tRNAs of Trypanosoma brucei. Unusual gene organization and mitochondrial importation

Trypanosomes as a magnifying glass for cell and molecular biology

The African trypanosome, Trypanosoma brucei, has developed into a flexible and robust experimental model for molecular and cellular parasitology, allowing us to better combat these and related parasites that cause worldwide suffering. Diminishing case numbers, due to efficient public health efforts, and recent development of new drug treatments have reduced the need for continued study of T. brucei in a disease context. However, we argue that this pathogen has been instrumental in revolutionary discoveries that have widely informed molecular and cellular biology and justifies continuing research as an experimental model. Ongoing work continues to contribute towards greater understanding of both diversified and conserved biological features. We discuss multiple examples where trypanosomes pushed the boundaries of cell biology and hope to inspire researchers to continue exploring these remarkable protists as tools for magnifying the inner workings of cells.

The metazoan landscape of mitochondrial DNA gene order and content is shaped by selection and affects mitochondrial transcription

Mitochondrial DNA (mtDNA) harbors essential genes in most metazoans, yet the regulatory impact of the multiple evolutionary mtDNA rearrangements has been overlooked. Here, by analyzing mtDNAs from ~8000 metazoans we found high gene content conservation (especially of protein and rRNA genes), and codon preferences for mtDNA-encoded tRNAs across most metazoans. In contrast, mtDNA gene order (MGO) was selectively constrained within but not between phyla, yet certain gene stretches (ATP8-ATP6, ND4-ND4L) were highly conserved across metazoans. Since certain metazoans with different MGOs diverge in mtDNA transcription, we hypothesized that evolutionary mtDNA rearrangements affected mtDNA transcriptional patterns. As a first step to test this hypothesis, we analyzed available RNA-seq data from 53 metazoans. Since polycistron mtDNA transcripts constitute a small fraction of the steady-state RNA, we enriched for polycistronic boundaries by calculating RNA-seq read densities across junctions between gene couples encoded either by the same strand (SSJ) or by different strands (DSJ). We found that organisms whose mtDNA is organized in alternating reverse-strand/forward-strand gene blocks (mostly arthropods), displayed significantly reduced DSJ read counts, in contrast to organisms whose mtDNA genes are preferentially encoded by one strand (all chordates). Our findings suggest that mtDNA rearrangements are selectively constrained and likely impact mtDNA regulation.

Preferential import of queuosine-modified tRNAs into Trypanosoma brucei mitochondrion is critical for organellar protein synthesis

Transfer RNAs (tRNAs) are key players in protein synthesis. To be fully active, tRNAs undergo extensive post-transcriptional modifications, including queuosine (Q), a hypermodified 7-deaza-guanosine present in the anticodon of several tRNAs in bacteria and eukarya. Here, molecular and biochemical approaches revealed that in the protozoan parasite Trypanosoma brucei, Q-containing tRNAs have a preference for the U-ending codons for asparagine, aspartate, tyrosine and histidine, analogous to what has been described in other systems. However, since a lack of tRNA genes in T. brucei mitochondria makes it essential to import a complete set from the cytoplasm, we surprisingly found that Q-modified tRNAs are preferentially imported over their unmodified counterparts. In turn, their absence from mitochondria has a pronounced effect on organellar translation and affects function. Although Q modification in T. brucei is globally important for codon selection, it is more so for mitochondrial protein synthesis. These results provide a unique example of the combined regulatory effect of codon usage and wobble modifications on protein synthesis; all driven by tRNA intracellular transport dynamics.

Mitochondria, Telomeres and Telomerase Subunits

Mitochondrial functions and telomere functions have mostly been studied independently. In recent years, it, however, has become clear that there are intimate links between mitochondria, telomeres, and telomerase subunits. Mitochondrial dysfunctions cause telomere attrition, while telomere damage leads to reprogramming of mitochondrial biosynthesis and mitochondrial dysfunctions, which has important implications in aging and diseases. In addition, evidence has accumulated that telomere-independent functions of telomerase also exist and that the protein component of telomerase TERT shuttles between the nucleus and mitochondria under oxidative stress. Our previously published data show that the RNA component of telomerase TERC is also imported into mitochondria, processed, and exported back to the cytosol. These data show a complex regulation network where telomeres, nuclear genome, and mitochondria are co-regulated by multi-localization and multi-function proteins and RNAs. This review summarizes the connections between mitochondria and telomeres, the mitochondrion-related functions of telomerase subunits, and how they play a role in crosstalk between mitochondria and the nucleus.

Unusual noncanonical intron editing is important for tRNA splicing in Trypanosoma brucei

In cells, tRNAs are synthesized as precursor molecules bearing extra sequences at their 5' and 3' ends. Some tRNAs also contain introns, which, in archaea and eukaryotes, are cleaved by an evolutionarily conserved endonuclease complex that generates fully functional mature tRNAs. In addition, tRNAs undergo numerous posttranscriptional nucleotide chemical modifications. In Trypanosoma brucei, the single intron-containing tRNA (tRNA(Tyr)GUA) is responsible for decoding all tyrosine codons; therefore, intron removal is essential for viability. Using molecular and biochemical approaches, we show the presence of several noncanonical editing events, within the intron of pre-tRNA(Tyr)GUA, involving guanosine-to-adenosine transitions (G to A) and an adenosine-to-uridine transversion (A to U). The RNA editing described here is required for proper processing of the intron, establishing the functional significance of noncanonical editing with implications for tRNA processing in the deeply divergent kinetoplastid lineage and eukaryotes in general.

