Presence of a bent helix in fragments of kinetoplast DNA minicircles from several trypanosomatid species

Comparison of the Mitochondrial Genomes and Steady State Transcriptomes of Two Strains of the Trypanosomatid Parasite, Leishmania tarentolae

U-insertion/deletion RNA editing is a post-transcriptional mitochondrial RNA modification phenomenon required for viability of trypanosomatid parasites. Small guide RNAs encoded mainly by the thousands of catenated minicircles contain the information for this editing. We analyzed by NGS technology the mitochondrial genomes and transcriptomes of two strains, the old lab UC strain and the recently isolated LEM125 strain. PacBio sequencing provided complete minicircle sequences which avoided the assembly problem of short reads caused by the conserved regions. Minicircles were identified by a characteristic size, the presence of three short conserved sequences, a region of inherently bent DNA and the presence of single gRNA genes at a fairly defined location. The LEM125 strain contained over 114 minicircles encoding different gRNAs and the UC strain only ~24 minicircles. Some LEM125 minicircles contained no identifiable gRNAs. Approximate copy numbers of the different minicircle classes in the network were determined by the number of PacBio CCS reads that assembled to each class. Mitochondrial RNA libraries from both strains were mapped against the minicircle and maxicircle sequences. Small RNA reads mapped to the putative gRNA genes but also to multiple regions outside the genes on both strands and large RNA reads mapped in many cases over almost the entire minicircle on both strands. These data suggest that minicircle transcription is complete and bidirectional, with 3’ processing yielding the mature gRNAs. Steady state RNAs in varying abundances are derived from all maxicircle genes, including portions of the repetitive divergent region. The relative extents of editing in both strains correlated with the presence of a cascade of cognate gRNAs. These data should provide the foundation for a deeper understanding of this dynamic genetic system as well as the evolutionary variation of editing in different strains.

U-insertion/deletion RNA editing is a unique post-transcriptional mRNA modification process that occurs in trypanosomatid parasites and is required for viability. The participation of guide RNAs which are transcribed from the thousands of catenated minicircles in determining the precise sites and number of U’s inserted and deleted to create translatable mRNAs is novel and significant in terms of the recently realized importance of small RNAs in biology. This study contributes the necessary bioinformatics foundation for a deeper understanding of this important genetic system in molecular detail using a model trypanosomatid, Leishmania tarentolae. We used Next Generation Sequencing methods to determine the complete maxicircle and minicircle genomes and to map maxicircle pre-edited and edited transcripts and minicircle transcripts. The transcription of minicircle-encoded guide RNAs was confirmed and novel information about minicircle gene expression was obtained. The biological context involved a comparison of two strains of the parasites, one recently isolated and having an intact mitochondrial genetic system and the other an old lab strain that has developed a partially defective mitochondrial genome. The data are important for an understanding of the mitochondrial genomic complexity and expression of this dynamic genetic system.

DNA structure and function

The proposal of a double-helical structure for DNA over 60 years ago provided an eminently satisfying explanation for the heritability of genetic information. But why is DNA, and not RNA, now the dominant biological information store? We argue that, in addition to its coding function, the ability of DNA, unlike RNA, to adopt a B-DNA structure confers advantages both for information accessibility and for packaging. The information encoded by DNA is both digital - the precise base specifying, for example, amino acid sequences - and analogue. The latter determines the sequence-dependent physicochemical properties of DNA, for example, its stiffness and susceptibility to strand separation. Most importantly, DNA chirality enables the formation of supercoiling under torsional stress. We review recent evidence suggesting that DNA supercoiling, particularly that generated by DNA translocases, is a major driver of gene regulation and patterns of chromosomal gene organization, and in its guise as a promoter of DNA packaging enables DNA to act as an energy store to facilitate the passage of translocating enzymes such as RNA polymerase.

