Comparison of the maxicircle (mitochondrial) genomes of Leishmania tarentolae and Trypanosoma brucei at the level of nucleotide sequence

The entire 16.7-kilobase (kb) transcribed region of the Leishmania tarentolae maxicircle was compared to the entire 15-kb transcribed region of the Trypanosoma brucei maxicircle at the nucleotide sequence level by dot matrix analysis and by alignments of individual genes. The L. tarentolae NADH dehydrogenase subunit 1 (ND1) gene was identified in a newly obtained 2.9-kb sequence. All but two regions which flank the cytochrome b gene are highly conserved in both species. One 3.1-kb region in L. tarentolae that contains the cytochrome oxidase subunit III (COIII) gene and several open reading frames corresponds to a 2-kb sequence in T. brucei with limited sequence homology that lacks the COIII gene. Another 0.6-kb region that comprises an unidentified open reading frame (open reading frame 12) in L. tarentolae is substituted by a nonhomologous 0.4-kb open reading frame in T. brucei. A short intergenic region between the ND1 gene and the maxicircle unidentified reading frame 1 gene shows limited sequence homology, and the regions between the ND4 and ND5 genes and between the COI and ND4 genes are not conserved. All of the intergenic regions share G + C richness and a similar pattern of G versus C strand bias. 1.8 kb of the L. tarentolae divergent region (DV) and around 3 kb of the T. brucei DV were also obtained. The T. brucei DV sequences were not homologous to the L. tarentolae DV sequence but were organized in a similar fashion with tandem repeats of varying complexity.     

Structure and organization of Marchantia polymorpha chloroplast genome. IV. Inverted repeat and small single copy regions

We characterized the genes in the regions of large inverted repeats (IRA and IRB, 10,058 base-pairs each) and a small single copy (SSC 19,813 bp) of chloroplast DNA from Marchantia polymorpha. The inverted repeat (IR) regions contain genes for four ribosomal RNAs (16 S, 23 S, 4.5 S and 5 S rRNAs) and five transfer RNAs (valine tRNA(GAC), isoleucine tRNA(GAU), alanine tRNA(UGC), arginine tRNA(ACG) and asparagine tRNA(GUU)). The gene organization of the IR regions in the liverwort chloroplast genome is conserved, although the IR regions are smaller (10,058 base-pairs) than any reported in higher plant chloroplasts. The small single-copy region (19,813 base-pairs) encoded genes for 17 open reading frames, a leucine tRNA(UAG) and a proline tRNA(GGG)-like sequence. We identified 12 open reading frames by homology of their coding sequences to a 4Fe-4S-type ferredoxin protein, a bacterial nitrogenase reductase component (Fe-protein), five human mitochondrial components of NADH dehydrogenase (ND1, ND4, ND4L, ND5 and ND6), two Escherichia coli ribosomal proteins (S15 and L21), two putative proteins encoded in the kinetoplast maxicircle DNA of Leishmania tarentolae (LtORF 3 and LtORF 4), and a bacterial permease inner membrane component (encoded by malF in E. coli or hisQ in Salmonella typhimurium).     

The ATPase subunit 6 gene sequence predicts that RNA editing is conserved between lizard- and human-infecting Leishmania.

Here we investigate the similarities in the kinetoplastid RNA editing process between human- and lizard-infecting Leishmania species. We present the sequence of the maxicircle-encoded ATPase subunit 6 gene from L. (V.) panamensis, L. (L.) mexicana and L. (L.) donovani species of human-infecting Leishmania. These represent the first available sequences of this gene from Leishmania species other than the lizard-infecting L. tarentolae. The gene sequences are highly conserved, both over the edited and unedited parts of the gene, implying that the RNA editing process is likely to be highly conserved between Leishmania species. Indeed, the first editing domain is absolutely conserved in all three Leishmania species studied and L. tarentolae. A phylogeny based on part of the ATPase subunit 6 gene placed the lizard-infecting Leishmania within the monophyletic Leishmania genus, supporting previous data which suggest that lizard- and human-infecting Leishmania species are closely related.     

