND1 transcripts possess longer in-tails in the mammalian life stage. By mathematically modelling states of in-tail and ex-tail addition, we determined that the typical length at which an in-tail is extended to become an ex-tail differs by transcript and, in the case of ND1, by life stage. To the best of our knowledge, we provide the first evidence that developmental differences exist in tail length distributions of mtRNAs, underscoring the potential involvement of in-tail and ex-tail populations in mitochondrial post-transcriptional regulation mechanisms.

Malleable mitochondrion of Trypanosoma brucei

The importance of mitochondria for a typical aerobic eukaryotic cell is undeniable, as the list of necessary mitochondrial processes is steadily growing. Here, we summarize the current knowledge of mitochondrial biology of an early-branching parasitic protist, Trypanosoma brucei, a causative agent of serious human and cattle diseases. We present a comprehensive survey of its mitochondrial pathways including kinetoplast DNA replication and maintenance, gene expression, protein and metabolite import, major metabolic pathways, Fe-S cluster synthesis, ion homeostasis, organellar dynamics, and other processes. As we describe in this chapter, the single mitochondrion of T. brucei is everything but simple and as such rivals mitochondria of multicellular organisms.

Additive and transcript-specific effects of KPAP1 and TbRND activities on 3' non-encoded tail characteristics and mRNA stability in Trypanosoma brucei

Short, non-encoded oligo(A), oligo(U), or A/U tails can impact mRNA stability in kinetoplastid mitochondria. However, a comprehensive picture of the relative effects of these modifications in RNA stability is lacking. Furthermore, while the U-preferring exoribonuclease TbRND acts on U-tailed gRNAs, its role in decay of uridylated mRNAs has only been cursorily investigated. Here, we analyzed the roles of mRNA 3′ tail composition and TbRND in RNA decay using cells harbouring single or double knockdown of TbRND and the KPAP1 poly(A) polymerase. Analysis of mRNA abundance and tail composition reveals dramatic and transcript-specific effects of adenylation and uridylation on mitochondrial RNAs. Oligo(A) and A-rich tails can stabilize a proportion of edited and never-edited RNAs. However, non-tailed RNAs are not inherently unstable, implicating additional stability determinants and/or spatial segregation of sub-populations of a given RNA in regulation of RNA decay. Oligo(U) tails, which have been shown to contribute to decay of some never-edited RNAs, are not universally destabilizing. We also show that RNAs display very different susceptibility to uridylation in the absence of KPAP1, a factor that may contribute to regulation of decay. Finally, 3′ tail composition apparently impacts the ability of an RNA to be edited.

Guide RNA biogenesis involves a novel RNase III family endoribonuclease in Trypanosoma brucei

The mitochondrial genome of kinetoplastids, including species of Trypanosoma and Leishmania, is an unprecedented DNA structure of catenated maxicircles and minicircles. Maxicircles represent the typical mitochondrial genome encoding components of the respiratory complexes and ribosomes. However, most mRNA sequences are cryptic, and their maturation requires a unique U insertion/deletion RNA editing. Minicircles encode hundreds of small guide RNAs (gRNAs) that partially anneal with unedited mRNAs and direct the extensive editing. Trypanosoma brucei gRNAs and mRNAs are transcribed as polycistronic precursors, which undergo processing preceding editing; however, the relevant nucleases are unknown. We report the identification and functional characterization of a close homolog of editing endonucleases, mRPN1 (mitochondrial RNA precursor-processing endonuclease 1), which is involved in gRNA biogenesis. Recombinant mRPN1 is a dimeric dsRNA-dependent endonuclease that requires Mg(2+), a critical catalytic carboxylate, and generates 2-nucleotide 3' overhangs. The cleavage specificity of mRPN1 is reminiscent of bacterial RNase III and thus is fundamentally distinct from editing endonucleases, which target a single scissile bond just 5' of short duplexes. An inducible knockdown of mRPN1 in T. brucei results in loss of gRNA and accumulation of precursor transcripts (pre-gRNAs), consistent with a role of mRPN1 in processing. mRPN1 stably associates with three proteins previously identified in relatively large complexes that do not contain mRPN1, and have been linked with multiple aspects of mitochondrial RNA metabolism. One protein, TbRGG2, directly binds mRPN1 and is thought to modulate gRNA utilization by editing complexes. The proposed participation of mRPN1 in processing of polycistronic RNA and its specific protein interactions in gRNA expression are discussed.

