trans splicing in Leishmania enriettii and identification of ribonucleoprotein complexes containing the spliced leader and U2 equivalent RNAs

Genomic organization of leishmania species

Leishmania is a protozoan parasite belonging to the family Trypanosomatidae, which is found among 88 different countries. The parasite lives as an amastigote in vertebrate macrophages and as a promastigote in the digestive tract of sand fly. It can be cultured in the laboratory using appropriate culture media. Although the sexual cycle of Leishmania has not been observed during the promastigote and amastigote stages, it has been reported by some researchers. Leishmania has eukaryotic cell organization. Cell culture is convenient and cost effective, and because posttranslational modifications are common processes in the cultured cells, the cells are used as hosts for preparing eukaryotic recombinant proteins for research. Several transcripts of rDNA in the Leishmania genome are suitable regions for conducting gene transfer. Old World Leishmania spp. has 36 chromosomes, while New World Leishmania spp. has 34 or 35 chromosomes. The genomic organization and parasitic characteristics have been investigated. Leishmania spp. has a unique genomic organization among eukaryotes; the genes do not have introns, and the chromosomes are smaller with larger numbers of genes confined to a smaller space within the nucleus. Leishmania spp. genes are organized on one or both DNA strands and are transcribed as polycistronic (prokaryotic-like) transcripts from undefined promoters. Regulation of gene expression in the members of Trypanosomatidae differs from that in other eukaryotes. The trans-splicing phenomenon is a necessary step for mRNA processing in lower eukaryotes and is observed in Leishmania spp. Another particular feature of RNA editing in Leishmania spp. is that mitochondrial genes encoding respiratory enzymes are edited and transcribed. This review will discuss the chromosomal and mitochondrial (kinetoplast) genomes of Leishmania spp. as well as the phenomenon of RNA editing in the kinetoplast genome.

The Trypanosoma brucei La protein is a candidate poly(U) shield that impacts spliced leader RNA maturation and tRNA intron removal

By virtue of its preferential binding to poly(U) tails on small RNA precursors and nuclear localisation motif, the La protein has been implicated for a role in the stabilisation and nuclear retention of processing intermediates for a variety of small RNAs in eukaryotic cells. As the universal substrate for trans-splicing, the spliced leader RNA is transcribed as a precursor with just such a tail. La protein was targeted for selective knockdown by inducible RNA interference in Trypanosoma brucei. Of three RNA interference strategies employed, a p2T7-177 vector was the most effective in reducing both the La mRNA as well as the protein itself from induced cells. In the relative absence of La protein T. brucei cells were not viable, in contrast to La gene knockouts in yeast. A variety of potential small RNA substrates were examined under induction, including spliced leader RNA, spliced leader associated RNA, the U1, U2, U4, and U6 small nuclear RNAs, 5S ribosomal RNA, U3 small nucleolar RNA, and tRNATyr. None of these molecules showed significant variance in size or abundance in their mature forms, although a discrete subset of intermediates appear for spliced leader RNA and tRNATyr intron splicing under La depletion conditions. 5'-end methylation in the spliced leader RNA and U1 small nuclear RNA was unaffected. The immediate cause of lethality in T. brucei was not apparent, but may represent a cumulative effect of multiple defects including processing of spliced leader RNA, tRNATyr and other unidentified RNA substrates. This study indicates that La protein binding is not essential for maturation of the spliced leader RNA, but does not rule out the presence of an alternative processing pathway that could compensate for the absence of normally-associated La protein.

Leishmania chagasi: The α-tubulin intercoding region results in constant levels of mRNA abundance despite protein synthesis inhibition and growth state

The intercoding regions of many Leishmania sp. genes have been implicated in the regulation of mRNA processing, stability, and translation. Herein we show that the intercoding region of the Leishmania chagasi alpha-tubulin gene (alpha-TUB) confers stable beta-galactosidase (beta-GAL) reporter mRNA levels during promastigote growth and development in vitro and during protein synthesis inhibition. The abundance of both endogenous alpha-TUB mRNA and beta-GAL mRNA from a beta-GAL coding region situated upstream of the alpha-TUB intercoding region did not change significantly as promastigotes grew from logarithmic to stationary phase in vitro and the half-life of the beta-GAL mRNA remained constant. The abundance of both the endogenous alpha-TUB and the beta-GAL mRNA increased by less than 2-fold after protein synthesis inhibition corresponding to a moderate increase in mRNA half-life. These data suggest that the alpha-TUB intercoding region is an excellent control for the study of the regulation of other differentially expressed genes.

