A new consensus for Trypanosoma cruzi intraspecific nomenclature: second revision meeting recommends TcI to TcVI.

In an effort to unify the nomenclature of Trypanosoma cruzi, the causative agent of Chagas disease, an updated system was agreed upon at the Second Satellite Meeting. A consensus was reached that T. cruzi strains should be referred to by six discrete typing units (T. cruzi I-VI). The goal of a unified nomenclature is to improve communication within the scientific community involved in T. cruzi research. The justification and implications will be presented in a subsequent detailed report.

Transcription termination and 3'-End processing of the spliced leader RNA in kinetoplastids.

Addition of a 39-nucleotide (nt) spliced leader (SL) by trans splicing is a basic requirement for all trypanosome nuclear mRNAs. The SL RNA in Leishmania tarentolae is a 96-nt precursor transcript synthesized by a polymerase that resembles polymerase II most closely. To analyze SL RNA genesis, we mutated SL RNA intron structures and sequence elements: stem-loops II and III, the Sm-binding site, and the downstream T tract. Using an exon-tagged SL RNA gene, we examined the phenotypes produced by a second-site 10-bp linker scan mutagenic series and directed mutagenesis. Here we report that transcription is terminated by the T tract, which is common to the 3' end of all kinetoplastid SL RNA genes, and that more than six T's are required for efficient termination in vivo. We describe mutants whose SL RNAs end in the T tract or appear to lack efficient termination but can generate wild-type 3' ends. Transcriptionally active nuclear extracts show staggered products in the T tract, directed by eight or more T's. The in vivo and in vitro data suggest that SL RNA transcription termination is staggered in the T tract and is followed by nucleolytic processing to generate the mature 3' end. We show that the Sm-binding site and stem-loop III structures are necessary for correct 3'-end formation. Thus, we have defined the transcription termination element for the SL RNA gene. The termination mechanism differs from that of vertebrate small nuclear RNA genes and the SL RNA homologue in Ascaris.

petD mRNA maturation in Chlamydomonas reinhardtii chloroplasts: role of 5' endonucleolytic processing.

Complex processing of primary transcripts occurs during the expression of higher-plant chloroplast genes. In Chlamydomonas reinhardtii, most chloroplast genes appear to possess their own promoters, rather than being transcribed as part of multicistronic operons. By generating specific deletion mutants, we show that petD, which encodes subunit IV of the cytochrome b6/f complex, has an RNA processing site that is required for accumulation of monocistronic petD mRNA in petD promoter deletion mutants; in such mutants, transcription of petD originates from the upstream petA promoter. The 5' ends of transcripts initiated at the petD promoter are probably also generated by processing, since the 5' end of monocistronic petD mRNA is the same in wild-type strains as it is in the petD promoter mutants. The location and function of the processing site were further examined by inserting petD-uidA fusion genes into the chloroplast genome (uidA is an Escherichia coli gene that encodes beta-glucuronidase). When a promoterless petD-uidA fusion gene was inserted downstream of petA, a monocistronic uidA transcript accumulated, which was apparently initiated at the petA promoter and was processed at a site corresponding precisely to the petD mRNA 5' end. When a construct including only sequences downstream of +25 relative to the mature mRNA 5' end was inserted into the same site, a dicistronic petA-uidA transcript accumulated but no monocistronic uidA transcript could be detected, suggesting that a processing site lies at least partially within the region from -1 to +25. Beta-glucuronidase activity was not detected in transformants that accumulated only the dicistronic petA-uidA transcript, suggesting that the first 25 bp of the 5' untranslated region are required for translation initiation. One explanation for this translational defect is that Chlamydomonas chloroplasts cannot translate the second coding region of some dicistronic messages.

The petD gene is transcribed by functionally redundant promoters in Chlamydomonas reinhardtii chloroplasts.

FUD6, a nonphotosynthetic mutant of Chlamydomonas reinhardtii, was previously found to be deficient in the synthesis of subunit IV of the cytochrome b6/f complex, the chloroplast petD gene product (C. Lemaire, J. Girard-Bascou, F.-A. Wollman, and P. Bennoun, Biochim. Biophys. Acta 851:229-238, 1986). The lesion in FUD6 is a 236-bp deletion between two 11-bp direct repeats in the chloroplast genome. It extends from 82 to 72 bp upstream of the 5' end of wild-type petD mRNA to 156 to 166 bp downstream of the 5' end. Thus, the deletion extends into the putative promoter and 5' untranslated region of petD. No petD mRNA of the normal size can be detected in FUD6 cells, but a low level of a dicistronic message accumulates, which contains the coding regions for subunit IV and cytochrome f, the product of the upstream petA gene. petD transcriptional activity in FUD6 is not significantly altered from the wild-type level. This transcriptional activity was eliminated by petA promoter disruptions, suggesting that it originates at the petA promoter. We conclude that the petD-coding portion of most cotranscripts is rapidly degraded in FUD6, possibly following processing events that generate the 3' end of petA mRNA. A chloroplast transformant was constructed in which only the sequence from -81 to -2 relative to the major 5' end of the petD transcript was deleted. Although this deletion eliminates all detectable petD promoter activity, the transformant grows phototrophically and accumulates high levels of monocistronic petD mRNA. We conclude that the petD gene can be transcribed by functionally redundant promoters. In the absence of a functional petD promoter, a lack of transcription termination allows the downstream petD gene to be cotranscribed with the petA coding region and thereby expressed efficiently.