Genomic analysis of sequence-dependent DNA curvature in Leishmania

Leishmania major is a flagellated protozoan parasite of medical importance. Like other members of the Trypanosomatidae family, it possesses unique mechanisms of gene expression such as constitutive polycistronic transcription of directional gene clusters, gene amplification, mRNA trans-splicing, and extensive editing of mitochondrial transcripts. The molecular signals underlying most of these processes remain under investigation. In order to investigate the role of DNA secondary structure signals in gene expression, we carried out a genome-wide in silico analysis of the intrinsic DNA curvature. The L. major genome revealed a lower frequency of high intrinsic curvature regions as well as inter- and intra- chromosomal distribution heterogeneity, when compared to prokaryotic and eukaryotic organisms. Using a novel method aimed at detecting region-integrated intrinsic curvature (RIIC), high DNA curvature was found to be associated with regions implicated in transcription initiation. Those include divergent strand-switch regions between directional gene clusters and regions linked to markers of active transcription initiation such as acetylated H3 histone, TRF4 and SNAP50. These findings suggest a role for DNA curvature in transcription initiation in Leishmania supporting the relevance of DNA secondary structures signals.

Molecular parasitology in the 21st century

Protist parasites cause important human and animal diseases, and because of their early divergence from other eukaryotes they possess structural and biochemical characteristics not found in other cells. The completion of the genome projects of most human protist parasites and the development of novel molecular tools for their study guarantee a rapid progress in understanding how they invade, modify and survive within their hosts. The ultimate goal of these studies will be the identification of targets for the design of drugs, diagnostics and vaccines. In addition, the accessibility of some of these parasites to multiple genetic manipulations has converted them into model systems in cell and molecular biology studies that could lead to the understanding of basic biological processes, as well as their evolution and pathogenesis. In the present chapter we discuss the biochemical and molecular peculiarities of these parasites and the molecular tools available for their study.

Conserved repeats in the kinetoplast maxicircle divergent region of Leishmania sp. and Leptomonas seymouri

The maxicircle control region [also termed divergent region (DR)] composed of various repeat elements remains the most poorly studied part of the kinetoplast genome. Only three extensive DR sequences demonstrating no significant similarity were available for trypanosomatids (Leishmania tarentolae, Crithidia oncopelti, Trypanosoma brucei). Recently, extensive DR sequences have been obtained for Leishmania major and Trypanosoma cruzi. In this work we have sequenced DR fragments of Leishmania turanica, Leishmania mexicana, Leishmania chagasi and two monogenetic trypanosomatids Leptomonas seymouri and Leptomonas collosoma. With the emergence of the additional extensive sequences some conserved features of DR structure become evident. A conserved palindromic sequence has been revealed in the DRs of the studied Leishmania species, L. seymouri, and T. cruzi. The overall DR structure appears to be similar in all the Leishmania species, their relative L. seymouri, and T. brucei: long relatively GC-rich repeats are interspersed with clusters of short AT-rich repeats. C. oncopelti, L. collosoma, and T. cruzi have a completely different DR structure. Identification of conserved sequences and invariable structural features of the DR may further our understanding of the functioning of this important genome fragment.

Trypanosoma cruzi mitochondrial maxicircles display species- and strain-specific variation and a conserved element in the non-coding region

BACKGROUND

The mitochondrial DNA of kinetoplastid flagellates is distinctive in the eukaryotic world due to its massive size, complex form and large sequence content. Comprised of catenated maxicircles that contain rRNA and protein-coding genes and thousands of heterogeneous minicircles encoding small guide RNAs, the kinetoplast network has evolved along with an extreme form of mRNA processing in the form of uridine insertion and deletion RNA editing. Many maxicircle-encoded mRNAs cannot be translated without this post-transcriptional sequence modification.

RESULTS

We present the complete sequence and annotation of the Trypanosoma cruzi maxicircles for the CL Brener and Esmeraldo strains. Gene order is syntenic with Trypanosoma brucei and Leishmania tarentolae maxicircles. The non-coding components have strain-specific repetitive regions and a variable region that is unique for each strain with the exception of a conserved sequence element that may serve as an origin of replication, but shows no sequence identity with L. tarentolae or T. brucei. Alternative assemblies of the variable region demonstrate intra-strain heterogeneity of the maxicircle population. The extent of mRNA editing required for particular genes approximates that seen in T. brucei. Extensively edited genes were more divergent among the genera than non-edited and rRNA genes. Esmeraldo contains a unique 236-bp deletion that removes the 5'-ends of ND4 and CR4 and the intergenic region. Esmeraldo shows additional insertions and deletions outside of areas edited in other species in ND5, MURF1, and MURF2, while CL Brener has a distinct insertion in MURF2.