Leishmania major LACK antigen is required for efficient vertebrate parasitization

The Leishmania major LACK antigen is a key target of the immune response in susceptible BALB/c mice and remains a viable vaccine candidate for human leishmaniasis. We describe the genomic organization of the four lack genes in the L. major diploid genome together with results of selected lack gene targeting. Parasites containing a single lack gene in either the upstream or downstream locus grew comparably to wild-type promastigotes in vitro, but failed to parasitize BALB/c mice efficiently, even in a T cell-deficient environment. The replication of single copy lack mutants as amastigotes was attenuated in macrophages in vitro, and parasites failed to increase in numbers in immunodeficient mice, despite their persistence over months. Complementation with an additional lack copy was sufficient to induce robust lesion development, which also occurred using parasites with two lack genes. Conversely, attempts to generate lack-null parasites failed, suggesting that LACK is required for parasite viability. These data suggest that LACK is critical for effective mammalian parasitization and thus represents a potential drug target for leishmaniasis.

Xanthine phosphoribosyltransferase from Leishmania donovani. Molecular cloning, biochemical characterization, and genetic analysis

Xanthine phosphoribosyltransferase (XPRT) from Leishmania donovani is a unique enzyme that lacks a mammalian counterpart and is, therefore, a potential target for antiparasitic therapy. To investigate the enzyme at the molecular and biochemical level, a cDNA encoding the L. donovani XPRT was isolated by functional complementation of a purine auxotroph of Escherichia coli that also harbors deficiencies in the prokaryotic phosphoribosyltransferase (PRT) activities. The cDNA was then used to isolate the XPRT genomic clone. XPRT encodes a 241-amino acid protein exhibiting approximately 33% amino acid identity with the L. donovani hypoxanthine-guanine phosphoribosyltransferase (HGPRT) and significant homology with other HGPRT family members. Southern blot analysis revealed that XPRT was a single copy gene that co-localized with HGPRT within a 4.3-kilobase pair (kb) EcoRI fragment, implying that the two genes arose as a result of an ancestral duplication event. Sequencing of this EcoRI fragment confirmed that HGPRT and XPRT were organized in a head-to-tail arrangement separated by an approximately 2.2-kb intergenic region. Both the 3.2-kb XPRT mRNA and XPRT enzyme were significantly up-regulated in Deltahgprt and Deltahgprt/Deltaaprt L. donovani mutants. Genetic obliteration of the XPRT locus by targeted gene replacement indicated that XPRT was not an essential gene under most conditions and that the Deltaxprt null strain was competent of salvaging all purines except xanthine. XPRT was overexpressed in E. coli and the recombinant protein purified to homogeneity. Kinetic analysis revealed that the XPRT preferentially phosphoribosylated xanthine but could also recognize hypoxanthine and guanine. K(m) values of 7.1, 448.0, and >100 microM and k(cat) values of 3.5, 2.6, and approximately 0.003 s(-1) were calculated for xanthine, hypoxanthine, and guanine, respectively. The XPRT gene and XPRT protein provide the requisite molecular and biochemical reagents for subsequent studies to validate XPRT as a potential therapeutic target.

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.

Mini-exon gene variation in human pathogenic Leishmania species

We have used polymerase chain reaction to amplify the mini-exon gene repeat from 18 Leishmania strains. DNA sequence analysis of the cloned products reveals high conservation of both the exon and intron (i.e. transcribed region). In contrast, variation is evident in both the length and primary sequence of the non-transcribed spacers. Dermotropic species of the New World subgenus Leishmania possess a 0.3-kb gene that differs from the 0.25-kb gene of New World dermotropic species of the subgenus Viannia. The Old/New World viscerotropic species and Old World dermotropic species possess a 0.4-kb mini-exon gene. However, the genes from the viscerotropic and dermotropic groups may be distinguished on the basis of sequence differences in the non-transcribed spacer. Comparative analysis of the -86 to -1 region from all species has been used to measure relatedness within the genus. In general, all the observed differences correlate with the four major groups of Leishmania (New World dermotropic Leishmania, New World dermotropic Viannia, Old World dermotropic Leishmania and viscerotropic Leishmania). Two of the three repeats cloned from L. donovani show short deletions. The missing sequence is flanked by direct, 7-bp repeats suggesting that the sequences may have been deleted by homologous recombination. Such rearrangements could account for the diversity detected in the non-transcribed spacers of the mini-exon genes.