Mitochondrial RNA processing in trypanosomes

The mitochondrial genome of trypanosomes is composed of ∼50 maxicircles and thousands of minicircles. Maxi-(∼25 kb) and mini-(∼1 kb)circles are catenated and packed into a dense structure called a kinetoplast. Both types of circular DNA are transcribed by a phage-like RNA polymerase: maxicircles yield multicistronic rRNA and mRNA precursors, while guide RNA (gRNA) precursors are produced from minicircles. To function in mitochondrial translation, pre-mRNAs must undergo a nucleolytic processing and 3' modifications, and often uridine insertion/deletion editing. gRNAs, which represent short (50-60 nt) RNAs directing editing reactions, are produced by 3' nucleolytic processing of a much longer precursor followed by 3' uridylation. Ribosomal RNAs are excised from precursors and their 3' ends are also trimmed and uridylated. All tRNAs are imported from the cytoplasm and some are further modified and edited in the mitochondrial matrix. Historically, the fascinating phenomenon of RNA editing has been extensively studied as an isolated pathway in which nuclear-encoded proteins mediate interactions of maxi- and minicircle transcripts to create open reading frames. However, recent studies unraveled a highly integrated network of mitochondrial genome expression including critical pre- and post-editing 3' mRNA processing, and gRNA and rRNA maturation steps. Here we focus on RNA 3' adenylation and uridylation as processes essential for biogenesis, stability and functioning of mitochondrial RNAs.

Organization and expression of organellar genomes

Protist mitochondrial genomes show a very wide range of gene content, ranging from three genes for respiratory chain components in Apicomplexa and dinoflagellates to nearly 100 genes in Reclinomonas americana. In many organisms the rRNA genes are fragmented, although still functional. Some protist mitochondria encode a full set of tRNAs, while others rely on imported molecules. There is similarly a wide variation in mitochondrial genome organization, even among closely related groups. Mitochondrial gene expression and control are generally poorly characterized. Transcription probably relies on a 'viral-type' RNA polymerase, although a 'bacterial-type' enzyme may be involved in some cases. Transcripts are heavily edited in many lineages. The chloroplast genome generally shows less variation in gene content and organization, although greatly reduced genomes are found in dinoflagellate algae and non-photosynthetic organisms. Genes in the former are located on small plasmids in contrast to the larger molecules found elsewhere. Control of gene expression in chloroplasts involves transcriptional and post-transcriptional regulation. Redox poise and the ATP/ADP ratio are likely to be important determinants. Some protists have an additional extranuclear genome, the nucleomorph, which is a remnant nucleus. Nucleomorphs of two separate lineages have a number of features in common.

Immunobiology of African trypanosomes: need of alternative interventions

Trypanosomiasis is one of the major parasitic diseases for which control is still far from reality. The vaccination approaches by using dominant surface proteins have not been successful, mainly due to antigenic variation of the parasite surface coat. On the other hand, the chemotherapeutic drugs in current use for the treatment of this disease are toxic and problems of resistance are increasing (see Kennedy (2004) and Legros et al. (2002)). Therefore, alternative approaches in both treatment and vaccination against trypanosomiasis are needed at this time. To be able to design and develop such alternatives, the biology of this parasite and the host response against the pathogen need to be studied. These two aspects of this disease with few examples of alternative approaches are discussed here.

The MRB1 complex functions in kinetoplastid RNA processing

Mitochondrial (mt) gene expression in Trypanosoma brucei entails multiple types of RNA processing, including polycistronic transcript cleavage, mRNA editing, gRNA oligouridylation, and mRNA polyadenylation, which are catalyzed by various multiprotein complexes. We examined the novel mitochondrial RNA-binding 1 (MRB1) complex that has 16 associated proteins, four of which have motifs suggesting RNA interaction. RNase treatment or the lack of kDNA in mutants resulted in lower MRB1 complex sedimentation in gradients, indicating that MRB1 complex associates with kDNA transcripts. RNAi knockdowns of expression of the Tb10.406.0050 (TbRGGm, RGG motif), Tb927.6.1680 (C2H2 zinc finger), and Tb11.02.5390 (no known motif) MRB1 proteins each inhibited in vitro growth of procyclic form parasites and resulted in cells with abnormal numbers of nuclei. Knockdown of TbRGGm, but not the other two proteins, disrupted the MRB1 complex, indicating that it, but perhaps not the other two, is required for complex assembly and/or stability. The knockdowns resulted in similar but nonidentical patterns of altered in vivo abundances of edited, pre-edited, and preprocessed mt mRNAs, but did not appreciably affect the abundances of mRNAs that do not get edited. These results indicate that MRB1 complex is critical to the processing of mt RNAs, and although its specific function is unknown, it appears essential to parasite viability.