CONCLUSION

The CL Brener and Esmeraldo maxicircles represent two of three previously defined maxicircle clades and promise utility as taxonomic markers. Restoration of the disrupted reading frames might be accomplished by strain-specific RNA editing. Elements in the non-coding region may be important for replication, transcription, and anchoring of the maxicircle within the kinetoplast network.

Mitochondrial genome diversity in parasites

Mitochondrial genomes have been sequenced from a wide variety of organisms, including an increasing number of parasites. They maintain some characteristics in common across the spectrum of life-a common core of genes related to mitochondrial respiration being most prominent-but have also developed a great diversity of gene content, organisation, and expression machineries. The characteristics of mitochondrial genomes vary widely among the different groups of protozoan parasites, from the minute genomes of the apicomplexans to amoebae with 20 times as many genes. Kinetoplastid protozoa have a similar number of genes to metazoans, but the details of gene organisation and expression in kinetoplastids require extraordinary mechanisms. Mitochondrial genes in nematodes and trematodes appear quite sedate in comparison, but a closer look shows a strong tendency to unusual tRNA structure and alternative initiation codons among these groups. Mitochondrial genes are increasingly coming into play as aids to phylogenetic and epidemiologic analyses, and mitochondrial functions are being recognised as potential drug targets. In addition, examination of mitochondrial genomes is producing further insights into the diversity of the wide-ranging group of organisms comprising the general category of parasites.

Phytomonas and other trypanosomatid parasites of plants and fruit

Trypanosomatid parasites are fairly common in the latex, phloem, fruit sap, seed albumen, and even in the nectar, of many plant families. They are transmitted to the plants in the saliva of phytophagous hemipterous bugs (Insecta). Morphologically, plant trypanosomatids have no special characteristic, except perhaps a very twisted cell body. Most occur in plants as promastigotes and a few as choanomastigotes. It is still controversial whether or not they are pathogenic in lactiferous plants or fruit, but it is certain that the phloem parasites are pathogenic in coconut palms and coffee bushes. In these plants, they cause lethal diseases responsible for the destruction of many plantations in Central and South America, but fortunately nowhere else in the world. Probably more than one genus of Trypanosomatidae is represented among the plant parasites. The most important is certainly Phytomonas, but Leptomonas, Crithidia and Herpetomonas may also be present. The distinction between them is difficult and only recently have molecular markers become available to help in their identification. At present, Phytomonas can be identified by DNA hybridization with a specific probe (SL3') complementary to a sequence of the mini-exon or spliced leader gene. The development of a polymerase chain reaction coupled to SL3' hybridization has facilitated the detection of Phytomonas in plants. The phylogeny of Phytomonas is still being worked out. For the moment it can only be said that the genus is very close to Herpetomonas.

Demonstration of mRNA editing and localization of guide RNA genes in kinetoplast-mitochondria of the plant trypanosomatid Phytomonas serpens

Maxicircle molecules of kDNA in several isolates of Phytomonas were detected by hybridization with the 12S rRNA gene probe from Leishmania tarentolae. The estimated size of maxicircles is isolate-specific and varies from 27 to 36 kb. Fully edited and polyadenylated mRNA for kinetoplast-encoded ribosomal protein S12 (RPS12) was found in the steady-state kinetoplast RNA isolated from Phytomonas serpens strain 1G. Two minicircles (1.45 kb) from this strain were also sequenced. Each minicircle contains two 120 bp conserved regions positioned 180 degrees apart, a region enriched with G and T bases and a variable region. One minicircle encodes a gRNA for the first block of editing of RPSl2 mRNA, and the other encodes a gRNA with unknown function. A gRNA gene for the second block of RPSl2 was found on a minicircle sequenced previously. On each minicircle, a gRNA gene is located in the variable region in a similar position and orientation with respect to the conserved regions.