A small chromosome of Leishmania (Viannia) braziliensis contains multicopy sequences which are complex specific

Orthogonal Field Alternating Gel Electrophoresis (OFAGE) has been used to show a band of approximately 260 kb which is stained intensely with ethidium bromide in Leishmania (V.) braziliensis stock M2903. This small chromosome (sc-2903), as well as a 50 kb and a 200 kb chromosome seen in L. (L.) mexicana and L. (L.) amazonensis, respectively, are stably maintained and linear. When used as a hybridisation probe, sc-2903 showed homology to large chromosomal DNA bands and to a multiplicity of genomic fragments in all braziliensis stocks tested, indicating either different sequences, different copy numbers or both but no hybridisation to mexicana stocks. It is possible that these sequences are present in all members of the braziliensis complex and are not related to LD1 or any other previously published small chromosome sequences. However, at least one clone isolated from a sc-2903 library recognised genomic DNA of stocks belonging to the braziliensis, mexicana and donovani complexes. Our results suggest that the clone carries sequence(s) that are repeated and shared between stocks of different complexes but with a variable genomic distribution.

Genes selectively expressed in the infectious (metacyclic) stage of Leishmania major promastigotes encode a potential basic-zipper structural motif

Complementary DNA clones representing transcripts selectively expressed in the non-dividing, infective (metacyclic) stage of Leishmania major promastigotes (MP) were identified by differential and subtractive screening. The majority of the selected clones hybridized on Northern blots to a set of transcripts highly expressed by MP, but to a much lower extent in proliferating and stationary-phase attenuated promastigotes. Stationary, but not log-phase cultures, of each of 5 L. major strains showing a potential for differentiation to metacyclics, expressed these transcripts (MAT-1; MP-associated transcripts). From sequence analysis of full-length cDNA clones corresponding to the predominating MAT-1 species, an open reading frame encoding a 139 aa polypeptide (15.4 kDa) was predicted and supported by immunoprecipitation by kala-azar sera of reticulocyte extract translation products using in vitro transcribed RNA. Although no significant primary sequence homology to database nucleic acid and protein sequences was found, the sequence displays similarities to the basic-zipper families of transcription regulatory proteins.

mRNA processing in the Trypanosomatidae

Members of the Trypanosomatidae, which include the African trypanosomes, the American trypanosomes and the leishmanias, cause disease in vast proportions in man and his livestock and are a major detrimental factor to the social and economic well-being of the third world. Current research using the techniques of molecular biology has revealed two unusual types of mRNA processing in these protozoans; these are the addition of a shared leader sequence to the 5' ends of nuclear mRNAs by a mechanism of trans splicing, and the insertion and deletion of specific uridine residues in mitochondrial transcripts by RNA editing. The presence of these two mRNA processing pathways in the Trypanosomatidae has profound consequences for the organization and expression of their genetic information.

A comparison of trans-RNA splicing in trypanosomes and nematodes

Many aspects of the biology of kinetoplastids are unique, so it is surprising that they share with nematodes an unusual post-transcriptional process called trans-splicing. During this process, a small conserved RNA sequence is added to the 5' non-translated ends of transcribed RNAs of protein-encoding genes. Trypanosomes and nematodes are the only organisms to date in which these sequences have been described, and the biological significance of trans-splicing remains a mystery but may be of wider occurrence in invertebrates. In this review, John Donelson and Wenlin Zeng compare the process in nematodes and trypanosomes and speculate on its raison d'être.

Spliced leader RNA sequences can substitute for the essential 5' end of U1 RNA during splicing in a mammalian in vitro system

L. collosoma or C. elegans SL RNA sequences joined to an adenovirus intron and 3' exon are spliced highly efficiently and accurately in HeLa nuclear extract. After inactivation of U1 snRNPs using RNAase H and a deoxyoligonucleotide complementary to the first 12 nucleotides of U1, splicing of SL RNA-containing constructs continues undiminished, whereas control substrates no longer splice. Since neither binding of U1 snRNPs nor inhibition of splicing is detected using anti-(U1)RNP antibodies, splicing of SL RNA-containing constructs may be entirely U1 snRNP independent. Analyses of altered L. collosoma constructs revealed that the sequence surrounding the 5' splice site is not sufficient to confer U1-independent splicing; the smallest U1-independent region identified so far retains only the first stem-loop of the SL RNA. That sequences responsible for recognition of the 5' splice site can be relocated within the splicing substrate itself reinforces the similarity between group II self-splicing and spliceosome-mediated pre-mRNA splicing.