Genome sequencing of the lizard parasite Leishmania tarentolae reveals loss of genes associated to the intracellular stage of human pathogenic species

The Leishmania tarentolae Parrot-TarII strain genome sequence was resolved to an average 16-fold mean coverage by next-generation DNA sequencing technologies. This is the first non-pathogenic to humans kinetoplastid protozoan genome to be described thus providing an opportunity for comparison with the completed genomes of pathogenic Leishmania species. A high synteny was observed between all sequenced Leishmania species. A limited number of chromosomal regions diverged between L. tarentolae and L. infantum, while remaining syntenic to L. major. Globally, >90% of the L. tarentolae gene content was shared with the other Leishmania species. We identified 95 predicted coding sequences unique to L. tarentolae and 250 genes that were absent from L. tarentolae. Interestingly, many of the latter genes were expressed in the intracellular amastigote stage of pathogenic species. In addition, genes coding for products involved in antioxidant defence or participating in vesicular-mediated protein transport were underrepresented in L. tarentolae. In contrast to other Leishmania genomes, two gene families were expanded in L. tarentolae, namely the zinc metallo-peptidase surface glycoprotein GP63 and the promastigote surface antigen PSA31C. Overall, L. tarentolae's gene content appears better adapted to the promastigote insect stage rather than the amastigote mammalian stage.     

Sequences of six genes and several open reading frames in the kinetoplast maxicircle DNA of Leishmania tarentolae

The DNA sequence of approximately 80% of the transcribed region of the kinetoplast maxicircle DNA of Leishmania tarentolae was obtained, and structural genes were localized by comparison of the translated amino acid sequences with those of known mitochondrial genes from other organisms. By this method, the genes for cytochrome oxidase subunits I, II, and III, cytochrome b, and human mitochondrial unidentified reading frames 4 and 5 were identified. By comparing the amino acid sequences of the putative L. tarentolae genes with those of known genes, we conclude that TGA codes for tryptophan, as in most other mitochondrial systems. This is the only apparent change from the universal genetic code. The six identified structural genes show various degrees of divergence from the homologous genes in other species, with cytochrome oxidase subunit I being the most conserved and cytochrome oxidase subunit III being the least conserved. A comparison of the cytochrome b genes from L. tarentolae and Trypanosoma brucei showed that the ratio of transversions to transitions is 1:1, suggesting that these species diverged from each other more than 80 X 10(6) years ago. Several as yet unidentified open reading frames were also present in the maxicircle sequence. These data confirm that maxicircle DNA has a coding potential which typifies other mitochondrial systems.     

Restriction map, partial cloning and localization of 9S and 12S kinetoplast RNA genes on the maxicircle component of the kinetoplast DNA of Leishmania tarentolae.

We have constructed a restriction map of the maxicircle component of the kinetoplast DNA of Leishmania tarentolae for the enzymes EcoRI, Bam HI, HaeIII, HpaII, SalI, BglII and HindIII. The 9 and 12S kinetoplast RNAs were localized on this map. Two fragments of this maxicircle molecule were cloned in the bacterial plasmid, pBR322, including a 4.4 . 10(6) dalton EcoRI/BamHI fragment which contains the 9 and 12S RNA genes.     

Identification of a gp63 surface glycoprotein in Leishmania tarentolae

The promastigote stage of most if not all Leishmania species possesses an abundant surface glycoprotein of 63 kDa (gp63) that has protease activity. We show that the lizard parasite Leishmania tarentolae appears to lack the surface protease activity. L. tarentolae does, however, possess an approximately 63-kDa molecule that is antigenically cross-reactive with the L. major gp63. Additionally, the genome of L. tarentolae contains sequences that hybridise at high stringency to a L. major gp63 gene probe.     

Primary sequence and partial secondary structure of the 12S kinetoplast (mitochondrial) ribosomal RNA from Leishmania tarentolae: conservation of peptidyl-transferase structural elements.

The sequence of the 1173 nt 12S kinetoplast ribosomal RNA from Leishmania tarentolae was determined from the maxicircle DNA sequence, and the 5' and 3' ends localized by primer runoff and S1 nuclease protection experiments. The gene was shown to be free of introns by S1 nuclease analysis. A partial secondary structure model of the 12S RNA molecule is presented which is equivalent in certain respects to the corresponding portions of the Escherichia coli 23S ribosomal RNA model. Domain II of the E. coli model is completely missing in the kinetoplast model with the exception of several phylogenetically conserved stems and one loop. There is a striking conservation of the functionally important peptidyl-transferase region except for the deletion of a few stems and loops. The 12S RNA is the smallest large subunit ribosomal RNA described to date.