An intergenic G-rich region in Leishmania tarentolae kinetoplast maxicircle DNA is a pan-edited cryptogene encoding ribosomal protein S12.

Six short G-rich intergenic regions in the maxicircle of Leishmania tarentolae are conserved in location and polarity in two other kinetoplastid species. We show here that G-rich region 6 (G6) represents a pan-edited cryptogene which contains at least two domains edited independently in a 3'-to-5' manner connected by short unedited regions. In the completely edited RNA, 117 uridines are added at 49 sites and 32 uridines are deleted at 13 sites, creating a translated 85-amino-acid polypeptide. Similar polypeptides are probably encoded by pan-edited G6 transcripts in two other species. The G6 polypeptide has significant sequence similarity to the family of S12 ribosomal proteins. A minicircle-encoded gRNA overlaps 12 editing sites in G6 mRNA, and chimeric gRNA/mRNA molecules were shown to exist, in agreement with the transesterification model for editing.

Three small nucleolar RNAs identified from the spliced leader-associated RNA locus in kinetoplastid protozoans.

First characterized in Trypanosoma brucei, the spliced leader-associated (SLA) RNA gene locus has now been isolated from the kinetoplastids Leishmania tarentolae and Trypanosoma cruzi. In addition to the T. brucei SLA RNA, both L. tarentolae and T. cruzi SLA RNA repeat units also yield RNAs of 75 or 76 nucleotides (nt), 92 or 94 nt, and approximately 450 or approximately 350 nt, respectively, each with significant sequence identity to transcripts previously described from the T. brucei SLA RNA locus. Cell fractionation studies localize the three additional RNAs to the nucleolus; the presence of box C/D-like elements in two of the transcripts suggests that they are members of a class of small nucleolar RNAs (snoRNAs) that guide modification and cleavage of rRNAs. Candidate rRNA-snoRNA interactions can be found for one domain in each of the C/D element-containing RNAs. The putative target site for the 75/76-nt RNA is a highly conserved portion of the small subunit rRNA that contains 2'-O-ribose methylation at a conserved position (Gm1830) in L. tarentolae and in vertebrates. The 92/94-nt RNA has the potential to form base pairs near a conserved methylation site in the large subunit rRNA, which corresponds to position Gm4141 of small rRNA 2 in T. brucei. These data suggest that trypanosomatids do not obey the general 5-bp rule for snoRNA-mediated methylation.

Characterization of a GTP-binding protein in the ADP-ribosylation factor subfamily from Leishmania tarentolae.

We report the cloning and characterization of a gene, LtARL, which encodes a small GTP-binding protein, from the protozoan Leishmania tarentolae. Hybridization analysis of genomic DNA under high stringency conditions indicates the single-copy nature of LtARL. LtARL is transcribed and yields a approximately 0.9 kb mRNA that is processed at the 5' end by trans-splicing. When expressed in Escherichia coli, LtArl binds GTP with a low stoichiometry and in a phospholipid-independent manner. Based on the greatest sequence identity with Homo sapiens Arl3 and lipid-independent binding of guanine nucleotides we designate this gene LtARL and the encoded protein LtArl.

Sensitive detection and schizodeme classification of Trypanosoma cruzi cells by amplification of kinetoplast minicircle DNA sequences: use in diagnosis of Chagas' disease.

Amplification of DNA sequences from the kinetoplast minicircle DNA was employed as a method for the detection and classification of small numbers of Trypanosoma cruzi cells. Two overlapping fragments from the conserved 120 bp minirepeat regions of the minicircle DNA and one fragment covering the adjacent variable regions were amplified. The minimal amount of minicircle DNA required to detect a product by hybridization with an oligonucleotide probe was 0.015 fg, which represents approximately 10 molecules or 0.1% of the minicircle DNA component of a single cell. The amplification worked equally well with kDNA from several strains of T. cruzi and did not occur with kDNA from several other kinetoplastids. kDNA recovered from less than 10 trypanosomes in whole blood could be used as a template for amplification; the presence of a several billion fold excess of human DNA had no effect on the amplification process. Schizodeme analysis by hybridization with specific oligonucleotides or by direct restriction enzyme digestion could be performed on the amplified fragments representing the minicircle conserved region or variable regions. This method should prove useful as a rapid, specific and sensitive assay for Chagas' disease in chronic patients as well as for epidemiological studies of infected animals and insects.

