Posttranscriptional regulation of cytochrome c expression during the developmental cycle of Trypanosoma brucei

Exosomal and Non-Exosomal Transport of Extra-Cellular microRNAs in Follicular Fluid: Implications for Bovine Oocyte Developmental Competence

Cell-cell communication within the follicle involves many signaling molecules, and this process may be mediated by secretion and uptake of exosomes that contain several bioactive molecules including extra-cellular miRNAs. Follicular fluid and cells from individual follicles of cattle were grouped based on Brilliant Cresyl Blue (BCB) staining of the corresponding oocytes. Both Exoquick precipitation and differential ultracentrifugation were used to separate the exosome and non-exosomal fraction of follicular fluid. Following miRNA isolation from both fractions, the human miRCURY LNA™ Universal RT miRNA PCR array system was used to profile miRNA expression. This analysis found that miRNAs were present in both exosomal and non-exosomal fraction of bovine follicular fluid. We found 25 miRNAs differentially expressed (16 up and 9 down) in exosomes and 30 miRNAs differentially expressed (21 up and 9 down) in non-exosomal fraction of follicular fluid in comparison of BCB- versus BCB+ oocyte groups. Expression of selected miRNAs was detected in theca, granulosa and cumulus oocyte complex. To further explore the potential roles of these follicular fluid derived extra-cellular miRNAs, the potential target genes were predicted, and functional annotation and pathway analysis revealed most of these pathways are known regulators of follicular development and oocyte growth. In order to validate exosome mediated cell-cell communication within follicular microenvironment, we demonstrated uptake of exosomes and resulting increase of endogenous miRNA level and subsequent alteration of mRNA levels in follicular cells in vitro. This study demonstrates for the first time, the presence of exosome or non-exosome mediated transfer of miRNA in the bovine follicular fluid, and oocyte growth dependent variation in extra-cellular miRNA signatures in the follicular environment.

A tryparedoxin-dependent peroxidase protects African trypanosomes from membrane damage

Hydroperoxide detoxification in African trypanosomes is achieved by 2-Cys-peroxiredoxin (TXNPx)- and non-selenium glutathione peroxidase (Px)-type enzymes which both obtain their reducing equivalents from the unique trypanothione/tryparedoxin system. Previous RNA interference approaches revealed that the cytosolic TXNPx and the Px-type enzymes are essential for Trypanosoma brucei. Because of partially overlapping in vitro substrate specificities and subcellular localisation the physiological function of the individual enzymes was not yet clear. As shown here, TXNPx and Px are expressed at comparable levels and in their active reduced state. Px-overexpressing parasites were less sensitive toward linoleic acid hydroperoxide but not hydrogen peroxide. Kinetic studies confirmed that Px-but not TXNPx-reduces lipophilic hydroperoxides including phospholipids with high efficiency. Most interestingly, the severe proliferation defect of Px-depleted bloodstream cells could be rescued by Trolox, but not by hydrophilic antioxidants, in the medium. This allowed us to knock-out the three Px genes individually and thus to distinguish their in vivo role. Deletion of the cytosolic Px I and II resulted in extremely fast membrane peroxidation followed by cell lysis. Cells lacking specifically the mitochondrial Px III showed a transient growth retardation and cardiolipin peroxidation but adapted within 24h to normal proliferation.

Diverse effects on mitochondrial and nuclear functions elicited by drugs and genetic knockdowns in bloodstream stage Trypanosoma brucei

Background

The options for treating the fatal disease human African trypanosomiasis are limited to a few drugs that are toxic or facing increasing resistance. New drugs that kill the causative agents, subspecies of Trypanosoma brucei, are therefore urgently needed. Little is known about the cellular mechanisms that lead to death of the pathogenic bloodstream stage.

Methodology/Principal Findings

We therefore conducted the first side by side comparison of the cellular effects of multiple death inducers that target different systems in bloodstream form parasites, including six drugs (pentamidine, prostaglandin D₂, quercetin, etoposide, camptothecin, and a tetrahydroquinoline) and six RNAi knockdowns that target distinct cellular functions. All compounds tested were static at low concentrations and killed at high concentrations. Dead parasites were rapidly quantified by forward and side scatter during flow cytometry, as confirmed by ethidium homodimer and esterase staining, making these assays convenient for quantitating parasite death. The various treatments yielded different combinations of defects in mitochondrial potential, reactive oxygen species, cell cycle, and genome segregation. No evidence was seen for phosphatidylserine exposure, a marker of apoptosis. Reduction in ATP levels lagged behind decreases in live cell number. Even when the impact on growth was similar at 24 hours, drug-treated cells showed dramatic differences in their ability to further proliferate, demonstrating differences in the reversibility of effects induced by the diverse compounds.