Signal recognition particle RNA in dinoflagellates and the Perkinsid Perkinsus marinus

In dinoflagellates and perkinsids, the molecular structure of the protein translocating machinery is unclear. Here, we identified several types of full-length signal recognition particle (SRP) RNA genes from Karenia brevis (dinoflagellate) and Perkinsus marinus (perkinsid). We also identified the four SRP S-domain proteins, but not the two Alu domain proteins, from P. marinus and several dinoflagellates. We mapped both ends of SRP RNA transcripts from K. brevis and P. marinus, and obtained the 3' end from four other dinoflagellates. The lengths of SRP RNA are predicted to be ∼260-300 nt in dinoflagellates and 280-285 nt in P. marinus. Although these SRP RNA sequences are substantially variable, the predicted structures are similar. The genomic organization of the SRP RNA gene differs among species. In K. brevis, this gene is located downstream of the spliced leader (SL) RNA, either as SL RNA-SRP RNA-tRNA gene tandem repeats, or within a SL RNA-SRP RNA-tRNA-U6-5S rRNA gene cluster. In other dinoflagellates, SRP RNA does not cluster with SL RNA or 5S rRNA genes. The majority of P. marinus SRP RNA genes array as tandem repeats without the above-mentioned small RNA genes. Our results capture a snapshot of a potentially complex evolutionary history of SRP RNA in alveolates.

Transfer RNA travels from the cytoplasm to organelles

Transfer RNAs (tRNAs) encoded by the nuclear genome are surprisingly dynamic. Although tRNAs function in protein synthesis occurring on cytoplasmic ribosomes, tRNAs can transit from the cytoplasm to the nucleus and then again return to the cytoplasm by a process known as the tRNA retrograde process. Subsets of the cytoplasmic tRNAs are also imported into mitochondria and function in mitochondrial protein synthesis. The numbers of tRNA species that are imported into mitochondria differ among organisms, ranging from just a few to the entire set needed to decode mitochondrially encoded mRNAs. For some tRNAs, import is dependent on the mitochondrial protein import machinery, whereas the majority of tRNA mitochondrial import is independent of this machinery. Although cytoplasmic proteins and proteins located on the mitochondrial surface participating in the tRNA import process have been described for several organisms, the identity of these proteins differ among organisms. Likewise, the tRNA determinants required for mitochondrial import differ among tRNA species and organisms. Here, we present an overview and discuss the current state of knowledge regarding the mechanisms involved in the tRNA retrograde process and continue with an overview of tRNA import into mitochondria. Finally, we highlight areas of future research to understand the function and regulation of movement of tRNAs between the cytoplasm and organelles.

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.

Mitochondrial tRNA import--the challenge to understand has just begun

Mitochondrial translation is important for the synthesis of proteins involved in oxidative phosphorylation, which yields the bulk of the ATP made in cells. During evolution most mitochondria-containing organisms have lost tRNA genes from their mitochondrial genomes. Thus, to support the essential process of nuanced mitochondrial translation, mechanisms to actively transport tRNAs from the cytoplasm across the mitochondrial membranes into the mitochondrion have evolved. Here, we review the currently known tRNA import mechanisms, comment on recent discoveries of various import factors, and suggest a rationale for forces that lie behind the evolution of mitochondrial tRNA import.

Mitochondrial tRNA import in Trypanosoma brucei is independent of thiolation and the Rieske protein

Due to a complete lack of the tRNA genes in the mitochondrial genome of Trypanosoma brucei, all tRNAs needed for mitochondrial translation have to be imported into the organelle from the cytosol. A previous study showed that the modified nucleotide s(2)U could act as a negative determinant for mitochondrial tRNA import in another kinetoplastid, Leishmania tarentolae. We have investigated whether the same type of cytosolic control for tRNA retention exists in T. brucei. Based on Northern analysis with subcellular RNA fractions and in vitro import assays, we demonstrate that silencing of the cysteine desulfurase, TbNfs (TbIscS), the key enzyme in tRNA thiolation (s(2)U) and Fe-S cluster formation in vivo, has no effect on tRNA partitioning. This observation is especially surprising in light of a recent report suggesting that in L. tropica the Rieske Fe-S protein is an essential component of the RNA import complex (RIC). In line with the above observation, we also show that down-regulation of the Rieske protein by RNA interference, similar to the TbNfs knockdowns, has no effect on import. The data presented here supports the view that in T. brucei: (1) s(2)U is not a negative determinant for tRNA import; (2) the Rieske protein is not an essential component of the import machinery, and (3) since the Rieske protein is essential for respiration and maintenance of inner mitochondrial membrane potential, neither process plays a critical role in tRNA import. We therefore suggest that the T. brucei import machinery differs substantially from what has been described in Leishmania.

Specific features of 5S rRNA structure - its interactions with macromolecules and possible functions

Small non-coding RNAs are today a topic of great interest for molecular biologists because they can be regarded as relicts of a hypothetical "RNA world" which, apparently, preceded the modern stage of organic evolution on Earth. The small molecule of 5S rRNA (approximately 120 nucleotides) is a component of large ribosomal subunits of all living beings (5S rRNAs are not found only in mitoribosomes of fungi and metazoans). This molecule interacts with various protein factors and 23S (28S) rRNA. This review contains the accumulated data to date concerning 5S rRNA structure, interactions with other biological macromolecules, intracellular traffic, and functions in the cell.

On the evolution and expression of Chlamydomonas reinhardtii nucleus-encoded transfer RNA genes

In Chlamydomonas reinhardtii, 259 tRNA genes were identified and classified into 49 tRNA isoaccepting families. By constructing phylogenetic trees, we determined the evolutionary history for each tRNA gene family. The majority of the tRNA sequences are more closely related to their plant counterparts than to animals ones. Northern experiments also permitted us to show that at least one member of each tRNA isoacceptor family is transcribed and correctly processed in vivo. A short stretch of T residues known to be a signal for termination of polymerase III transcription was found downstream of most tRNA genes. It allowed us to propose that the vast majority of the tRNA genes are expressed and to confirm that numerous tRNA genes separated by short spacers are indeed cotranscribed. Interestingly, in silico analyses and hybridization experiments show that the cellular tRNA abundance is correlated with the number of tRNA genes and is adjusted to the codon usage to optimize translation efficiency. Finally, we studied the origin of SINEs, short interspersed elements related to tRNAs, whose presence in Chlamydomonas is exceptional. Phylogenetic analysis strongly suggests that tRNA(Asp)-related SINEs originate from a prokaryotic-type tRNA either horizontally transferred from a bacterium or originally present in mitochondria or chloroplasts.