Roles for TbDSS-1 in RNA surveillance and decay of maturation by-products from the 12S rRNA locus

The Trypanosoma brucei exoribonuclease, TbDSS-1, has been implicated in multiple aspects of mitochondrial RNA metabolism. Here, we investigate the role of TbDSS-1 in RNA processing and surveillance by analyzing 12S rRNA processing intermediates in TbDSS-1 RNAi cells. RNA fragments corresponding to leader sequence upstream of 12S rRNA accumulate upon TbDSS-1 depletion. The 5' extremity of 12S rRNA is generated by endonucleolytic cleavage, and TbDSS-1 degrades resulting upstream maturation by-products. RNAs with 5' ends at position -141 and 3' ends adjacent to the mature 5' end of 12S rRNA are common and invariably possess oligo(U) tails. 12S rRNAs with mature 3' ends and unprocessed 5' ends also accumulate in TbDSS-1 depleted cells, suggesting that these RNAs represent dead-end products normally destined for decay by TbDSS-1 in an RNA surveillance pathway. Together, these data indicate dual roles for TbDSS-1 in degradation of 12S rRNA maturation by-products and as part of a mitochondrial RNA surveillance pathway that eliminates stalled 12S processing intermediates. We further provide evidence that TbDSS-1 degrades RNAs originating upstream of the first gene on the minor strand of the mitochondrial maxicircle suggesting that TbDSS-1 also removes non-functional RNAs generated from other regions of the mitochondrial genome.

Troglitazone induces differentiation in Trypanosoma brucei

Trypanosoma brucei, a protozoan parasite causing sleeping sickness, is transmitted by the tsetse fly and undergoes a complex lifecycle including several defined stages within the insect vector and its mammalian host. In the latter, differentiation from the long slender to the short stumpy form is induced by a yet unknown factor of trypanosomal origin. Here we describe that some thiazolidinediones are also able to induce differentiation. In higher eukaryotes, thiazolidinediones are involved in metabolism and differentiation processes mainly by binding to the intracellular receptor peroxisome proliferator activated receptor gamma. Our studies focus on the effects of troglitazone on bloodstream form trypanosomes. Differentiation was monitored using mitochondrial markers (membrane potential, succinate dehydrogenase activity, inhibition of oxygen uptake by KCN, amount of cytochrome transcripts), morphological changes (Transmission EM and light microscopy), and transformation experiments (loss of the Variant Surface Glycoprotein coat and increase of dihydroliponamide dehydrogenase activity). To further investigate the mechanisms responsible for these changes, microarray analyses were performed, showing an upregulation of expression site associated gene 8 (ESAG8), a potential differentiation regulator.

Conserved repeats in the kinetoplast maxicircle divergent region of Leishmania sp. and Leptomonas seymouri

The maxicircle control region [also termed divergent region (DR)] composed of various repeat elements remains the most poorly studied part of the kinetoplast genome. Only three extensive DR sequences demonstrating no significant similarity were available for trypanosomatids (Leishmania tarentolae, Crithidia oncopelti, Trypanosoma brucei). Recently, extensive DR sequences have been obtained for Leishmania major and Trypanosoma cruzi. In this work we have sequenced DR fragments of Leishmania turanica, Leishmania mexicana, Leishmania chagasi and two monogenetic trypanosomatids Leptomonas seymouri and Leptomonas collosoma. With the emergence of the additional extensive sequences some conserved features of DR structure become evident. A conserved palindromic sequence has been revealed in the DRs of the studied Leishmania species, L. seymouri, and T. cruzi. The overall DR structure appears to be similar in all the Leishmania species, their relative L. seymouri, and T. brucei: long relatively GC-rich repeats are interspersed with clusters of short AT-rich repeats. C. oncopelti, L. collosoma, and T. cruzi have a completely different DR structure. Identification of conserved sequences and invariable structural features of the DR may further our understanding of the functioning of this important genome fragment.

Identification of pentatricopeptide repeat proteins in Trypanosoma brucei

A new class of organellar proteins, characterized by pentatricopeptide repeat (PPR) motifs, has been identified in plants. These proteins contain multiple 35-amino acid repeats that are proposed to form a super helix capable of binding a strand of RNA. All PPR proteins characterized to date appear to be involved in RNA processing pathways in organelles. Twenty-three PPR proteins have been identified in Trypanosoma brucei and database research indicates that most of these proteins are predicted to contain the traditional mitochondrial target sequence. Orthologues of each of the 23 proteins have also been identified in Leishmania major and Trypanosoma cruzi, indicating that these proteins represent a highly conserved class of proteins within the kinetoplastid family. Preliminary experiments using RNAi to specifically silence one identified PPR gene (TbPPRl- Tb927.2.3180), indicate that cells depleted of TbPPRl transcripts show a slow growth phenotype and altered mitochondrial maxicircle RNA profiles. This initial characterization suggests that PPR proteins will play important roles in the complex RNA processing required for mitochondrial gene expression in trypanosomes.

The Leishmania major maxicircle divergent region is variable in different isolates and cell types

The maxicircle divergent region (DR) was partially sequenced in several isolates of Leishmania major. The sequence contains various repeated elements: two types of long GC-rich repeats alternating with clusters of short AT-rich repeats. The arrangement of repeats appears to be similar in the studied Leishmania species and their relative Leptomonas seymouri. Furthermore, a conserved sequence containing putative promoters within a palindrome was revealed in the DRs of these species. Unexpectedly, the DR sequence proved to be dissimilar in promastigotes and amastigotes of the same isolate perhaps through selection of parasites with particular maxicircle variants in the course of the promastigote-amastigote differentiation. Different number of repeats and numerous single nucleotide polymorphisms are observed in the compared sequences. We have also investigated the DR structure in 21 L. major isolates by PCR and demonstrated its great variability. We suppose, however, that different variants of the DR structure are generated by combination of several highly conserved domains.