Conclusions/Significance

Parasites showed different phenotypes depending on the treatment, but none of them were clear predictors of whether apparently live cells could go on to proliferate after drugs were removed. We therefore suggest that clonal proliferation assays may be a useful step in selecting anti-trypanosomal compounds for further development. Elucidating the genetic or biochemical events initiated by the compounds with the most profound effects on subsequent proliferation may identify new means to activate death pathways.

The parasite Trypanosoma brucei causes human African trypanosomiasis, which is fatal unless treated. Currently used drugs are toxic, difficult to administer, and often are no longer effective due to drug resistance. The search for new drugs is long and expensive, and determining which compounds are worth pursuing is a key challenge in that process. In this study we sought to determine whether different compounds elicited different responses in the mammalian-infective stage of the parasite. We also examined whether genetic knockdown of parasite molecules led to similar responses. Our results show that, depending on the treatment, the replication of the parasite genomes, proper division of the cell, and mitochondrial function can be affected. Surprisingly, these different responses were not able to predict which compounds affected the long term proliferative potential of T. brucei. We found that some of the compounds had irreversible effects on the parasites within one day, so that even cells that appeared healthy could not proliferate. We suggest that determining which compounds set the parasites on a one-way journey to death may provide a means of identifying those that could lead to drugs with high efficacy.

Trypanosome alternative oxidase is regulated post-transcriptionally at the level of RNA stability

In the bloodstream form of African trypanosomes, trypanosome alternative oxidase (TAO), the non-cytochrome ubiquinol:oxidoreductase, is the only terminal oxidase of the mitochondrial electron transport system. TAO is developmentally regulated during mitochondrial biogenesis in this parasite. During in vitro differentiation of Trypanosoma brucei from the bloodstream to the procyclic form, the overall rate of oxygen consumption decreased about 80%. The mode of respiration changed over a 2- to 3-wk period from a cyanide-insensitive, SHAM-sensitive pathway to a predominantly cyanide-sensitive pathway. The TAO protein level gradually decreased to the level present in the procyclic forms during this 3-wk period. However, within the first week of differentiation, the TAO transcript level decreased about 90% and then in the following weeks it reached the level present in the established procyclic form, that is about 20% of that in bloodstream forms. Like other trypanosomatid genes TAO transcript synthesis remains unaltered in fully differentiated bloodstream and procyclic trypanosomes. The half-life of the TAO mRNA was about 3.2 h in the procyclic trypanosomes, whereas the TAO transcript level remained unaltered even after 4 h of incubation with actinomycin D in bloodstream forms. Inhibition of protein synthesis resulted in about a four-fold accumulation of the TAO transcript in the procyclic trypanosomes, comparable to the level present in the bloodstream forms. Thus, TAO is regulated at the level of mRNA stability and de novo protein synthesis is required for the reduction of the TAO mRNA pool in the procyclic form.

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.

Cytochrome oxidase subunit VI of Trypanosoma brucei is imported without a cleaved presequence and is developmentally regulated at both RNA and protein levels

Mitochondrial respiration in the African trypanosome undergoes dramatic developmental stage regulation. This requires co-ordinated control of components encoded by both the nuclear genome and the kinetoplast, the unusual mitochondrial genome of these parasites. As a model for understanding the co-ordination of these genomes, we have examined the regulation and mitochondrial import of a nuclear-encoded component of the cytochrome oxidase complex, cytochrome oxidase subunit VI (COXVI). By generating transgenic trypanosomes expressing intact or mutant forms of this protein, we demonstrate that COXVI is not imported using a conventional cleaved presequence and show that sequences at the N-terminus of the protein are necessary for correct mitochondrial sorting. Analyses of endogenous and transgenic COXVI mRNA and protein expression in parasites undergoing developmental stage differentiation demonstrates a temporal order of control involving regulation in the abundance of, first, mRNA and then protein. This represents the first dissection of the regulation and import of a nuclear-encoded protein into the cytochrome oxidase complex in these organisms, which were among the earliest eukaryotes to possess a mitochondrion.