Conserved sequences in the U2 snRNA-encoding genes of Kinetoplastida do not include the putative branchpoint recognition region

The U2 small nuclear RNA (snRNA) of Trypanosoma brucei gambiense, a flagellated protozoon of the order Kinetoplastida, is 148 nucleotides (nt) long, and thus the smallest U2 snRNA identified so far. To examine the evolutionary conservation of this RNA among Kinetoplastida, we have cloned and sequenced the U2 genes from Trypanosoma congolense and Leishmania mexicana amazonensis, which are 145 and 141 nt in length, respectively. The sequences of the Kinetoplastida U2 snRNAs are essentially identical in the 5' half of the molecule. Surprisingly, the putative branch site recognition sequence of L. m. amazonensis U2 snRNA shows two nt changes when compared with the other two U2 snRNAs. The sequence of the 3' half of the Kinetoplastida U2 snRNAs is less conserved with T. congolense and L. m. amazonensis RNAs showing 23 and 35 nt sequence variations, respectively, when compared with the corresponding sequence of the T. b. gambiense U2 snRNA. Alignment of the flanking regions of the U2 genes revealed several elements which are conserved both in sequence and in position relative to the U2 coding region and which may function in the biosynthesis of U2 snRNAs. One upstream element specifically binds protein factor(s) present in T. brucei nuclear extracts.

Heat-shock protein 83 of Leishmania mexicana amazonensis is an abundant cytoplasmic protein with a tandemly repeated genomic arrangement

The 83-kDa heat-shock protein HSP83 is a highly abundant protein in Leishmania amastigotes and promastigotes exposed to elevated temperature. Antibodies against this protein were obtained by immunization with a synthetic peptide derived from a conserved region. These antibodies recognized both the denatured and the native form of the molecule and were used for immunofluorescence analysis. These experiments, together with analysis by cell fractionation, show that HSP83 is distributed in the cytoplasm of Leishmania parasites. The gene for HSP83 in Leishmania mexicana amazonensis has been cloned from a genomic library, and molecular characterization shows it is present in several copies of 4-kb repeats arranged in tandem.

A tandem pair of Leishmania donovani cation transporting ATPase genes encode isoforms that are differentially expressed

The second gene (ATPase 1b) of a tandem pair of cation transporting ATPases from Leishmania donovani was cloned and sequenced. The sequence of this gene was very similar to its upstream neighbor (ATPase 1a). Both genes contained a 2922 base open reading frame capable of encoding a protein of 974 amino acids. The genes differed at 34 nucleotide base positions, predicting 20 amino acid differences between the two peptides. These changes were clustered at the carboxy terminus with 15 changes occurring in the COOH-terminal 37 amino acids. However, these changes did not alter the highly charged nature of the carboxy terminus observed in ATPase 1a. The sequence was also conserved for 73 bases upstream of ATPase 1a and 1b but downstream conservation was limited to 15 bases beyond the termination codon. RNA from ATPase 1a was 5.2 kb and was present in both developmental forms of Leishmania. By contrast the ATPase 1b gene expressed a 5.75 kb transcript which was much more abundant in the amastigote form of Leishmania than in the promastigote form.

Trans splicing involves a novel form of small nuclear ribonucleoprotein particles

The trans-splicing reaction occurring in trypanosomes and related species as well as in the nematode Caenorhabditis elegans involves the transfer of a 5' exon from a spliced leader transcript (SL RNA) to a precursor messenger RNA transcript with a 3' splice acceptor site. This seems to take place in the same nuclear compartment as normal cis splicing and proceeds through Y-branched intermediates analogous to the lariats formed in cis splicing. The cellular machinery catalysing cis and trans splicing might therefore be expected to share some components, particularly in the nematode where some mRNAs are produced by both cis and trans splicing. We generated possible secondary structures for the SL RNAs of several species and found they were remarkably similar although neither nucleotide sequence nor length is conserved. Each contained three stem-loops; strikingly the 5' splice site is adjacent to the turn of the most 5' loop and an Sm-binding consensus sequence is found between the second and third stem-loops. Sm is an antigen associated with small nuclear ribonucleoprotein particles (snRNPs). When incubated in HeLa cell nuclear extracts, SL RNAs become immunoprecipitable by anti-Sm, but not by other autoantibodies directed against proteins of mammalian snRNPs. We propose that SL RNAs have a dual function in the trans splicing process: they consist of a 5' exon covalently linked to an snRNA-like sequence and seem likely to exist as Sm snRNP particles (SL snRNPs) within the cell. Just as the RNA in the U1 snRNP base-pairs with the 5' splice site, rendering it susceptible to attack in the cis-splicing reaction, so might the SL snRNP autonomously activate its own 5' splice site and thereby eliminate the need for a U1-like snRNP in the trans-splicing machinery.