Protein targeting in parasites with cryptic mitochondria

Many highly specialised parasites have adapted to their environments by simplifying different aspects of their morphology or biochemistry. One interesting case is the mitochondrion, which has been subject to strong reductive evolution in parallel in several different parasitic groups. In extreme cases, mitochondria have degenerated so much in physical size and functional complexity that they were not immediately recognised as mitochondria, and are now referred to as 'cryptic'. Cryptic mitochondrion-derived organelles can be classified as either hydrogenosomes or mitosomes. In nearly all cases they lack a genome and all organellar proteins are nucleus-encoded and expressed in the cytosol. The same is true for the majority of proteins in canonical mitochondria, where the proteins are directed to the organelle by specific targeting sequences (transit peptides) that are recognised by translocases in the mitochondrial membrane. In this review, we compare targeting sequences of different parasitic systems with highly reduced mitochondria and give an overview of how the import machinery has been modified in hydrogenosomes and mitosomes.

A sequence motif within trypanosome precursor tRNAs influences abundance and mitochondrial localization

Trypanosoma brucei lacks mitochondrial genes encoding tRNAs and must import nuclearly encoded tRNAs from the cytosol. The mechanism and specificity of this process remain unclear. We have identified a unique sequence motif, YGG(C/A)RRC, upstream of the genes encoding mitochondrially localized tRNAs in T. brucei. Both in vitro import studies and in vivo transfection studies indicate that deletion of the YGG(C/A)RRC sequence alters mitochondrial localization of tRNA(Leu), and in vivo studies also show a decrease in the cellular abundance of tRNA(Leu). These studies provide direct evidence for cis-acting RNA motifs within precursor tRNAs that facilitate the selection of tRNAs for mitochondrial import in trypanosomes. Furthermore, we found that mutations to the YGG(C/A)RRC sequence also altered the intracellular distribution of other endogenous tRNAs, suggesting a general role for this sequence in tRNA trafficking in trypanosomes.

Identification and comparative analysis of components from the signal recognition particle in protozoa and fungi

Background

The signal recognition particle (SRP) is a ribonucleoprotein complex responsible for targeting proteins to the ER membrane. The SRP of metazoans is well characterized and composed of an RNA molecule and six polypeptides. The particle is organized into the S and Alu domains. The Alu domain has a translational arrest function and consists of the SRP9 and SRP14 proteins bound to the terminal regions of the SRP RNA. So far, our understanding of the SRP and its evolution in lower eukaryotes such as protozoa and yeasts has been limited. However, genome sequences of such organisms have recently become available, and we have now analyzed this information with respect to genes encoding SRP components.

Results

A number of SRP RNA and SRP protein genes were identified by an analysis of genomes of protozoa and fungi. The sequences and secondary structures of the Alu portion of the RNA were found to be highly variable. Furthermore, proteins SRP9/14 appeared to be absent in certain species. Comparative analysis of the SRP RNAs from different Saccharomyces species resulted in models which contain features shared between all SRP RNAs, but also a new secondary structure element in SRP RNA helix 5. Protein SRP21, previously thought to be present only in Saccharomyces, was shown to be a constituent of additional fungal genomes. Furthermore, SRP21 was found to be related to metazoan and plant SRP9, suggesting that the two proteins are functionally related.

Conclusions

Analysis of a number of not previously annotated SRP components show that the SRP Alu domain is subject to a more rapid evolution than the other parts of the molecule. For instance, the RNA portion is highly variable and the protein SRP9 seems to have evolved into the SRP21 protein in fungi. In addition, we identified a secondary structure element in the Sacccharomyces RNA that has been inserted close to the Alu region. Together, these results provide important clues as to the structure, function and evolution of SRP.

tRNAs in Trypanosoma brucei: genomic organization, expression, and mitochondrial import

The mitochondrial genome of Trypanosoma brucei does not encode tRNAs. Consequently, all mitochondrial tRNAs are imported from the cytosol and originate from nucleus-encoded genes. Analysis of all currently available T. brucei sequences revealed that its genome carries 50 tRNA genes representing 40 different isoacceptors. The identified set is expected to be nearly complete since all but four codons are accounted for. The number of tRNA genes in T. brucei is very low for a eukaryote and lower than those of many prokaryotes. Using quantitative Northern analysis we have determined the absolute abundance in the cell and the mitochondrion of a group of 15 tRNAs specific for 12 amino acids. Except for the initiator type tRNA(Met), which is cytosol specific, the cytosolic and the mitochondrial sets of tRNAs were qualitatively identical. However, the extent of mitochondrial localization was variable for the different tRNAs, ranging from 1 to 7.5% per cell. Finally, by using transgenic cell lines in combination with quantitative Northern analysis it was shown that import of tRNA(Leu)(CAA) is independent of its 5'-genomic context, suggesting that the in vivo import substrate corresponds to the mature, fully processed tRNA.