Circular superhelical DNA complexes with synthetic oligopeptide: unusual compact structures and influence of bent sequences on the results of compaction

The organization of synthetic oligopeptide trivaline (1) complexes with four types of circular superhelical DNA preparations was studied by electron microscopy. The DNA molecules in the preparations investigated had different sizes ranging from 2.9 kb to 21.0 kb. Two plasmids contained bent DNA sequences from minicircles of kinetoplast DNA of Leishmania gymnodactili and Trypanosoma boissoni. The main structures in all preparations observed were circular compact particles which coincide in their appearance and compaction coefficient (3,5-3,7) with triple rings described earlier. But along with triple rings the new types of compact structures were observed having the shape of a ring with attached rod or the shape of two compact rings attached to each other by a region of compact fiber. The latter structures could be observed in significant quantities in case of DNA preparations longer than 10 kb. The conclusions can be made that due to TVP stimulated compaction of circular DNA molecules compact fibers containing both two or three DNA duplexes arranged side by side can be formed. It is shown that presence of bent DNA sequences stimulates the formation of structures containing more than one triple ring. It demonstrates the possibility of the primary DNA structure influence on the compaction process in case of the circular molecules. The new ways of circular DNA folding described can be of importance for understanding of DNA organization in different cell structures.

The genomic organization of guide RNA genes in kinetoplastid protozoa: several conundrums and their solutions

The guide RNA (gRNA) paradigm states that the uridine (U) insertion/deletion type of RNA editing is mediated by short 3' uridylylated gRNAs that are complementary to specific blocks of mature edited sequence. These gRNAs contain the edited sequence information in the form of guiding purine residues that can base pair with the inserted U's and do not base pair with encoded U's that are to be deleted. The minicircle gRNA genes in trypanosomatids are localized at specific sites within the variable region, with the number and the precise localization of genes also being species-specific. The total number of minicircle sequence classes and thereby minicircle-encoded gRNAs varies greatly between species and even between different strains of the same species, with the greatest number being in the trypanosome species. Several conundrums which appeared to raise problems for the gRNA paradigm arose during comparative analysis of minicircle gRNA gene organization. The solution of these conundrums has led to a better understanding of the function and evolution of this RNA modification phenomenon.

Isolation of proteins associated with kinetoplast DNA networks in vivo

Kinetoplast DNA (kDNA), the mitochondrial DNA of trypanosomes, is a highly condensed disc-shaped network of catenated DNA circles consisting of maxicircles, the equivalent of conventional mitochondrial DNA, and several thousand smaller circular DNAs termed minicircles. Upon cell lysis, kDNA expands, giving rise to a two-dimensional network of catenated circles with an overall diameter close to that of the whole cell. To identify proteins associated with the condensed form of kDNA in the cell, proteins were reversibly crosslinked to kDNA in whole cells of Crithidia fasciculata by formaldehyde treatment. Crosslinked networks were purified and found to retain a condensed structure which becomes fully expanded upon proteinase K treatment or reversal of the crosslinks by heating at 65 degrees C. Five low molecular weight proteins released from the kDNA by heat treatment were purified by polyacrylamide gel electrophoresis and their amino-terminal sequences were determined. PCR amplification and sequence analysis of cDNA sequences between these amino-terminal sequences and the miniexon (spliced leader) sequence present at the 5' end of all C. fasciculata mRNAs predicts the presence of 9-amino acid presequences with features characteristic of mitochondrial presequences on three of the proteins. Two of these proteins are lysine-rich basic proteins. These findings suggest that basic proteins may play a role in the condensation of kDNA in the kinetoplast and that these proteins are imported into the kinetoplast by a mechanism involving a cleavable presequence.

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.

Trypanosoma equiperdum minicircles encode three distinct primary transcripts which exhibit guide RNA characteristics

The mitochondrial DNA of trypanosomes is composed of maxicircle and minicircle DNAs catenated into a network, called the kinetoplast. Maxicircles encode proteins and RNAs necessary for mitochondrial assembly. Minicircles encode small transcripts which are believed to serve as guide RNAs in the process of RNA editing of maxicircle transcripts. Trypanosoma equiperdum minicircles contain three transcription units which produce three distinct transcripts. The genes for these transcripts are flanked by imperfect 18-bp repeats separated by approximately 110 bp. The transcripts have a 5' triphosphate, indicating that they are primary transcripts. Minicircle transcription initiates at a purine within a conserved sequence, 5'-AYAYA-3', where Y is a pyrimidine, 32 bp from the upstream inverted repeat, suggesting that the repeats may function in transcript initiation. Transcripts from a single minicircle transcription unit range in size from 55 to 70 nucleotides. This size heterogeneity within a single sequence class is due to the variable length of nontemplated uridine residues composing a 3' tail. The size range and heterogeneous polyuridylate 3' end of the minicircle transcripts appear to be conserved features and may be related to transcript function.