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

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

Developmental regulation of two nuclear RNA binding proteins, p34 and p37, from Trypanosoma brucei

We have previously reported the purification of two closely related nucleic acid binding proteins, p34 and p37, from Trypanosoma brucei and the cloning and sequencing of the two genes encoding these two proteins. The predicted primary structures of the two proteins are nearly identical with one major and several minor differences. Three sequence motifs have been identified in both proteins: an N-terminal alanine, proline, and lysine rich domain, one and a half internal consensus RNA binding domains, and a C-terminal KKDX repeat region. p34 and p37 bind preferentially to heterogeneous RNA as compared with other nucleic acids. Here, we report the developmental regulation of the expression of these two highly related proteins and their intracellular localization in T. brucei. The results indicate that these two RNA binding proteins are differently regulated through the Trypanosoma brucei life cycle. The steady state level of p34 transcript and protein are highest in the procyclic form. In bloodstream form, however, the p34 message is readily detectable, while the protein is not detectable. The p37 transcript level is nearly as high as that for p34 in procyclic form, while the p37 protein level is low. In bloodstream form p37 protein does correlate with the relative abundance of the steady state mRNA level. The two proteins have been localized to the nucleus by immunofluorescent confocal microscopy and subcellular fractionation.

Subunit 9 of the mitochondrial ATP synthase of Trypanosoma brucei is nuclearly encoded and developmentally regulated

We have previously shown that the mitochondrial ATP synthase is developmentally regulated through the life cycle of Trypanosoma brucei. The mechanism of this regulation is as yet unknown. We are currently examining regulation of expression of several key subunits of the ATP synthase to investigate this mechanism. In the work presented here, we have cloned, sequenced, and confirmed the identity of the ATPase subunit 9 homologue from T. brucei. The ATPase subunit 9 gene that we have identified from T. brucei has between 40 and 600% identity with subunit 9 from a variety of organisms. This gene possesses a putative mitochondrial import sequence at the N terminus of the encoded protein sequence. The protein expressed from this gene by in vitro transcription/translation comigrates with native protein isolated from inner mitochondrial membrane vesicles from T. brucei. We have shown that the cDNA identifies a copy of this gene in the nuclear genome, but does not identify a similar gene in kinetoplast DNA (kDNA) prepared from T. brucei. This gene does not show homology to any published sequence data from maxicircle DNA or edited maxicircle derived sequences. Steady state transcripts of a single size have been identified by Northern analysis and demonstrate significant developmental regulation through the T. brucei life cycle. Northern analysis and quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) results show that the transcript is 10-14-fold higher in procyclic form than in early and late bloodstream forms.

Transcription of protein-coding genes in trypanosomes by RNA polymerase I

In eukaryotes, RNA polymerase (pol) II transcribes the protein-coding genes, whereas RNA pol I transcribes the genes that encode the three RNA species of the ribosome [the ribosomal RNAs (rRNAs)] at the nucleolus. Protozoan parasites of the order Kinetoplastida may represent an exception, because pol I can mediate the expression of exogenously introduced protein-coding genes in these single-cell organisms. A unique molecular mechanism, which leads to pre-mRNA maturation by trans-splicing, facilitates pol I-mediated protein-coding gene expression in trypanosomes. Trans-splicing adds a capped 39-nucleotide mini-exon, or spliced leader transcript, to the 5' end of the main coding exon posttranscriptionally. In other eukaryotes, the addition of a 5' cap, which is essential for mRNA function, occurs exclusively as a result of RNA pol II-mediated transcription. Given the assumption that cap addition represents the limiting factor, trans-splicing may have uncoupled the requirement for RNA pol II-mediated mRNA production. A comparison of the alpha-amanitin sensitivity of transcription in naturally occurring trypanosome protein-coding genes reveals that a unique subset of protein-coding genes-the variant surface glycoprotein (VSG) expression sites and the procyclin or the procyclic acidic repetitive protein (PARP) genes-are transcribed by an RNA polymerase that is resistant to the mushroom toxin alpha-amanitin, a characteristic of transcription by RNA pol I. Promoter analysis and a pharmacological characterization of the RNA polymerase that transcribes these genes have strengthened the proposal that the VSG expression sites and the PARP genes represent naturally occurring protein-coding genes that are transcribed by RNA pol I.