Cycles within cycles: the interplay between differentiation and cell division in Trypanosoma brucei

The life cycle o f the African trypanosome is divided between the mammal and the tsetse. Those life cycle stages which traverse between these two hosts appear to be pre-adopted for survival in their new habitat They are also non-dividing. Here, Keith Matthews and Keith Gull discuss how and why trypanosomes might enmesh the control o f their cell cycle with their regulation o f the transition between different life cycle forms.

TbDSS-1, an essential Trypanosoma brucei exoribonuclease homolog that has pleiotropic effects on mitochondrial RNA metabolism

Mitochondrial gene expression in trypanosomes is controlled primarily at the levels of RNA processing and RNA stability. This regulation undoubtedly involves numerous ribonucleases. Here we characterize the Trypanosoma brucei homolog of the yeast DSS-1 mitochondrial exoribonuclease, which we term TbDSS-1. Biochemical fractionation indicates that TbDSS-1 is mitochondrially localized, as predicted by its N-terminal sequence. In contrast to its yeast homolog, TbDSS-1 does not appear to be associated with mitochondrial ribosomes. Targeted downregulation of TbDSS-1 by RNA interference in procyclic-form T. brucei results in a severe growth defect. In addition, TbDSS-1 depletion leads to a decrease in the levels of never edited cytochrome oxidase subunit I (COI) mRNA and both unedited and edited COIII mRNAs, indicating this enzyme functions in the control of mitochondrial RNA abundance. We also observe a considerable reduction in the level of edited apocytochrome b (CYb) mRNA and a corresponding increase in unedited CYb mRNA, suggesting that TbDSS-1 functions, either directly or indirectly, in the control of RNA editing. The abundance of both gCYb[560] and gA6[149] guide RNAs is reduced upon TbDSS-1 depletion, although the reduction in gCYb[560] is much more dramatic. The significant reduction in gCYb levels could potentially account for the observed decrease in CYb RNA editing. Western blot analyses of mitochondrial RNA editing and stability factors indicate that the perturbations of RNA levels observed in TbDSS-1 knock-downs do not result from secondary effects on other mitochondrial proteins. In all, these data demonstrate that TbDSS-1 is an essential protein that plays a role in mitochondrial RNA stability and RNA editing.

An intragenic guide RNA location suggests a complex mechanism for mitochondrial gene expression in Trypanosoma brucei

In Trypanosoma brucei, two classes of transcripts are produced from two distinct mitochondrial genome components. Guide RNAs (gRNAs) are usually minicircle encoded and exist as primary transcripts, while the maxicircle-encoded rRNAs and mRNAs are processed from a polycistronic precursor. The genes for the gRNAs gMURF2-II and gCYb(560) each have uncommon kinetoplast DNA (kDNA) locations that are not typically associated with transcription initiation events. We demonstrate that the conserved maxicircle gRNA gMURF2-II has an unusual location within the ND4 gene. This is the first report of a completely intragenic gene in kDNA. In addition, the gMURF2-II and ND4 transcripts are generated by distinctly different events; the ND4 mRNA is processed from a polycistronic precursor, while transcription of the gRNA initiates downstream of the 5' end of the ND4 gene. The gCYb(560) gene has an atypical minicircle location in that it is not flanked by the inverted repeat sequences that surround the majority of minicircle gRNA genes. Our data indicate that the mature gCYb(560) gRNA is also a primary transcript and that the 5'-end heterogeneity previously observed for this gRNA is a result of multiple transcription initiation sites and not of imprecise 5'-end processing. Together, these data indicate that gRNA genes represent individual transcription units, regardless of their genomic context, and suggest a complex mechanism for mitochondrial gene expression in T. brucei.

Complete cycles of bloodstream trypanosome RNA editing in vitro

RNA editing in kinetoplastid protists is required for the maturation of mitochondrial pre-mRNAs and occurs by protein-catalyzed cycles of uridylate insertion and deletion. During the complex life cycle of Trypanosoma brucei this process is differentially regulated in the mammalian bloodstream and insect procyclic stages. Complementary guide RNAs (gRNAs) direct editing, but the abundance of these transcripts is not developmentally controlled. The establishment of in vitro systems that recreate efficient RNA editing in bloodstream T. brucei would be valuable for mechanistic studies of regulation. Here we describe a robust in vitro system that reconstitutes full cycles of both U insertion and U deletion in bloodstream trypanosomes, and the first direct comparisons of the in vitro systems for strains of mammalian and insect stages.