In vitro transcription of mutated Leishmania tarentolae spliced leader RNA genes approximates in vivo patterns.

To elucidate the process of transcription in the kinetoplastids and to aid in the purification of transcription factors, we have developed a transcriptionally-competent nuclear extract from Leishmania tarentolae for the study of the spliced leader (SL) RNA gene. The extract was competent to transcribe a tagged SL RNA gene. The in vitro SL RNA transcripts initiated accurately and their synthesis was dependent on the presence of the promoter defined in vivo. The nuclear extract was then challenged rigorously using an exhaustive set of mutated SL RNA gene templates previously tested for transcriptional activity in vivo. Mutation of four nucleotides (CCGG) at positions -34 to -31 had a detrimental effect on transcription in vitro: the CC dinucleotide overlaps one element necessary in vivo. Similarly. four nucleotides (TGAC; positions -67 to -64) important for transcription in vitro overlapped the other core promoter element defined in vivo, but were generally not effective as point mutations. The promoter-binding ability of the transcriptionally-competent extract for the -60 region mutations mirrored the in vitro transcription pattern. Although it does not reflect precisely the in vivo results, this in vitro system provides us with an important tool for monitoring the purification of potential transcription factors, as well as the basis for future reconstitution experiments.

Single nucleotide resolution of promoter activity and protein binding for the Leishmania tarentolae spliced leader RNA gene.

In Kinetoplastid protozoa, trans-splicing is a central step in the maturation of nuclear mRNAs. In Leishmania, a common 39 nt spliced-leader (SL) is transferred via trans-splicing from the precursor 96 nt SL RNA to the 5' terminus of all known protein-encoding RNAs. In this study, promoter elements of the L. tarentolae SL RNA gene have been identified with respect to transcriptional activity and putative transcription factor binding. We have mapped the essential regions in the SL RNA gene promoter at single nucleotide resolution using both in vivo transcription and in vitro protein/DNA binding approaches. Two regions located upstream of the SL RNA gene were identified: a GN3CCC element at -39 to -33 and a GACN5G element at -66 to -58 were essential for SL RNA gene transcription in stably transfected cells. Consistent with other known bipartite promoter elements, the spacing between the GN3CCC and GACN5G elements was found to be critical for proper promoter function and correct transcription start point selection, as was the distance between the two elements and the wild-type transcription start point. The GACN5G element interacts specifically and in a double-stranded form with a protein(s) in Leishmania nuclear extracts. The degree of this protein DNA interaction in vitro correlated with SL RNA gene transcription efficiency in vivo, consistent with a role of the protein as a transcription factor. The core nucleotides GACN5G fit the consensus PSE promoter structure of pol II-transcribed snRNA genes in metazoa.

The mini-exon genes of three Phytomonas isolates that differ in plant tissue tropism.

The tandem mini-exon gene repeat is an ideal diagnostic target for trypanosomatids because it includes sequences that are conserved absolutely coupled with regions of extreme variability. We have exploited these features and the polymerase chain reaction to differentiate Phytomonas strains isolated from phloem, fruit or latex of various host plants. While the transcribed regions are nearly identical, the intergenic sequences are variable in size and content (130-332 base pairs). The mini-exon genes of these phytomonads can therefore be distinguished from each other and from the corresponding genes in insect trypanosomes, with which they are oft confused.

Two sequence classes of kinetoplastid 5S ribosomal RNA gene revealed among bodonid spliced leader RNA gene arrays.

The spliced leader RNA genes of Bodo saltans, Cryptobia helicis and Dimastigella trypaniformis were analyzed as molecular markers for additional taxa within the suborder Bodonina. The non-transcribed spacer regions were distinctive for each organism, and 5S rRNA genes were present in Bodo and Dimastigella but not in C. helicis. Two sequence classes of 5S rRNA were evident from analysis of the bodonid genes. The two classes of 5S rRNA genes were found in other Kinetoplastids independent of co-localization with the spliced leader RNA gene.

Kinetoplast DNA minicircles of phloem-restricted Phytomonas associated with wilt diseases of coconut and oil palms have a two-domain structure.