Mutations in a tRNA import signal define distinct receptors at the two membranes of Leishmania mitochondria

Nucleus-encoded tRNAs are selectively imported into the mitochondrion of Leishmania, a kinetoplastid protozoan. An oligoribonucleotide constituting the D stem-loop import signal of tRNA(Tyr)(GUA) was efficiently transported into the mitochondrial matrix in organello as well as in vivo. Transfer through the inner membrane could be uncoupled from that through the outer membrane and was resistant to antibody against the outer membrane receptor TAB. A number of mutations in the import signal had differential effects on outer and inner membrane transfer. Some mutants which efficiently traversed the outer membrane were unable to enter the matrix. Conversely, restoration of the loop-closing GC pair in reverse resulted in reversion of transfer through the inner, but not the outer, membrane, and binding of the RNA to the inner membrane was restored. These experiments indicate the presence at the two membranes of receptors with distinct specificities which mediate stepwise transfer into the mitochondrial matrix. The combination of oligonucleotide mutagenesis and biochemical fractionation may provide a general tool for the identification of tRNA transport factors.

The trans-spliceosomal U4 RNA from the monogenetic trypanosomatid Leptomonas collosoma. Cloning and identification of a transcribed trna-like element that controls its expression

U4 small nuclear RNA is essential for trans-splicing. Here we report the cloning of U4 snRNA gene from Leptomonas collosoma and analysis of elements controlling its expression. The trypanosome U4 RNA is the smallest known, it carries an Sm-like site, and has the potential for extensive intermolecular base pairing with the U6 RNA. Sequence analysis of the U4 locus indicates the presence of a tRNA-like element 86 base pairs upstream of the gene that is divergently transcribed to yield a stable small tRNA-like RNA. Two additional tRNA genes, tRNA(Pro) and tRNA(Gly), were found upstream of this element. By stable expression of a tagged U4 RNA, we demonstrate that the tRNA-like gene, but not the upstream tRNA genes, is essential for U4 expression and that the B box but not the A Box of the tRNA-like gene is crucial for expression in vivo. Mapping the 2'-O-methyl groups on U4 and U6 small nuclear RNAs suggests the presence of modifications in canonical positions. However, the number of modified nucleotides is fewer than in mammalian homologues. The U4 genomic organization including both tRNA-like and tRNA genes may represent a relic whereby trypanosomatids "hired" tRNA genes to provide extragenic promoter elements. The close proximity of tRNA genes to the tRNA-like molecule in the U4 locus further suggests that the tRNA-like gene may have evolved from a tRNA member of this cluster.

Stepwise transfer of tRNA through the double membrane of Leishmania mitochondria

Import of tRNA into Leishmania mitochondria involves transfer through a double membrane barrier. To examine whether specific sorting mechanisms for individual tRNAs direct them to different mitochondrial compartments, the distribution of tRNA transcripts, internalized in vitro, was examined by suborganellar fractionation. Significant amounts of tRNA(Tyr) were localized in the matrix and on the outer face of the inner mitochondrial membrane. With time, the matrix:membrane ratio increased. Translocation through the inner membrane apparently required the presence of a specific signal in the D arm of tRNA(Tyr), and tRNA(Gln)(CUG), lacking this sequence, was excluded. Hydrolysis of ATP was necessary at both the outer and inner membranes. However, the protonophores carbonylcyanide m-chlorophenylhydrazone and nigericin, the K(+) ionophore valinomycin, and the F(1)F(0) ATPase inhibitor oligomycin had only marginal effects on uptake through the outer membrane but severely inhibited inner membrane translocation, indicating the unusual requirement of both the electrical and chemical components of the electromotive force generated across the inner membrane. The results are consistent with a mechanism involving stepwise transfer of tRNA through distinct outer and inner membrane channels.

In vitro import of a nuclearly encoded tRNA into the mitochondrion of Trypanosoma brucei

All of the mitochondrial tRNAs of Trypanosoma brucei have been shown to be encoded in the nucleus and must be imported into the mitochondrion. The import of nuclearly encoded tRNAs into the mitochondrion has been demonstrated in a variety of organisms and is essential for proper function in the mitochondrion. An in vitro import assay has been developed to study the pathway of tRNA import in T. brucei. The in vitro system utilizes crude isolated trypanosome mitochondria and synthetic RNAs transcribed from a cloned nucleus-encoded tRNA gene cluster. The substrate, composed of tRNA(Ser) and tRNA(Leu), is transcribed in tandem with a 59-nucleotide intergenic region. The tandem tRNA substrate is imported rapidly, while the mature-size tRNA(Leu) fails to be imported in this system. These results suggest that the preferred substrate for tRNA import into trypanosome mitochondria is a precursor molecule composed of tandemly linked tRNAs. Import of the tandem tRNA substrate requires (i) a protein component that is associated with the surface of the mitochondrion, (ii) ATP pools both outside and within the mitochondrion, and (iii) a membrane potential. Dissipation of the proton gradient across the inner mitochondrial membrane by treatment with an uncoupling agent inhibits import of the tandem tRNA substrate. Characterization of the import requirements indicates that mitochondrial RNA import proceeds by a pathway including a protein component associated with the outer mitochondrial membrane, ATP-dependent steps, and a mitochondrial membrane potential.

tRNAs and proteins are imported into mitochondria of Trypanosoma brucei by two distinct mechanisms

Import of tRNA into the mitochondrial matrix of Trypanosoma brucei was reconstituted in vitro. Efficient import required the hydrolysis of externally added ATP and was shown to be a carrier-mediated process depending on proteinaceous receptors on the surface of mitochondria. A partly synthetic tRNA(Tyr) as well as a physiological tRNA(Lys) were imported along the same pathway. Contrary to import of all matrix-localized proteins, tRNA import does not require a membrane potential. Furthermore, addition of an excess of import-competent tRNA had no effect on import of a mitochondrial matrix protein. In summary, these results show that tRNAs and proteins in T. brucei are imported by fundamentally different mechanisms.