Trypanosoma equiperdum minicircles encode three distinct primary transcripts which exhibit guide RNA characteristics

The mitochondrial DNA of trypanosomes is composed of maxicircle and minicircle DNAs catenated into a network, called the kinetoplast. Maxicircles encode proteins and RNAs necessary for mitochondrial assembly. Minicircles encode small transcripts which are believed to serve as guide RNAs in the process of RNA editing of maxicircle transcripts. Trypanosoma equiperdum minicircles contain three transcription units which produce three distinct transcripts. The genes for these transcripts are flanked by imperfect 18-bp repeats separated by approximately 110 bp. The transcripts have a 5' triphosphate, indicating that they are primary transcripts. Minicircle transcription initiates at a purine within a conserved sequence, 5'-AYAYA-3', where Y is a pyrimidine, 32 bp from the upstream inverted repeat, suggesting that the repeats may function in transcript initiation. Transcripts from a single minicircle transcription unit range in size from 55 to 70 nucleotides. This size heterogeneity within a single sequence class is due to the variable length of nontemplated uridine residues composing a 3' tail. The size range and heterogeneous polyuridylate 3' end of the minicircle transcripts appear to be conserved features and may be related to transcript function.

Organization of minicircle genes for guide RNAs in Trypanosoma brucei

We have identified four T. brucei minicircle sequences that are complementary to cytochrome oxidase III (COIII) edited mRNA sequence and have shown the existence of transcripts from three of these minicircle sequences. These minicircle transcripts potentially serve as guide RNAs (gRNAs) for RNA editing of the COIII transcript. These gRNAs range in size from 55 to 70 nucleotides, are heterogeneous in sequence, and have a 5' terminal triphosphate. The genes for these gRNAs are flanked by imperfect 18 bp repeats separated by approximately 110 bp. Transcription initiates at the first purine within a conserved sequence, 5'-RYA-YA-3', 31 or 32 bp from the upstream inverted repeat. We propose that these 18 bp inverted repeats are important for minicircle gRNA expression in T. brucei.

Characterization of kinetoplast minicircle DNA in the lower trypanosomatid Crithidia oncopelti

The kinetoplast DNA of the lower trypanosomatid Crithidia oncopelti contains minicircles of four major size classes. Attempts to clone these molecules revealed the unclonability of the full-length minicircles in pUC and M13 vectors. A few clones were obtained using a lambda insertion vector lambda XIII. The nucleotide sequence of a cloned, apparently full-length minicircle has been determined and characterized. This 1848-bp molecule contains a single region corresponding to the 'conserved' minicircle region in other trypanosomatid species and an area with some features of the bent helix. About one-third of the molecule length is occupied by an extremely (T+G) versus (A+C) strand biased region. The role of this region, as well as the significance of the ORFs found and the putative secondary structures potentially formed by the minicircle sequence, remains unknown. The hybridization of kDNA with the different regions of a cloned minicircle shows that there are some segments of DNA specific to a particular class or a group of classes. Such a mode of sequence heterogeneity suggests that the possible functions (if any) of different minicircle classes may differ.

Replication of DNA minicircles in kinetoplasts isolated from Crithidia fasciculata: structure of nascent minicircles

We have previously described an isolated kinetoplast system from Crithidia fasciculata capable of ATP-dependent replication of kinetoplast DNA minicircles (L. Birkenmeyer and D.S. Ray, J. Biol. Chem. 261: 2362-2368, 1986). We present here the identification of two new minicircle species observed in short pulse-labeling experiments in this system. The earliest labeled minicircle species (component A) contains both nascent H and L strands and is heterogeneous in sedimentation and electrophoretic migration. Component A has characteristics consistent with a Cairns-type structure in which the L strand is the leading strand and the H strand is the lagging strand. The other new species (component B) has a nascent 2.5-kilobase linear L strand with a single discontinuity that mapped to either of two alternative origins located 180 degrees apart on the minicircle map. Component B could be repaired to a covalently closed form by Escherichia coli polymerase I and T4 ligase but not by T4 polymerase and T4 ligase. Even though component B has a single gap in one strand, it had an electrophoretic mobility on an agarose gel (minus ethidium bromide) similar to that of a supercoiled circle with three supertwists. Treatment of component B with topoisomerase II converted it to a form that comigrated with a nicked open circular form (replicative form II). These results indicate that component B is a knotted topoisomer of a kinetoplast DNA minicircle with a single gap in the L strand.