RBP38, a novel RNA-binding protein from trypanosomatid mitochondria, modulates RNA stability

We describe here the isolation and characterization of a novel RNA-binding protein, RBP38, from Leishmania tarentolae mitochondria. This protein does not contain any known RNA-binding motifs and is highly conserved among the trypanosomatids, but no homologues were found in other organisms. Recombinant LtRBP38 binds single and double-stranded (ds) RNA substrates with dissociation constants in the 100 nM range, as determined by fluorescence polarization analysis. Downregulation of expression of the homologous gene, TbRBP38, in procyclic Trypanosoma brucei by using conditional dsRNA interference resulted in 80% reduction of steady-state levels of RNAs transcribed from both maxicircle and minicircle DNA. In organello pulse-chase labeling experiments were used to determine the stability of RNAs in mitochondria that were depleted of TbRBP38. The half-life of metabolically labeled RNA decreased from approximately 160 to approximately 60 min after depletion. In contrast, there was no change in transcriptional activity. These observations suggest a role of RBP38 in stabilizing mitochondrial RNA.

RBP16 is a multifunctional gene regulatory protein involved in editing and stabilization of specific mitochondrial mRNAs in Trypanosoma brucei

RBP16 is a Trypanosoma brucei mitochondrial RNA-binding protein that associates with guide RNAs (gRNAs), mRNAs, and ribosomal RNAs. Based on its inclusion in the multifunctional Y-box protein family and its ability to bind multiple RNA classes, we hypothesized that RBP16 plays a role in diverse aspects of mitochondrial gene regulation. To gain insight into RBP16 function, we generated cells expressing less than 10% of wild-type RBP16 levels by tetracycline-regulated RNA interference (RNAi). Poisoned primer extension analyses revealed that edited, but not unedited, CYb mRNA is reduced by approximately 98% in tetracycline-induced RBP16 RNAi cells, suggesting that RBP16 is critical for CYb RNA editing. The down-regulation of CYb editing in RBP16 RNAi transfectants apparently entails a defect in gRNA utilization, as gCYb[560] abundance is similar in uninduced and induced cells. We observed a surprising degree of specificity regarding the ability of RBP16 to modulate editing, as editing of mRNAs other than CYb is not significantly affected upon RBP16 disruption. However, the abundance of the never edited mitochondrial RNAs COI and ND4 is reduced by 70%-80% in RBP16 RNAi transfectants, indicating an additional role for RBP16 in the stabilization of these mRNAs. Analysis of RNAs bound to RBP16 immunoprecipitated from wild-type cells reveals that RBP16 is associated with multiple gRNA sequence classes in vivo, including those whose abundance and usage appear unaffected by RBP16 disruption. Overall, our results indicate that RBP16 is an accessory factor that regulates the editing and stability of specific populations of mitochondrial mRNAs.

Natural and induced dyskinetoplastic trypanosomatids: how to live without mitochondrial DNA

Salivarian trypanosomes are the causative agents of several diseases of major social and economic impact. The most infamous parasites of this group are the African subspecies of the Trypanosoma brucei group, which cause sleeping sickness in humans and nagana in cattle. In terms of geographical distribution, however, Trypanosoma equiperdum and Trypanosoma evansi have been far more successful, causing disease in livestock in Africa, Asia, and South America. In these latter forms the mitochondrial DNA network, the kinetoplast, is altered or even completely lost. These natural dyskinetoplastic forms can be mimicked in bloodstream form T. brucei by inducing the loss of kinetoplast DNA (kDNA) with intercalating dyes. Dyskinetoplastic T. brucei are incapable of completing their usual developmental cycle in the insect vector, due to their inability to perform oxidative phosphorylation. Nevertheless, they are usually as virulent for their mammalian hosts as parasites with intact kDNA, thus questioning the therapeutic value of attempts to target mitochondrial gene expression with specific drugs. Recent experiments, however, have challenged this view. This review summarises the data available on dyskinetoplasty in trypanosomes and revisits the roles the mitochondrion and its genome play during the life cycle of T. brucei.

A trypanosome mitochondrial RNA polymerase is required for transcription and replication

Understanding mitochondrial transcription is a requisite first step toward understanding the regulation of mitochondrial gene expression in kinetoplastids. Here we report the identification and functional characterization of a mitochondrial RNA polymerase (mtRNAP) from Trypanosoma brucei, the first trans-acting factor involved in kinetoplast mitochondrial transcription to be identified. Using sequences conserved among the catalytic domains of the single-subunit mtRNAPs, we were able to obtain a full-length sequence for a candidate mtRNAP from T. brucei. Sequence comparison indicates that it shares homology in its catalytic domain with other single-subunit mtRNAPs, including functionally conserved residues that are identical in all single-subunit RNAPs. We used RNA interference to functionally knock out the gene product to determine whether the candidate gene represents an mtRNAP. As predicted for a mitochondrial specific RNA polymerase, reduction of the gene product resulted in a specific decrease of mitochondrial versus nuclear transcripts. Additionally, similar to the mtRNAP of other organisms, the mtRNAP characterized here is involved in replication of the mitochondrial genome. Thus, based on sequence comparison and functional studies, we have cloned an mtRNAP from trypanosomes.