A nuclear encoded and mitochondrial imported dicistronic tRNA precursor in Trypanosoma brucei

The mitochondrial tRNAs of Trypanosoma brucei are nuclear encoded and imported into the mitochondrion. A heterogeneous population of RNAs having characteristics of precursor tRNAs have previously been identified within the mitochondrion of T. brucei, suggesting that import occurs via a precursor molecule. In order to identify nuclear genes encoding tRNAs targeted to the mitochondrion, individual mitochondrial tRNAs were separated using two-dimensional gel electrophoresis and enzymatically sequenced. A 1.1-kilobase pair genomic DNA fragment was cloned containing three tRNA genes, tRNA(1)(Ser), tRNA(Leu), and tRNA(2)(Ser). Dicistronic precursors containing the tRNA(1)(Ser) and tRNA(Leu) transcripts with a 59-nucleotide intergenic sequence were identified by reverse transcriptase and polymerase chain reactions and the 5' end of the precursors determined. The dicistronic precursor tRNA is present both in the cytosol and the mitochondrion supporting a model for tRNA import involving precursor tRNA transcripts.

In vivo import of unspliced tRNATyr containing synthetic introns of variable length into mitochondria of Leishmania tarentolae

The mitochondrial genomes of trypanosomatids lack tRNA genes. Instead, mitochondrial tRNAs are encoded and synthesized in the nucleus and are then imported into mitochondria. This also applies for tRNATyr, which in trypanosomatids contains an 11 nt intron. Previous work has defined an exon mutation which leads to accumulation of unspliced precursor tRNATyr. In this study we have used the splicing-deficient tRNATyr as a vehicle to introduce foreign sequences into the mitochondrion of Leishmania tarentolae. The naturally occurring intron was replaced by synthetic sequences of increasing length and the resulting tRNATyr precursors were expressed in transgenic cell lines. Whereas stable expression of precursor tRNAsTyr was obtained for introns up to a length of 76 nt, only precursors having introns up to 38 nt were imported into mitochondria. These results demonstrate that splicing-deficient tRNATyr can be used to introduce short synthetic sequences into mitochondria in vivo. In addition, our results show that one factor which limits the efficiency of import is the length of the molecule.

Expression and regulation of mitochondrial uncoupling protein 1 from brown adipose tissue in Leishmania major promastigotes

Rat uncoupling protein 1 (UCP1) was successfully translated in transfected Leishmania major promastigotes. Immune electron microscopy revealed that the protein was exclusively in the mitochondria. UCP1 expression was about 350,000 copies per promastigote, accounting for 4.7% of the total mitochondrial protein. In intact parasites, expression of UCP1 induced a slight increase in respiratory rate and a modest decrease in mitochondrial membrane potential (delta psi(m)). In contrast, in digitonin-permeabilized parasites, a significantly lower value both in delta psi(m) (57 +/- 10 vs 153 +/- 12 mV) and respiratory control ratio (0.99 vs 1.54) were observed for UCP1 versus control parasites, although when UCP1 activity was inhibited by bovine serum albumin (BSA) and GDP, control values were restored. Therefore, a fully functional UCP1 was present and only partially inhibited in vivo by endogenous purine nucleotides. However, neither ATP levels, growth rate nor mitochondrial protein import differed significantly between both types of parasites. Expression of the pore-like mutant UCP1 delta 9 was deleterious to the organism. Consequently, Leishmania was capable of expressing and importing into mitochondria proteins from higher eukaryotes lacking an N-terminal targeting pre-sequence as UCP1. As described previously, parasite metabolism had only a limited tolerance to mitochondrial disfunction. Transfection of Leishmania with foreign proteins which play an important regulatory role in metabolism is a useful tool to study both parasite metabolism in general, and alternative pathways involved in maintaining internal homeostasis.

Regulated tRNA import in Leishmania mitochondria

The genes for three new tRNA and a 5S RNA were identified from a genomic DNA clone of 917 nucleotide pairs from the protozoon Leishmania tarentolae. They were encoded in the following order. The transcriptional directions and anticodons are in parentheses: tRNA(Val) (CAC-->)-5SRNA (-->)-tRNA(His) (<--GUG)-tRNA(Phe) (GAA-->). The tRNA(His) and tRNA(Phe) sequences have not been reported previously in trypanosomatid organisms. By northern analysis, tRNA(Val) and tRNA(Phe) were equally distributed between the cytosol and mitochondria, while tRNA(His) was less abundant in mitochondria than in the cytosol. Accordingly, the latter tRNA is classified as Import restricted (Impr). As shown before, 5S RNA was not imported. Recently, Mahapatra and Adhya [S. Mahapatra, T. Ghosh, S. Adhya, Nucl. Acids Res. 22 (1994) 3381-3386; S. Mahapatra, S. Adhya, J. Biol. Chem. 271 (1996) 20432-20437] have developed an in vitro import system in Leishmania and suggested that the D-loop sequence could serve as the import determinant. We examined all available tRNA gene sequences in trypanosomatids but found no apparent consensus within the D-loop that might account for tRNA-import regulation.

Role of an RNA-binding protein in import of tRNA into Leishmania mitochondria

Nuclear-encoded cytoplasmic tRNAs are imported into the mitochondria of kinetoplastid protozoa by an unknown mechanism. In a Leishmania in organello system, ATP-dependent import of a cloned, unspliced tRNATyr(GUA) transcript was demonstrated by protection from ribonuclease, whereas import of a tRNAGln(CUG) transcript was much less efficient. Specific binding of tRNATyr to two mitochondrial surface proteins of 15 and 22 kilodaltons was observed. Tubulin antisense-binding protein (TAB), the 15-kilodaton species, was purified to apparent homogeneity by RNA affinity chromatography. TAB forms stable complexes with the D stem-loop region of tRNATyr. Immunocytochemical and cell fractionation experiments, combined with limited proteolysis, suggested the association of TAB with the outer mitochondrial membrane. Importantly, anti-TAB antibody specifically inhibited binding as well as import of tRNATyr and of a synthetic structural homolog. These results support the role of TAB as a membrane-bound receptor or carrier for RNA import into Leishmania mitochondria.