In vitro import of the Rieske iron-sulfur protein by trypanosome mitochondria

Most of the proteins present in the mitochondrion are imported to that location from the cytosol. While this process has been studied extensively in fungal and mammalian systems, little work has been done in other eukaryotic organisms. We are particularly interested in the Trypanosoma brucei system because this organism developmentally regulates mitochondrial function during its life cycle and because one of the imported proteins lacks a conventional targeting sequence. We report here the development of an in vitro import system using crude trypanosome mitochondria and a nuclear encoded, mitochondrial protein. Import of the Rieske iron-sulfur protein subunit of the cytochrome c reductase complex requires a membrane potential, ATP, and a protein component on the mitochondrial surface. The precursor protein is sequentially processed to the mature form in two steps by peptidases that require divalent metal ions for activity. As in other eukaryotic systems, the first processing event occurs inside the inner membrane and is probably catalyzed by a matrix-processing protease. Surprisingly, the second processing activity is located outside the inner membrane. Both processing steps require ATP but are independent of a membrane potential. We suggest that the trypanosome iron-sulfur protein is imported along a "conservative sorting pathway" but that the assembly mechanism of the reductase complex may be unique to trypanosomes.

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.

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

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

Membrane-related processes and overall energy metabolism in Trypanosoma brucei and other kinetoplastid species

An electrochemical proton gradient exists across the plasma membrane and the mitochondrial membrane of the bloodstream form of Trypanosoma brucei. The membrane potential across the plasma membrane and the regulation of the internal pH depend on the temperature. Leishmania donovani regulates its internal pH and maintains a constant electrochemical proton gradient across its plasma membrane under all conditions examined. The mitochondrion of the T. brucei bloodstream form is energized, even though the reactions taking place in it do not result in net ATP synthesis and the Kreb's cycle and the respiratory chain are absent. Glucose is transported across the plasma membrane of T. brucei by a facilitated diffusion carrier, that can transport a wider range of substrates than its mammalian counterparts. Pyruvate exits the cell via a facilitated diffusion transporter as well. Conflicting evidence exists for the mechanism of glucose transport in L. donovani; biochemical evidence suggests proton/glucose symport, while facilitated diffusion is indicated by physiological data.

The mitochondrial ATP synthase of Trypanosoma brucei: structure and regulation

The structure and regulation of the Trypanosoma brucei mitochondrial ATP synthase is reviewed. This enzyme complex which catalyzes the synthesis and hydrolysis of ATP within the mitochondrion is a multisubunit complex which is regulated in several ways. Several lines of evidence have shown that the ATP synthase is regulated through the life cycle of Trypanosoma brucei. The enzyme complex is present at maximal levels in the procyclic form where mitochondrial activity is the highest and cytochromes and Kreb's cycle components are present. The levels of the ATP synthase are decreased in the bloodstream forms where the levels of the mitochondrial cytochromes are absent or substantially decreased. In recent preliminary work we have shown the presence of an ATP synthase inhibitor peptide which may indicate an additional level of complexity to the regulation.

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.

Characterization of a Trypanosoma brucei nuclear gene encoding a protein homologous to a subunit of bovine NADH:ubiquinone oxidoreductase (complex I)

A Trypanosoma brucei gene has been identified that encodes a protein predicted to be a component of the trypanosome homologue of mitochondrial NADH:ubiquinone oxidoreductase (complex I). High homology was found to a 20-kDa component of the iron-sulfur protein fraction of bovine mitochondrial NADH:ubiquinone oxidoreductase and the products of the ndhK locus of Paramecium tetraurelia mitochondria and the NQO6 locus of Paracoccus denitrificans. The homology extends to several other proteins predicted to function as part of electron transport systems, including the psbG/ndhK gene products of chloroplast and cyanobacterial genomes which are thought to be subunits of a NADH:plastoquinone oxidoreductase involved in chlororespiration. The T. brucei ndhK counterpart is nuclearly encoded. An extended amino terminus of the T. brucei ndhK with structural similarity to mitochondrial presequences indicates that its transfer into mitochondria is likely. Stumpy and slender bloodforms and procyclic forms all possess similar levels of ndhK transcripts despite previous reports of stage-regulated expression of complex I-like activity.

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.