Replication of DNA minicircles in kinetoplasts isolated from Crithidia fasciculata: structure of nascent minicircles

We have previously described an isolated kinetoplast system from Crithidia fasciculata capable of ATP-dependent replication of kinetoplast DNA minicircles (L. Birkenmeyer and D.S. Ray, J. Biol. Chem. 261: 2362-2368, 1986). We present here the identification of two new minicircle species observed in short pulse-labeling experiments in this system. The earliest labeled minicircle species (component A) contains both nascent H and L strands and is heterogeneous in sedimentation and electrophoretic migration. Component A has characteristics consistent with a Cairns-type structure in which the L strand is the leading strand and the H strand is the lagging strand. The other new species (component B) has a nascent 2.5-kilobase linear L strand with a single discontinuity that mapped to either of two alternative origins located 180 degrees apart on the minicircle map. Component B could be repaired to a covalently closed form by Escherichia coli polymerase I and T4 ligase but not by T4 polymerase and T4 ligase. Even though component B has a single gap in one strand, it had an electrophoretic mobility on an agarose gel (minus ethidium bromide) similar to that of a supercoiled circle with three supertwists. Treatment of component B with topoisomerase II converted it to a form that comigrated with a nicked open circular form (replicative form II). These results indicate that component B is a knotted topoisomer of a kinetoplast DNA minicircle with a single gap in the L strand.

A knotted free minicircle in kinetoplast DNA

Kinetoplast DNA, the mitochondrial DNA of trypanosomes, is a network containing thousands of minicircles that are topologically interlocked. The minicircle replication intermediates are free molecules that have been released from the network. We report here that one form of free minicircles is a trefoil knot. Identification of this knotted structure is based on its electrophoretic and sedimentation properties, its response to treatments with restriction enzymes or topoisomerase II, and its appearance by electron microscopy. Except for its topology, the knotted minicircle closely resembles a previously described replication intermediate with a unique gap in the newly synthesized L strand.

Bent DNA structures associated with several origins of replication are recognized by a unique enzyme from trypanosomatids

Sequence-directed bending of the DNA double helix is a conformational variation found in both prokaryotic and eukaryotic organisms. The utilization of bent DNA structures from various sources as specific signals recognized by an enzyme is demonstrated here using a unique endonuclease purified from trypanosomatid cells. Crithidia fasciculata nicking enzyme was previously shown to recognize specifically the bent structure found in kinetoplast DNA minicircles. The binding constant measured for this specific interaction is of two orders of magnitude higher than that measured for the binding of the enzyme to a non-curved sequence. As determined by binding competition and mobility shift electrophoresis analyses, this enzyme recognizes the sequence-directed bends associated with the origins of replication of bacteriophage lambda and simian virus 40 (SV40), as well as that located within the autonomously replicating sequence (ARS1) region of the yeast S. cerevisiae.

Generation of sequence diversity in the kinetoplast DNA minicircles of Leishmania mexicana amazonensis

In order to understand the mechanisms which generate minicircle sequence diversity, we sequenced three minicircles belonging to the same or closely related sequence classes from the kinetoplast DNA of Leishmania mexicana amazonensis strains, PH8, Raimundo, and Josefa. Closely related minicircles from PH8 and Raimundo were unexpectedly found to differ at 11% of positions within the evolutionarily conserved region, but at only 3.9% of positions in the variable region. It thus appears that accumulation of point mutations will not account for the wide intra-strain and intra-subspecies divergence of the variable region. Comparison of more distantly related minicircles from PH8 and Josefa revealed only two short stretches of 70% homology within the variable region. These stretches of homology are not located in the same positions relative to the conserved regions in their respective minicircles. They may represent vestiges of recombinational events responsible for the rapid divergence of minicircle variable regions.