Leishmania tarentolae contains distinct cytosolic and mitochondrial glutaminyl-tRNA synthetase activities

The intracellular distribution of glutaminyl-tRNA synthetases and their role in mitochondrial tRNA import were evaluated in the ancient eukaryote Leishmania tarentolae. The following results were obtained: (i) Glutaminyl-tRNA synthetase was detected in leishmanial mitochondria. This was unexpected because it has been postulated that, in organelles, Gln-tRNAGln is not formed by direct acylation of tRNAGln but by enzymatic transamidation of misacylated Glu-tRNAGln. (ii) Whereas the cytosolic extract is able to charge cytosolic and mitochondrial tRNAsGln, the mitochondrial matrix extract does not aminoacylate the cytosol-specific tRNAGln. This indicates that mitochondrial and cytosolic glutaminyl-tRNA synthetases are distinct. (iii) Seven of the 11 nucleotides that differ between the cytosolic and the mitochondrial tRNAGln are sufficient to convert the cytosol-specific tRNAGln into an optimal substrate for the mitochondrial enzyme. These nucleotides are arranged in three groups consisting of the nucleotides flanking the anticodon stem, the 5' nucleotide of the anticodon, and four nucleotides within the acceptor stem. And (iv), it was shown that the identity elements for recognition by the mitochondrial glutaminyl-tRNA synthetase do not overlap with a previously identified sequence segment required for mitochondrial import of the tRNAGln.

Import of RNA into Leishmania mitochondria occurs through direct interaction with membrane-bound receptors

Cytoplasmic tRNAs are imported into the kinetoplast mitochondrion of Leishmania, but the mechanism of import is unknown, particularly whether RNA is transferred as a ribonucleoprotein complex through the protein import pathway or by a distinct receptor-mediated mechanism. Using isolated mitochondria, it was shown that a small, importable RNA, which is structurally homologous to tRNA, binds rapidly, specifically, and with high affinity to the mitochondrial surface in the absence of soluble protein factors to form an import intermediate. Two classes of binding site of apparent Kd 0.3 and 10 n, respectively, were distinguished. tRNA from Leishmania, but not yeast, competitively inhibited the binding. Northwestern blot analysis revealed the presence of a 15-kDa RNA binding protein on the mitochondrial surface. Whereas receptor binding was resistant to heparin and KCl, internalization was sensitive to both reagents. These results are consistent with the presence of a direct mechanism of receptor-mediated RNA import on Leishmania mitochondria.

Cytosolic yeast tRNA(His) is covalently modified when imported into mitochondria of Trypanosoma brucei

The mitochondrial genome of Trypanosoma brucei does not encode any tRNAs. Instead, mitochondrial tRNAs are synthesized in the nucleus and subsequently imported into mitochondria. The great majority of mitochondrial tRNAs have cytosolic counterparts showing identical primary sequences. The only difference found between mitochondrial and cytosolic isotypes of the tRNAs are mitochondria-specific nucleotide modifications which appear to be a common feature of imported tRNAs in trypanosomes. In this study, a mutated yeast cytosolic tRNAHis was expressed in trypanosomes and its import phenotype was analyzed by cell fractionation and nuclease treatment of intact mitochondria. Furthermore, cytosolic and mitochondrial isotypes of the yeast tRNA(His) were specifically labeled and analyzed by limited alkaline hydrolysis. These experiments revealed the presence of mitochondria-specific nucleotide modifications in the yeast tRNA(His). The positions of the modifications were determined by direct enzymatic sequencing of the tRNA(His) and shown to correspond to the ultimate and penultimate nucleotides before the anticodon, the same relative positions which are modified in the mitochondrial isotype of trypanosomal tRNA(Tyr). The results demonstrate that covalent modification of tRNAs; in trypanosomal mitochondria can be used, in analogy to processing of precursor proteins during mitochondrial protein import, as a marker for import of both endogenous and heterologous tRNAs.

In vitro import of proteins into mitochondria of Trypanosoma brucei and Leishmania tarentolae

In eukaryotic evolution, the earliest branch of organisms to have mitochondria are the trypanosomatids. Their mitochondrial biogenesis not only includes import of most proteins, but also, unlike in other organisms, import of the whole set of tRNAs. In order to investigate these processes, we devised novel procedures for the isolation of mitochondria from two trypanosomatid species: Trypanosoma brucei and Leishmania tarentolae. Isotonic cell lysis followed by equilibrium density centrifugation in Nycodenz gradients yielded mitochondrial fractions exhibiting a membrane potential. Furthermore, we have used these fractions to reconstitute import of mitochondrial matrix proteins in vitro. Energy-dependent uptake of an artificial precursor protein, containing a trypanosomal presequence attached to mouse dihydrofolate reductase and of yeast mitochondrial alcohol dehydrogenase could be demonstrated. The presequences of both proteins were processed in T. brucei whereas only the trypanosomal one was cleaved in L. tarentolae. Trypsin pretreatment abolished the ability of the mitochondria to import proteins, indicating the involvement of proteinaceous components at the surface of mitochondria.

Unexpected diversity in U6 snRNA sequences from trypanosomatids

We have isolated and sequenced the genes for the trans-spliceosomal U6 small nuclear RNAs (snRNAs) from the trypanosomatid species Leishmania mexicana (Lm) and Phytomonas sp. (Ps). Compared with the Trypanosoma brucei (Tb) U6 snRNA, the Lm U6 snRNA contains only a single additional G-C bp in the 5' terminal stem-loop. In contrast, the Ps U6 snRNA sequence contains a G-->C change at the last nucleotide of the highly conserved and functionally important ACAGAG hexanucleotide and three additional changes in conserved positions. Our results indicate that trans-spliceosomal U6 snRNAs from trypanosomatid species do not always conform to the consensus sequence of cis-spliceosomal U6 snRNAs.