Role of uridylate-specific exoribonuclease activity in Trypanosoma brucei RNA editing

Editing of mitochondrial mRNAs in kinetoplastid protozoa occurs by a series of enzymatic steps that insert and delete uridylates (U's) as specified by guide RNAs (gRNAs). The characteristics of the 3' exonuclease activity that removes the U's following cleavage during deletion editing were determined by using an in vitro precleaved deletion assay that is based on ATPase subunit 6 pre-mRNA and gA6[14] gRNA. The exonuclease in partially purified editing complexes is specific for U's. The specificity occurs in the absence of gRNA, but its activity is enhanced by the presence of gRNA. The 3' pre-mRNA fragment enhances the specificity, but not the efficiency, of U removal. The activity is sensitive to the 5' phosphate of the 3' fragment, which is not required for U removal. The ability of the 3' U's to base pair with purines in the gRNA protects them from removal, suggesting that the U-specific 3' exonuclease (exoUase) is specific for U's which are not base paired. ExoUase is stereospecific and cannot remove (Rp)alpha-thio-U. The specificity of the exoUase activity thus contributes to the precision of RNA editing.

Unique aspects of mitochondrial biogenesis in trypanosomatids

Mitochondrial biogenesis consists of the sum of all processes required for the formation of the mitochondrial membranes as well as the soluble compartments they contain. Furthermore, it includes the replication of the mitochondrial genome and correct segregation of the organelles during cell division. Mitochondrial proteins come from two sources, a limited but essential set of inner membrane proteins is encoded by the mitochondrial genome, whereas the large majority (90-95%) is derived from nucleus-encoded genes and are posttranslationally imported into the organelle. Trypanosomatids belong to the earliest diverging branches of the eukaryotic evolutionary tree which have mitochondria. This is reflected in the organisation of their mitochondrial DNA that consists of a network of two classes of topologically interlocked circular DNA molecules as well as many unique features in their mitochondrial biogenesis. The proteins encoded on the mitochondrial genome are conventional for a mitochondrial genome, their expression, however, involves a complex series of processes. Many genes represent incomplete open reading frames and their primary transcripts have to remodelled by RNA editing to convert them into translatable mRNAs. RNA editing is mediated by small mitochondria-encoded transcripts, the guide RNAs, and is in that form specific for trypanosomatids and closely related organisms. Mitochondrial translation is also unconventional. No tRNA genes are encoded on the mitochondrial genome. Instead, mitochondrial protein synthesis functions exclusively with imported cytosolic, eukaryotic-type tRNAs. The composition of mitochondrial ribosomes is also unusual in that they contain the smallest known rRNAs. They are about 30% shorter than the already much reduced rRNAs in human mitochondria. Furthermore, the topological organisation of the mitochondrial genome requires an elaborate replication machinery involving topoisomerases. Finally, some trypanosomatids have life cycle stages exhibiting very different mitochondrial activities and can therefore serve as a model system for the regulation of mitochondrial biogenesis.

Transcriptional and post-transcriptional in organello labelling of Trypanosoma brucei mitochondrial RNA

In organello labelling of Trypanosoma brucei mitochondrial (mt) RNA was characterised with respect to nucleotide requirements and drug sensitivity. Mitochondrial transcriptional activity is maximal in the presence of all ribonucleoside-triphosphate NTPs, and can be inhibited by UTP depletion. Mitochondrial transcription can also be partially inhibited by actinomycin D (actD) or ethidium bromide (EtBr). Post-transcriptional UTP incorporation is insensitive to actinomycin D or ethidium bromide. Proteins were identified that interact with transcriptional and post-transcriptionally labelled RNAs, and confirm the in vitro RNA-binding properties discovered for a number of T. brucei mt proteins. These experiments reveal new strategies for studying mt transcription and processing in T. brucei mitochondria.

UTP-dependent and -independent pathways of mRNA turnover in Trypanosoma brucei mitochondria

Although primary transcripts are polycistronic in the mitochondria of Trypanosoma brucei, steady-state levels of mature, monocistronic RNAs change throughout the parasitic life cycle. This indicates that steady-state RNA abundance is controlled by posttranscriptional mechanisms involving differential RNA stability. In this study, in organello pulse-chase labeling experiments were used to analyze the stability of different T. brucei mitochondrial RNA populations. In this system, total RNA and rRNA are stable for many hours. In contrast, mRNAs can be degraded by two biochemically distinct turnover pathways. The first pathway results in the rapid degradation of mRNA (half-life [t(1/2)] of 11 to 18 min) and is dependent upon the presence of an mRNA poly(A) tail. Remarkably, this pathway also requires the addition of UTP and therefore is termed UTP dependent. The second pathway results in slow turnover of mitochondrial mRNA (t(1/2) of approximately 3 h) and is not dependent upon the presence of an mRNA poly(A) tail or the addition of exogenous UTP. In summary, these results demonstrate the presence of a novel, UTP-dependent degradation pathway for T. brucei mitochondrial mRNAs and reveal an unprecedented role for both UTP and mRNA polyadenylation in T. brucei mitochondrial gene expression.