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

The steady-state levels of the mitochondrial ribosomal RNAs of Trypanosoma brucei are repressed in the early bloodstream developmental stage of the parasite and accumulate approximately 30-fold during differentiation to the stage found in the midgut of the insect vector. In order to determine the mechanism regulating this developmental process, we have examined the transcription and processing of the 9S and 12S mitochondrial rRNAs of T. brucei. A short-lived RNA was detected in pulse labeling experiments which contains the mature 12S and 9S rRNAs and at least 1200 nucleotides of RNA transcribed from upstream of the 12S rRNA gene. This putative processing precursor RNA was identified in both intact cells and in run-on experiments using isolated mitochondria. The transcripts containing the upstream sequences are unstable and reach isotopic equilibrium within 15 min. Mature rRNAs in the insect developmental stage are stable and show no detectable turnover during a 36-h chase. Comparison of rRNA synthesis in bloodstream and insect life-stages indicates that mitochondrial rRNA levels are controlled not at the transcriptional level, but rather by a mechanism which likely modulates the stability of the mature rRNAs. These results suggest that a short-lived rRNA precursor is synthesized and processed at comparable rates in both bloodstream and insect stages of the parasite. Thus, it appears that differential stability of the mature 9S and 12S rRNAs plays a major role in modulating mitochondrial gene expression during the developmental cycle of T. brucei.

A developmentally regulated cysteine proteinase gene of Leishmania mexicana

We have isolated a gene encoding a previously unreported class of trypanosomatid cysteine proteinase (CP) from the protozoan parasite Leishmania mexicana. The single-copy gene (lmcpa) [corrected]. has several unusual features that distinguish it from CP genes cloned from the related species Trypanosoma brucei and Trypanosoma cruzi. These include a shorter C-terminal extension of only 10 amino acids and a three-amino-acid insertion, GlyValMet, close to the predicted N-terminus of the mature protein. Northern blot analysis showed that the gene is expressed in all life-cycle stages but at higher levels in the amastigote stage in the mammal and in stationary phase promastigote cultures which contain the infective metacyclic form of the parasite. A precursor protein of 38 kDa was detected in amastigotes and stationary phase promastigotes with antisera specific to the LmCPa pro-region, but was barely detectable in early log-phase promastigotes. Anti-central domain antisera recognized the 38 kDa precursor and 24 and 27 kDa proteins. The major CPs of L. mexicana amastigotes, previously designated types A, B and C, were not detected with the antisera, suggesting that the gene codes for a previously uncharacterized CP in L. mexicana. The 24 kDa protein detected by the antiserum has no activity towards gelatin but apparently hydrolyses the peptide substrate BzPheValArgAMC. The relative levels of the 24 and 27 kDa proteins vary between the different life-cycle stages. The results indicate that expression of this CP is regulated at both the RNA and protein level.

Molecular Biology of African Trypanosomes: Development of New Strategies to Combat an Old Disease

African trypanosomes are protozoan parasites that cause a number of diseases of man and domesticated animals in large regions of sub-Saharan Africa. The diseases have proven to be particularly difficult to prevent or to effectively treat due to features of both the trypanosome and the insect vector, the tsetse fly. The habitat of the tsetse and its resistance to insecticides have rendered vector control efforts ineffective. Attempts to develop a vaccine against the African trypanosomes has been dwarfed by the parasite's ability to change the composition of its exposed surface antigens. This process of antigenic variation allows the parasite to avoid the host's immune response and presents the host with a seemingly endless antigenic repertoire. Since conventional approaches to the control of African trypanosomiasis have largely met with failure, there has been a renewed interest in identifying novel aspects of the biology, biochemistry, and molecular biology of trypanosomes that might be exploited to develop new targets for vaccines or chemotherapy. Importantly, this research has opened a virtual Pandora's box of exciting biochemical and molecular surprises, which makes the African trypanosomes not only important medical pathogens but also an exciting experimental system for the basic scientist. In this review, the authors will describe some of the most recent and intriguing developments in the field of molecular parasitology.

The mitochondrial ATP synthase of Trypanosoma brucei: developmental regulation through the life cycle

The mitochondrial H(+)-ATPase of the parasitic protozoan Trypanosoma brucei is shown to be developmentally regulated through the T. brucei life cycle as has been shown for components of the mitochondrial electron transport chain. We have substantiated our results by assaying not only for oligomycin-sensitive ATPase activity but also by determining the level of ATP synthetic activity. These results show that the level of ATPase present in the procyclic form of T. brucei is increased by at least threefold from that of the early bloodstream form while the ATPase activity in the late bloodstream form is only about twofold higher than the early form. ATP synthesis activity shows these same results. We have determined the level of ATP synthase protein present in the life cycle stages by Western analysis employing the antibodies that we have raised against both the water soluble F1 and the membrane-associated F0 moieties which we have purified from T. brucei. The Western blots of the procyclic form show strong reactivity with both the F0 and F1 antibodies. The other two life cycle stages, the early and the late bloodstream forms, show considerably less reactivity, paralleling the activity results. Electron micrographs of the sonicated mitochondrial fraction show inverted vesicles which are studded with knobby H(+)-ATPase in the procyclic form. The early bloodstream vesicles show very few of these characteristic structures, while the late bloodstream form shows a range of vesicles from nearly nude to partially studded.