Mitochondrial genome repositioning during the differentiation of the African trypanosome between life cycle forms is microtubule mediated

The cell cycle of the African trypanosome requires a precise orchestration of nuclear and mitochondrial genome (kinetoplast) positioning to ensure faithful segregation during division. The controls underlying these events must be subject to modulation, however, as the respective positioning of these organelles changes during the parasite's complex life cycle. We have studied mitochondrial DNA repositioning during differentiation between the trypanosome's bloodstream and procyclic form. We have found that repositioning occurs simultaneously with the DNA replication phase of the cell cycle of the differentiating parasite. Furthermore, we demonstrate, at the cell and individual microtubule level, that this organelle repositioning is achieved via microtubule-dependent processes. Our results have implications for the control of cell differentiation and division in African trypanosomes.

The U6 snRNA-encoding gene of the monogenetic trypanosomatid Leptomonas collosoma

The U6 snRNA (U6) is the most conserved small nuclear RNA (snRNA) and apparently plays a central role in catalysis of the cis-splicing reaction. In trans-splicing, U6 may have an additional function. In the nematode trans-splicing system, a direct interaction between the U6 and spliced leader (SL) RNAs has been demonstrated, suggesting that U6 may serve as a bridge between the SL RNA and the acceptor pre-mRNA. To examine possible phylogenetic conservation of trypanosomatid U6 sequences that may interact with spliceosomal RNAs, we have cloned and sequenced the U6 gene from the monogenetic trypanosomatid Leptomonas collosoma (Lc). The Lc U6 deviates from the Trypanosoma brucei (Tb) RNA only in four positions located in the 5' stem-loop and the central domains. As in Tb, U6 is a single-copy gene and two tRNA genes, tRNAGln and tRNAIle, are found upstream to the gene. The tRNAs are differentially expressed; tRNAGln is transcribed in the opposite direction to U6, whereas tRNAIle is not transcribed. Possible base-pairing between U6 and the U2 and SL RNAs, similar to the interactions that take place in the nematode trans-splicing system, are proposed.

Import of RNA into mitochondria

RNAs that function in mitochondria, in contrast to the majority of mitochondrial proteins, are generally encoded by the mitochondrial genome. However, evidence has been presented for transport of nucleus-encoded tRNAs into mitochondria in diverse organisms. While mitochondrial protein import has been characterized in great detail, virtually nothing is known about the pathway of RNA import into mitochondria. Only very recently have in vivo systems for RNA import been established, and these are now providing some insight into this intriguing process.

Karyotype analysis of the monogenetic trypanosomatid Leptomonas collosoma

In order to develop a genetic system for the monogenetic trypanosomatids, we have analyzed the molecular karyotype of Leptomonas collosoma based on chromosome separation by clamped homogeneous electric field (CHEF) gel electrophoresis. The chromosome location of 5 RNA coding genes (SL, U6, 5S, 7SL and rRNA) and 2 protein coding genes (for HSP83 and alpha-tubulin) was determined. All of the L. collosoma genes examined were found on at least 2 chromosomes, which differ in size in the range of 100-500 kb, suggesting that the organism is diploid. The weighted sum of L. collosoma chromosomes separated by CHEF analysis was approximately 62 +/- 3 Mb, whereas the genome size determined by FACS was estimated at approx. 80 Mb. This suggests that some of the homologous chromosomes differ in their size. The analysis presented here may facilitate studies on the function of individual genes, and on the genetic stability of this organism.

A nuclear tRNA gene cluster in the protozoan Leishmania tarentolae and differential distribution of nuclear-encoded tRNAs between the cytosol and mitochondria

All mitochondrial tRNAs in the protozoan Leishmania are believed to be encoded in the nuclear genome and imported selectively into the mitochondria by an as yet unknown mechanism. Previously, we reported that two tRNAs whose genes are tightly linked were imported by mitochondria. In contrast, a tRNA encoded by a lone tRNA gene was not detectable in mitochondria. The lone tRNA gene had flanking sequences that were different from the linked genes. These studies implied a possible correlation between tRNA gene organization and gene flanking sequence, and selective tRNA import into mitochondria. Here, we report the identification of a cluster of 10 tRNA genes and show the distribution of the corresponding tRNAs in cytosolic and mitochondrial fractions. tRNA(leu)(CAG) and tRNA2(arg)(TCG) are abundant in the cytosol, but relatively scarce in mitochondria. Conversely, tRNA(ile)(TAT) and tRNA1(lys)(TTT) are abundant in mitochondria, but relatively scarce in the cytosol. tRNA(val)(TAC) and tRNA2(thr)(TGT) are barely detectable in either cellular compartment, while tRNA(gln)(TTG), tRNA1(arg)(ACG), tRNA(gly)(TCC), and tRNA(trp)(CCA) are detected in approximately equal levels in both compartments. Sequencing of the 2600 bp that comprise the tRNA gene cluster also encoding the genes for 5S RNA and URNAB RNA indicates that nucleotide composition, length, and location of genes within the cluster do not clearly correlate with import characteristics. The unexpected presence of the tRNA(trp)(CCA)-gene transcript in mitochondria is also reported. Evidence suggests that this tRNA may have unidentified base modifications at the anticodon triplet.

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.