Localization of riboproteins in a trypanosomatid mitochondrion

There is growing evidence in support of mitochondrial translation in trypanosomes but mitoribosomes have never been characterized or localized in these parasites. On RNA-protein blots we identified several proteins from the trypanosomatid Crithidia fasciculata which bound the parasite's 12S and 9S mitochondrial ribosomal RNAs. Two of these proteins had significant amino acid sequence homology to riboproteins S8 and S21 across phyla. Immunoelectron microscopy revealed that antibodies raised against the two proteins react with matrix components in the C. fasciculata mitochondrion. Our data thus provide, we believe for the first time, evidence for the presence of riboproteins within a trypanosomatid mitochondrion, bound, possibly, to the 12S and 9S RNAs. The proteins were immunologically related to two cytosolic riboproteins which were also of identical size, suggesting the interesting possibility that the same set of riboproteins is shared between the cytosol and the mitochondrion in this parasite.

Uridine insertion/deletion RNA editing in trypanosome mitochondria--a review

The uridine insertion/deletion RNA editing in trypanosome mitochondria is a unique posttranscriptional RNA maturation process that involves the addition or removal of uridine residues at precise sites usually within the coding regions of mitochondrial transcripts. This process creates initiation and termination codons, corrects frameshifts and even builds entire open-reading frames from nonsense sequences. The development of several in-vitro editing assays has provided much insight into the molecular mechanism of RNA editing, which appears to involve cleavage, U addition, exonuclease trimming and ligation, essentially as proposed in the original 'enzyme cascade' model (Blum, B., Bakalara, N., Simpson, L., 1990. A model for RNA editing in kinetoplastid mitochondria: 'Guide' RNA molecules transcribed from maxicircle DNA provide the edited information. Cell 60, 189-198). However, little is known about the biochemical properties of the proteins involved and the significance and role of this process. This article is a review of recent findings on uridine-insertion/deletion editing in trypanosome mitochondria, with an emphasis on the proteins isolated and characterized that may have a role in this process.

Trypanosoma brucei poly(A) binding protein I cDNA cloning, expression, and binding to 5 untranslated region sequence elements

Poly(A) binding protein I (PABPI) is a highly conserved eukaryotic protein that binds mRNA poly(A) tails and functions in the regulation of translational efficiency and mRNA stability. As a first step in our investigation of the role(s) of mRNA poly(A) tails in posttranscriptional gene regulation in Trypanosoma brucei, we have cloned the cDNA encoding PABPI from this organism. The cDNA predicts a protein homologous to PABPI from other organisms and displaying conserved features of these proteins, including four RNA binding domains that span the N-terminal two-thirds of the protein. Comparison of northern blot data with the cDNA sequence indicates an unusually long 3' untranslated region (UTR) of approximately three kilobases. The 5 UTR contains both A-rich and AU repeat regions, the former being a ubiquitous property of PABPI 5' UTRs. T. brucei PABPI, expressed as a glutathione-S-transferase fusion protein, bound to RNA comprised of its full length 5' UTR in UV cross-linking experiments. This suggests that PABPI may play an autoregulatory role in its own expression. Competition experiments indicate that the A-rich region, but not the AU repeats, are involved in this binding.

Purification and characterization of MAR1. A mitochondrial associated ribonuclease from Leishmania tarentolae

A relatively thermostable 22-kDa endoribonuclease (MAR1) was purified more than 10,000-fold from a mitochondrial extract of Leishmania tarentolae and the gene cloned. The purified nuclease has a Km of 100-145 +/- 33 nM and a Vmax of 1.8-2.9 +/- 2 nmol/min, depending on the RNA substrate, and yields a 3'-OH and a 5'-phosphate. Cleavage was limited to several specific sites in the substrate RNAs tested, but cleavage of pre-edited RNAs was generally independent of the addition of cognate guide RNA. The MAR1 gene was expressed in Escherichia coli or in L. tarentolae cells, and the recombinant protein was affinity-purified. The cleavage specificity of the recombinant enzyme from L. tarentolae was identical to that of the native enzyme. The single copy MAR1 gene maps to an 820-kilobase pair chromosome and contains an open reading frame of 579 nucleotides. The 18-amino acid N-terminal sequence shows characteristics of an uncleaved mitochondrial targeting sequence. Data base searching revealed two homologues of MAR1 corresponding to unidentified open reading frames in Caenorhabditis elegans (GenBankTM accession number Z69637) and Archaeoglobus fulgidus (GenBankTM accession number AE000943). The function of MAR1 in mitochondrial RNA metabolism in L. tarentolae remains to be determined.