A site of intrinsic bending in a highly repeated element of Plasmodium berghei genome

The basic element of the 2.3 kb repetitive family, present in approximately 300 copies in the Plasmodium berghei genome, contains a bent DNA region. Indications of this given by anomalies in electrophoretic behaviour were confirmed by computational analysis of sequence data.

Sequence-directed bent DNA helix is the specific binding site for Crithidia fasciculata nicking enzyme

The sequence-directed bent structure of kinetoplast DNA minicircles specifies a unique binding site for Crithidia fasciculata nicking enzyme. Binding of the purified enzyme to the bent structure results in the formation of a tight enzyme-DNA complex that is highly specific to curved DNA. Recognition of the binding site is not determined by the nucleotide sequence at the site of binding per se but through the specific local variation in the DNA helix geometry. Both dynamic curved structures, which are generated by supercoiling, and static ones, which are sequenced-directed, could support and efficient enzyme-DNA complex formation. Binding interactions are dependent upon the degree of the helix curvature and decrease with the straightening of the binding site. DNase I protection experiments identify distinct domains of enzyme binding within the bent structure and suggest the induction of structural changes within these regions as a result of protein-DNA interactions.

Sequences of two kinetoplast minicircle DNAs of Trypanosoma (Nannomonas) congolense

Random minicircle DNA molecules were released from isolated kinetoplast network DNA of Trypanosoma congolense by BamHI digestion and cloned into plasmid pUC19. The sequences of two cloned minicircles (958 bp and 964 bp) were determined. Both minicircles contain the 13 bp sequence, 5'-GGGGTTGGTGTAA-3', thought to be the replication origin of minicircles in other trypanosomatids. The two minicircles have extensive homology in the 120 bp preceeding, and the 20 bp following, this 13-mer but only scattered homology elsewhere. Both possess tandem repeats downstream of the 13-mer. Comparison of these minicircles with minicircle sequences from other trypanosomatids reveals that they have the same general sequence organization as the others although only the 13-mer and its flanking regions are homologous.

Kinetoplast DNA minicircles: high-copy-number mitochondrial plasmids

The kinetoplast DNA of trypanosomes is a highly unusual network of catenated DNA circles of two kinds: maxicircles, the equivalent of conventional mitochondrial DNA, and minicircles, high-copy-number mitochondrial plasmids with no known function. Kinetoplast minicircles share many features with bacterial plasmids and represent a novel model system for the study of the mechanisms and regulation of DNA replication in eukaryotic organisms.

Kinetoplast DNA of Bodo caudatus: a noncatenated structure

The kinetoplast DNA (kDNA) of trypanosomes and other parasitic members of the order Kinetoplastida is organized as a complex network containing thousands of catenated circular DNA molecules. We found that the kDNA of a free-living kinetoplastida, Bodo caudatus, exists as a noncatenated structure. The kDNA of B. caudatus represents about 40% of the total cellular DNA, and the major components of this DNA are large circles of 10 and 12 kilobases (kb). Our results indicate that these circles are analogous to trypanosome kDNA minicircles despite their large size and noncatenated form. The kDNA of B. caudatus also contains a minor component of 19 kb which is transcribed. The 19-kb molecules are probably analogous to the maxicircles of trypanosomes. The properties of the B. caudatus kDNA suggest that the catenated network structure of trypanosome kDNA is not required for maxicircle segregation during kinetoplast division or for the expression of the maxicircle genome.

A quantitative measure of DNA curvature enabling the comparison of predicted structures

A growing body of data indicates that the equilibrium structures of some DNA fragments are curved and that curvature is sequence-directed. We describe a quantitative measure of DNA curvature that can be used for evaluating and comparing current proposed models for the molecular basis of DNA curvature. We demonstrate that this measure, in conjunction with any given prediction model, enables both the comparison of experimental data to predictions and the scanning of nucleotide sequence databases for potential curved regions.