In vivo expression and mitochondrial import of normal and mutated tRNA(thr) in Leishmania

Evidence suggests that mitochondria of protozoans and plants contain nuclear-encoded tRNAs. In trypanosomatids, the entire set of tRNAs in the mitochondria are presumably imported from the nucleus, but the mechanism of tRNA import is not presently understood. In this study, we have employed a plasmid-encoded nuclear tRNA gene as a means of investigating tRNA expression and mitochondrial import in vivo in Leishmania tarentolae. Using a Leishmania plasmid, we cloned a 1-kb or 250-bp restriction fragment carrying the nuclear tRNA(thr) gene and three in vitro mutagenized derivatives: Tac6 (an insertion of 6 nucleotides at the anticodon loop), Td4 (a 4-nt insert at the D-loop) and Tv4 (a 4-nt insert at the variable arm). Leishmania cells stably transfected with these plasmids were then examined for tRNA expression and import by Northern analysis. The results show that the plasmid-encoded wild type tRNA(thr) gene produced a significantly elevated level of expression in the cytosol. Similarly, the Tac6-transfected cells exhibited a large abundance of the mutant RNA relative to the normal tRNA (chromosome-encoded gene transcripts) in the cytosol. Furthermore, the mutant Tac6 RNA was found imported into mitochondria, although the proportion of the mutant vs. normal tRNA in mitochondria was greatly reduced as compared to that in the cytosol. We suggest that the mitochondrial import machinery is capable of discriminating against the mutant RNA in favor of the normal tRNA for import. In another example, we found that the Tv4 gene showed expression, albeit somewhat reduced, but its import into mitochondria was completely blocked. Unexpectedly, the 4-base addition mutation (Td4) at the D-loop showed neither expression nor import. While these results clearly signify the importance of various segments within the tRNA gene for in vivo expression, our data underscore the significance of the variable loop for mitochondrial import. It is our belief that this plasmid-encoded tRNA gene expression system in Leishmania may be useful in gaining further insights on tRNA import.

Selective import of nuclear-encoded tRNAs into mitochondria of the protozoan Leishmania tarentolae

The trypanosomatid mitochondrial genome does not encode tRNA genes at all and experimental evidence obtained with Leishmania tarentolae shows that tRNAs in mitochondria represent a selected set of imported nuclear-encoded tRNAs. In this paper we present the data showing that tRNAs derived from the clustered genomic tRNA genes are invariably imported into mitochondria, while tRNA from the solitary gene is not. By sequencing a cosmid DNA clone of L. tarentolae genomic DNA, we have identified a 1.5-kb subclone encoding a duplicate set of the closely linked tRNA(Tyr) (GTA) and tRNA(Thr) (AGT) genes. Northern analysis shows that these tRNAs are imported into mitochondria. In contrast, when the tRNA gene [tRNA(Gln) (CUG)] located alone in a 40-kb DNA fragment was examined, the corresponding tRNA was not detected in the mitochondrion. This "loner" tRNA gene is highly unusual since the 3'-flanking putative RNA polymerase III transcription termination signal sequence is characterized by a long string of 8 Ts followed by an A and a stretch of 7 Cs, while all other trypanosomatid tRNA genes whose tRNA transcripts are imported are terminated by a possible transcription termination signal of only 4-6 Ts. Whether the correlation found between the gene organization and tRNA-import characteristics is of general significance needs to be investigated further. A simple computer analysis presented in this paper rules out the possibility that tRNAs found in the trypanosomatid mitochondrion are the products of the U-addition type 'RNA editing' of maxicircle DNA.

Identification of a tRNA-like molecule that copurifies with the 7SL RNA of Trypanosoma brucei

During the purification of Trypanosoma brucei 7SL RNA, we detected a small RNA, 76 nucleotide-long (sRNA-76), that copurified with the 7SL RNP through several different separation steps. In this study, a partial RNA sequence of sRNA-76 was obtained and a complementary oligonucleotide to the RNA sequence was used to clone the corresponding gene. sRNA-76 is very similar to a tRNA molecule and is encoded by a single copy gene. The gene is located next to a tRNA(Val) which has 75.3% homology to T. brucei tRNA(Val) that exists in a different chromosomal locus. The highest homology of sRNA-76 is to mouse and rat tRNA(Asp) (69%), to mouse tRNA(Gly) (68.1%) and to yeast suppressor tRNA(Gly) (69.5%). However, sRNA-76 is neither a tRNA(Asp) nor a tRNA(Gly), since it has a Leu anticodon. In addition, sRNA-76 deviates from the canonical tRNA structure in 3 positions. A potential for base pairing between sRNA-76 and 7SL RNA was found in the 100 nt region of 7SL RNA, which is a highly conserved region in all 7SL RNAs.

The nucleotide sequence of the variable region in Trypanosoma brucei completes the sequence analysis of the maxicircle component of mitochondrial kinetoplast DNA

The nucleotide sequence of two non-contiguous DNA fragments of 4.0 and 2.2 kb, respectively, of the kinetoplast maxicircle of Trypanosoma brucei brucei EATRO strain 427 has been determined, completing the sequence analysis of the so-called variable region (see also de Vries et al., 1988, Mol. Biochem. Parasitol. 27, 71-82). Analysis of the entire 8-kb variable region sequence revealed the presence of a 5.2-kb cluster of imperfect, tandemly repeated sequences, flanked by DNA of unique sequence. Both repetitive and unique DNA evolve rapidly, but comparison to the closely related strain EATRO 164 indicated that the repetitive cluster is more prone to sequence and size divergence. The variable region is transcribed into RNAs of varying lengths but appears to be devoid of genes encoding mitochondrial proteins or tRNAs, as judged from computer analysis. Moreover, genes that could encode guide RNAs involved in producing the known edited mitochondrial mRNA sequences are also absent. The repetitive DNA cluster within this region consists of 14 blocks each containing one 130 bp repeat and a variable number of 19 bp repeats. A duplicated sequence was identified (5'-GGGGTTGGTGT) which proved to be identical to the eleven 5'-terminal residues of the universal minicircle dodecamer involved in initiation of leading strand synthesis. This suggests a role for these sequences in the initiation of maxicircle DNA replication. With the data presented in this report, the nucleotide sequence analysis of the 23016 bp maxicircle of T. brucei brucei EATRO strain 427 has been completed.