We report the cloning and sequencing of the first minicircle from a phloem-restricted, pathogenic Phytomonas sp. (Hart 1) isolated from a coconut palm with hartrot disease. The minicircle possessed a two-domain structure of two conserved regions, each containing three conserved sequence blocks (CSB). Based on the sequence around CSB 3 from Hart 1, PCR primers were designed to allow specific amplification of Phytomonas minicircles. This primer pair demonstrated specificity for at least six groups of plant trypanosomatids and did not amplify from insect trypanosomatids. The PCR results were consistent with a two-domain structure for other plant trypanosomatids.

The mini-exon gene of Trypanosoma (Nannomonas) simiae: sequence variation between isolates and a distinguishing molecular marker.

The mini-exon gene repeats from two isolates of Trypanosoma (Nannomonas) simiae were amplified by polymerase chain reaction (PCR). The products from each isolate differed in size, however they cross-hybridised in Southern blots. The nature of the size variation was revealed by comparison of the DNA sequence of each repeat: relative to the BAN7 strain, the mini-exon gene of KETRI 2431 contained three apparent deletions that were flanked by short (> or = 6-bp) direct repeats. Furthermore, one of the cloned repeats was used as a hybridisation probe against DNA from other closely-related African trypanosomes. The lack of hybridisation of the T. (N.) simiae mini-exon gene to genomic DNA from the Forest, Kilifi and Savannah subgroups of T. (N.) congolense and T. (N.) godfreyi indicate that this PCR-hybridisation assay may be useful for distinguishing T. (N.) simiae from other members of the subgenus Nannomonas.

Partially edited mRNAs for cytochrome b and subunit III of cytochrome oxidase from Leishmania tarentolae mitochondria: RNA editing intermediates.

Partially edited mRNAs were selected by the polymerase chain reaction and sequenced. In the case of cytochrome b, 102 out of 106 clones displayed patterns of editing that were consistent with a strictly progressive 3' to 5' editing process, as predicted by the guide RNA model of RNA editing. In the case of cytochrome oxidase subunit III (COIII), 177 out of 304 clones displayed strictly progressive 3' to 5' patterns of editing. However, the remaining 127 COIII clones displayed unexpected patterns in which upstream editing preceded downstream editing, uridines were inserted at sites not normally edited, and purine residues were deleted. We suggest that many of these RNAs are produced by normal 3' to 5' editing of the COIII mRNA with incorrect guide RNA molecules.

Leishmania tarentolae minicircles of different sequence classes encode single guide RNAs located in the variable region approximately 150 bp from the conserved region.

The complete sequences of three kinetoplast DNA minicircles (B4, D3 and D12) from Leishmania tarentolae are reported. All L. tarentolae minicircles encode single gRNAs localized within the variable region approximately 150 bp from the conserved region. The 5' termini and tentative 3' termini of the new gRNAs were determined and the gene sequences and flanking sequences of all minicircle gRNA genes compared for conserved motifs of possible transcriptional regulatory significance. All minicircle gRNAs possess 3' oligo-[U] tails of variable length similar to maxicircle gRNAs. A role for the D3 minicircle gRNA in the editing of the 5' pan-edited MURF4 mRNA was suggested by sequence analysis, and a role for the D12 minicircle gRNA in the editing of the COIII mRNA and another minicircle gRNA (Lt154) in the editing of the pan-edited G6 mRNA have been previously reported. The cryptogene mRNAs edited by the B4 and Lt19 minicircle gRNAs are yet undetermined.

The role of intron structures in trans-splicing and cap 4 formation for the Leishmania spliced leader RNA.

A 39-nucleotide leader is trans-spliced onto all trypanosome nuclear mRNAs. The precursor spliced leader RNA was tested for trans-splicing function in vivo by mutating the intron. We report that in Leishmania tarentolae spliced leader RNA 5' modification is influenced by the primary sequence of stem-loop II, the Sm-binding site, and the secondary structure of stem-loop III. The sequence of stem-loop II was found to be important for cap 4 formation and splicing. As in Ascaris, mutagenesis of the bulge nucleotide in stem-loop II was detrimental to trans-splicing. Because restoration of the L. tarentolae stem-loop II structure was not sufficient to restore splicing, this result contrasts the findings in the kinetoplastid Leptomonas, where mutations that restored stem-loop II structure supported splicing. Methylation of the cap 4 structure and splicing was also dependent on both the Sm-binding site and the structure of stem-loop III and was inhibited by incomplete 3' end processing. The critical nature of the L. tarentolae Sm-binding site is consistent with its essential role in the Ascaris spliced leader RNA, whereas in Leptomonas mutation of the Sm-binding site and deletion of stem-loop III did not affect trans-splicing. A pathway for Leishmania spliced leader RNA processing and maturation is proposed.