Kinetoplast DNA of Bodo caudatus: a noncatenated structure

The kinetoplast DNA (kDNA) of trypanosomes and other parasitic members of the order Kinetoplastida is organized as a complex network containing thousands of catenated circular DNA molecules. We found that the kDNA of a free-living kinetoplastida, Bodo caudatus, exists as a noncatenated structure. The kDNA of B. caudatus represents about 40% of the total cellular DNA, and the major components of this DNA are large circles of 10 and 12 kilobases (kb). Our results indicate that these circles are analogous to trypanosome kDNA minicircles despite their large size and noncatenated form. The kDNA of B. caudatus also contains a minor component of 19 kb which is transcribed. The 19-kb molecules are probably analogous to the maxicircles of trypanosomes. The properties of the B. caudatus kDNA suggest that the catenated network structure of trypanosome kDNA is not required for maxicircle segregation during kinetoplast division or for the expression of the maxicircle genome.

Organized packaging of kinetoplast DNA networks

The kinetoplast DNA (kDNA) of Trypanosoma equiperdum is organized as a complex structure of catenated circular DNA molecules. The major component of the kDNA network is the one kilobase minicircle that is present at about 10,000 copies per network. We have developed two assays to examine the structure of kDNA networks compacted in vitro with spermidine. Our results suggest that minicircles are arranged into a regular structure with an exposed domain which is DNAase I- and restriction-sensitive and a protected domain which is resistant to restriction endonucleases and DNAase I. This regularly packaged structure is dependent upon spermidine compaction and the circularity of the kDNA, but does not require supercoiled minicircles or catenated networks.

kDNA minicircles of the major sequence class of C. fasciculata contain a single region of bent helix widely separated from the two origins of replication

The major sequence class of Crithidia fasciculata minicircles is shown to have a single region of bent helical DNA widely separated from the two replication origins located 180 degrees apart on the minicircle map. The position of the bend in the DNA has been mapped both by gel electrophoretic methods and by direct electron microscopic observation of the DNA. This sequence directed bending is apparently the result of homopolymeric dA X dT tracts 4-6 base pairs long repeated in phase with the helix screw. The region of the bend contains nineteen such homopolymeric tracts in a region of about 200 base pairs with sixteen of the tracts oriented in the same direction.

Visualization of the bent helix in kinetoplast DNA by electron microscopy

Kinetoplast DNA minicircles from the trypanosomatid Crithidia fasciculata contain a segment of approximately 200 bp which is probably more highly bent than any other DNA previously studied. Electron microscopy (EM) of relaxed minicircles (2.5 kb) revealed 200-300 bp loops within the larger circles, and the loops could also be detected on full-length linear molecules. Examination by EM of a 219 bp cloned fragment which contains the bent helix revealed that up to 70% of the molecules appeared circular whether or not the ends were cohesive. In contrast, a 207 bp fragment from pBR322 showed no circles and the fragments in general appeared much straighter than the kinetoplast fragments. Treatment of the 219 bp bent kinetoplast fragment with the drug distamycin caused a striking reduction in curvature.

DNA bending at adenine . thymine tracts

Intrinsic bending of DNA molecules results from local structural polymorphism in regions of homopolymeric dA . dT which are at least 4 base pairs long; the A . T tracts must be repeated in phase with the helix screw. Bending, in the direction of base-pair tilt rather than roll, occurs at the junctions between the A . T tract and adjacent B-DNA, with a larger angle at the 3' than at the 5' end of the A tract.

Conservation of kinetoplastid minicircle characteristics without nucleotide sequence conservation

The nucleotide sequence and restriction fragment electrophoretic mobility of four minicircles from the kinetoplast DNA of Trypanosoma brucei were determined. Each minicircle possesses an approximately 130 base pair conserved sequence which occurs in other African trypanosome minicircles and contains a 13 base pair sequence that is conserved among kinetoplastid genera [Kidane et al. (1984) Gene 27, 265-277]. A sequence located adjacent to the conserved sequence conserves purine versus pyrimidine strand bias, but not nucleotide sequence, and contains periodic oligo(dA) tracts. Minicircle fragments containing the conserved sequence and adjacent segment exhibited anomalous electrophoretic mobility in polyacrylamide gels. The position of the oligo(dA) tracts in the fragments appears to influence this anomalous mobility. The presence of conserved features independent of conserved nucleotide sequence and the lack of conserved open reading frames among these minicircles suggests that minicircles may have a function other than encoding protein.