Genetics of antigenic variation in African trypanosomes

The major surface antigens of Trypanosoma brucei are the VSG (variant surface glycoprotein) at the bloodstream stage, and procyclin at the procyclic stage. Variation in the VSG allows the parasite to escape the antibody response of its mammalian host. This occurs through either DNA rearrangement in the telomeric VSG gene expression site, or alternate activation, without DNA rearrangement, of different telomeric expression sites. The VSG and procyclin genes each belong to large, polycistronic transcription units. Although the promoters of these units are both active at the two main stages of the parasite life cycle, stage-specific controls operating at the level of RNA elongation and processing lead to strictly differential expression of the end products of the two units. Despite their mutually exclusive control of expression, the VSG and procyclin transcription units share common characteristics. Both contain a similar gene, and both are transcribed by the same type of RNA polymerase, unusually resistant to alpha-amanitin. Among the eight genes present in the VSG transcription unit, two may be involved in the synthesis of cyclic AMP. The function of the other genes is unknown.

Characterization of a novel developmentally regulated gene from Trypanosoma brucei encoding a potential phosphoprotein

We have isolated a cDNA clone corresponding to a single-copy nuclear gene that is upregulated at the mRNA level during in vitro differentiation of bloodstream trypomastigotes of strains of both Trypanosoma brucei brucei and Trypanosoma brucei rhodesiense to procyclic forms. Transcript levels begin to increase within minutes of introduction of bloodstream forms into culture and peak well before cultures exhibit a procyclic morphology. This increase in transcript levels was found to occur both in the absence of protein synthesis and in a nontransforming strain blocked very early in the developmental program, both conditions under which accumulation of procyclic acidic repetitive protein (PARP) transcripts did not occur in control experiments. DNA sequence analysis reveals an open reading frame sufficient to encode a protein of approximately 50 kDa within the cDNA, but data base searches for homology at either the amino acid or nucleotide level revealed no related sequences. A high density of kinase consensus target sites in the deduced amino acid sequence suggests that the gene product may be a phosphoprotein.

Current concepts in stage-regulated gene expression in kinetoplastida

The different physiological environments provided by the hosts probably generated a strong selective force for the evolution of differential expression of gene products in digenetic kinetoplastid parasites. Indeed, the sorts of molecules that would be predicted to be stage-regulated have been found to be differentially expressed. Examples include transport molecules, metabolic enzymes, molecules involved in cell adhesion and penetration, and molecules involved in evasion of host defence mechanisms. Within the life cycle, environmental cues provided by the host, such as temperature and nutrients, may also function as triggers for the differential expression of gene products.

The human ATP synthase beta subunit gene: sequence analysis, chromosome assignment, and differential expression

In humans, the functional F0F1-ATP synthase beta subunit gene is located on chromosome 12 in the p13----qter region. Other partially homologous sequences have been detected on chromosomes 2 and 17. The bona fide beta subunit gene has 10 exons encoding a leader peptide of 49 amino acids and a mature protein of 480 amino acids. Thirteen Alu family DNA repeats are found upstream from the gene and in four introns. The gene has four "CCAAT" sequences upstream and in close proximity to the transcriptional initiation site. A 13-bp motif is found in the 5' nontranscribed region of both the beta subunit gene and an ADP/ATP translocator gene that is expressed in high levels in cardiac and skeletal muscle. Analysis of the beta subunit mRNA levels reveals marked differences among tissues. The highest levels are found in heart, lower levels in skeletal muscle, and the lowest levels in liver and kidney. These findings suggest that the tissue-specific levels of ATP synthase beta subunit mRNA may be generated through transcriptional control.

Characterization of a protein fraction containing cytochromes b and c1 from mitochondria of Leishmania tarentolae

A soluble red band fraction was obtained from Leishmania tarentolae cells by sucrose gradient sedimentation of a Triton X-100 lysate. Spectral analysis indicated that cytochrome b was present in the red band: the reduced minus oxidized difference spectra revealed absorption maxima at 562,527, and 431 nm at room temperature and 562, 530, and 422 nm at 77K. In addition, a 28-kDa protein was identified in this fraction which retained heme-associated peroxidase activity even after denaturation on SDS-polyacrylamide gels. The amino acid composition of this protein showed a strong similarity to cytochrome c1 of both bovine and yeast.