Mitochondrial mRNA 3' cleavage/polyadenylation and RNA editing in Trypanosoma brucei are independent events

The organization of the mitochondrial maxicircle genome of Trypanosoma brucei is unique in the close packing of the mRNA genes. For many of them, the 5' and 3' ends of adjacent transcripts overlap and formation of the proper 3' or 5' end can eliminate a portion of the coding sequence of the adjacent gene. Large, polycistronic transcripts have been detected. suggesting that mechanisms for precise cleavages at both 5' and 3' gene boundaries must exist. However, no common sequences near the ends of the mRNAs that could be candidates for control regions have been detected. In addition, nothing is known about how RNA editing interacts with and affects 5' and 3' processing and/or polyadenylation. Edited precursor transcripts have been detected, indicating that editing complexes can assemble prior to transcript cleavage. Because editing often initiates near the 3' end of the mRNA, the assembly of an editing complex in this region may influence the cleavage selection process. In order to determine the extent that RNA editing and 3' end-processing interact, RNAs were analyzed to determine the extent of editing in precursor RNAs and to determine if unedited transcripts can be cleaved and polyadenylated. Two overlapping RNA junctions were analyzed; the junction between NADH dehydrogenase (ND) subunit 7 and cytochrome oxidase (CO) subunit III, and the junction between CO subunit II and maxicircle unidentified reading frame (MURF) II. For both of these RNAs, editing affects restriction endonuclease recognition sequences, allowing us to analyze editing patterns by differential restriction digests. These analyses suggest that when the gRNA is supplied in trans, RNA editing and cleavage/polyadenylation are independent events and while they may influence one another, one event is not dependent on the other. Conversely, for the COII transcript, where the gRNA is located at the 3' end of the mRNA and appears to be supplied in cis, edited precursors were not detected. This suggests a requirement for a precise intramolecular interaction for COII editing that cannot form prior to 3' end-maturation.

Kinetoplast maxicircle DNA replication in Crithidia fasciculata and Trypanosoma brucei

Kinetoplast DNA, the mitochondrial DNA of trypanosomatids, is composed of several thousand minicircles and a few dozen maxicircles, all of which are topologically interlocked in a giant network. We have studied the replication of maxicircle DNA, using electron microscopy to analyze replication intermediates from both Crithidia fasciculata and Trypanosoma brucei. Replication intermediates were stabilized against branch migration by introducing DNA interstrand cross-links in vivo with 4,5',8-trimethylpsoralen and UV radiation. Electron microscopy of individual maxicircles resulting from a topoisomerase II decatenation of kinetoplast DNA networks revealed intact maxicircle theta structures. Analysis of maxicircle DNA linearized by restriction enzyme cleavage revealed branched replication intermediates derived from theta structures. Measurements of the linearized branched molecules in both parasites indicate that replication initiates in the variable region (a noncoding segment characterized by repetitive sequences) and proceeds unidirectionally, clockwise on the standard map.

Developmental regulation of mitochondrial biogenesis in Trypanosoma brucei

The metabolism of Trypanosoma brucei undergoes a significant change as the parasite differentiates from the mammalian bloodstream form to the form found in the tse-tse fly vector. Because the mitochondria of bloodstream form cells lack cytochromes and several key citric acid cycle enzymes, the metabolism of these cells is mostly limited to glycolysis. The reducing equivalents generated by this process are passed to oxygen by a plant-like alternative oxidase. As cells differentiate to the insect form, they begin to oxidatively metabolize proline. The mitochondria of insect form cells contain functional, cytochrome-mediated electron transport chains and have complete complements of citric acid cycle enzymes. Although the characterization is far from complete, the nuclear and mitochondrial genes involved in the expression of these mitochondrial functions appear to be developmentally regulated at posttranscriptional and posttranslational levels. This review outlines some of the molecular processes that are associated with the developmental regulation of mitochondrial biogenesis and suggests some possible mechanisms of regulation.

Structural organization of the maxicircle variable region of Trypanosoma brucei: identification of potential replication origins and topoisomerase II binding sites

The maxicircle of the parasitic protozoan Trypanosoma brucei, one component of the mitochondrial genome, has size differences among isolates that localize to the variable region (VR) between the ND5 and 12S rRNA genes. We present here the nucleotide sequence of this entire region, thus completing the sequence of the maxicircle genome. We also find heterogeneously sized transcripts from throughout most of the VR. The VR has three distinct sections, each with characteristic repeated sequences. The repeated sequences in two sections are short and highly reiterated; the intraspecies size variation occurs within this region. The third section contains non-repetitive sequences and a large duplication immediately upstream of the 12S rRNA gene. Two repeat units within section I contain a sequence that has homology to the DNA replication origin of minicircles. This region also contains sequences with homology to topoisomerase II binding and cleavage sites. These findings suggest a role for the VR in DNA replication of the maxicircle.

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.