Synthesis and processing of kinetoplast DNA minicircles in Trypanosoma equiperdum.

Kinetoplast DNA, the mitochondrial DNA in trypanosomes, is a giant network containing topologically interlocked minicircles. Replication occurs on free minicircles that have been detached from the network. In this paper, we report studies on the synthesis and processing of the minicircle L and H strands. Analysis of free minicircles from Trypanosoma equiperdum by two-dimensional agarose gel electrophoresis indicated that elongating L strands are present on theta structures. Hybridization studies indicated that L-strand elongation is continuous and unidirectional, starting near nucleotide 805 and proceeding around the entire minicircle. The theta structures segregate into monomeric progeny minicircles, and those with a newly synthesized L strand have a 8-nucleotide gap between nucleotides 805 and 814 (J. M. Ntambi, T. A. Shapiro, K. A. Ryan, and P. T. Englund, J. Biol. Chem. 261:11890-11895, 1986). These molecules are reattached to the network, where repair of the gap takes place. Of the molecules labeled during a 10-min pulse with [3H]thymidine, gap filling occurred on half within about 15 min and on virtually all by 60 min; however, there was no detectable covalent closure of the newly synthesized L strand by 60 min.     

Ribonucleotides associated with a gap in newly replicated kinetoplast DNA minicircles from Trypanosoma equiperdum

In Trypanosoma equiperdum, some newly replicated kinetoplast DNA minicircles contain a single gap at a unique location in their newly synthesized strand (Ntambi, J. M., and Englund, P. T. (1985) J. Biol. Chem. 260, 5574-5579). We now report that ribonucleotides are associated with this gap, with one or two covalently attached to the 5' terminus of the newly synthesized strand. There appear to be two possible RNA/DNA junctions at adjacent positions in the sequence. The ribonucleotides may be remnants of a replication primer, and their presence strongly implies that the gap is at the site of a replication origin.     

Effects of RNA interference of Trypanosoma brucei structure-specific endonuclease-I on kinetoplast DNA replication

Kinetoplast DNA, the mitochondrial DNA of trypanosomatid protozoa, is a network containing several thousand topologically interlocked DNA minicircles. Kinetoplast DNA synthesis involves release of minicircles from the network, replication of the free minicircles, and reattachment of the progeny back onto the network. One enzyme involved in this process is structure-specific endonuclease-I. This enzyme, originally purified from Crithidia fasciculata, has been proposed to remove minicircle replication primers (Engel, M. L., and Ray, D. S. (1998) Nucleic Acids Res. 26, 4773-4778). We have studied the structure-specific endonuclease-I homolog from Trypanosoma brucei, showing it to be localized in the antipodal sites flanking the kinetoplast DNA disk, as previously shown in C. fasciculata. RNA interference of structure-specific endonuclease-I caused persistence of a single ribonucleotide at the 5' end of both the leading strand and at least the first Okazaki fragment in network minicircles, demonstrating that this enzyme in fact functions in primer removal. Probably because of the persistence of primers, RNA interference also impeded the reattachment of newly replicated free minicircles to the network and caused a delay in kinetoplast DNA segregation. These effects ultimately led to shrinkage and loss of the kinetoplast DNA network and cessation of growth of the cell.     

Changes in network topology during the replication of kinetoplast DNA.

Kinetoplast DNA of Crithidia fasciculata is a network containing several thousand topologically interlocked DNA minicircles. In the prereplicative Form I network, each of the 5000 minicircles is intact and linked to an average of three neighbors (i.e. the minicircle valence is 3). Replication involves the release of minicircles from the interior of the network, the synthesis of nicked or gapped progeny minicircles and the attachment of the progeny to the network periphery. The ultimate result is a Form II network of 10,000 nicked or gapped minicircles. Our measurements of minicircle valence and density, and the network's surface area, revealed striking changes in network topology during replication. During the S phase, the peripheral newly replicated minicircles have a density twice that of minicircles in Form I networks, which suggests that the valence might be as high as 6. Most of the holes in the central region that occur from the removal of intact minicircles are repaired so that the central density and valence remain the same, as in prereplicative networks. When minicircle replication is complete at the end of the S phase, the isolated network has the surface area of a prereplicative network, despite having twice the number of minicircles. During the G2 phase, the Form II network undergoes a remodeling in which the area doubles and the valence is reduced to 3. Finally, the interruptions in the minicircles are repaired and the double-sized network splits in two.     

The structure of replicating kinetoplast DNA networks

Kinetoplast DNA (kDNA), the mitochondrial DNA of Crithidia fasciculata and related trypanosomatids, is a network containing approximately 5,000 covalently closed minicircles which are topologically interlocked. kDNA synthesis involves release of covalently closed minicircles from the network, and, after replication of the free minicircles, reattachment of the nicked or gapped progeny minicircles to the network periphery. We have investigated this process by electron microscopy of networks at different stages of replication. The distribution of nicked and closed minicircles is easily detectable either by autoradiography of networks radiolabeled at endogenous nicks by nick translation or by twisting the covalently closed minicircles with intercalating dye. The location of newly synthesized minicircles within the network is determined by autoradiography of network is determined by autoradiography of networks labeled in vivo with a pulse of [3H]thymidine. These studies have clarified structural changes in the network during replication, the timing of repair of nicked minicircles after replication, and the mechanism of division of the network.     

Structural characterization of site-specific discontinuities associated with replication origins of minicircle DNA from Crithidia fasciculata

The kinetoplast DNA of trypanosomes is comprised of thousands of DNA minicircles and 20-50 maxicircles catenated into a single network. Replication intermediates of minicircle DNA from the trypanosomatid species Crithidia fasciculata contain site-specific discontinuities in both heavy (H) and light (L) strands. These discontinuities map to two small regions situated 180 degrees apart on the minicircle; each region has two sites at which a discontinuity can occur, one on each strand. We have determined the position of these discontinuities on the minicircle DNA sequence and have characterized their structure. H-strand discontinuities occur within a 4-5-nucleotide sequence and consist of single nicks, only one of which appears to be a DNA-DNA junction. Characterization of the remaining H-strand nicks indicates a structure other than a typical DNA-DNA or DNA-RNA junction. Discontinuities on the L-strand can be either a nick or a short gap which overlaps a 12-nucleotide sequence universally conserved among minicircles from various trypanosome species. Up to 6 nucleotides are hydrolyzed from the 5' terminus facing the gap upon treatment with alkali, suggesting the presence of an RNA primer. Based on the structures of minicircle replication intermediates, we present a model for replication of minicircle DNA in which the site-specific discontinuities closely coincide with the origins of replication.     

Specific cleavage of kinetoplast minicircle DNA from Leishmania tarentolae by mung bean nuclease and identification of several additional minicircle sequence classes

Multiple sequence classes of kinetoplast minicircle DNA from Leishmania tarentolae were cleaved by mung bean nuclease in the presence of formamide, yielding unit length linear molecules which retained the anomalous electrophoretic mobility in acrylamide characteristic of minicircle DNA. No specific cleavage site sequence common to all minicircle sequence classes was apparent, although the main region of nuclease cleavage was localized approximately 350 bp from the unique SmaI restriction site of the conserved region found in all minicircle sequence classes. Covalent closure of the minicircle substrate was not a requirement for cleavage, as linearized network-derived or cloned minicircles were also cleaved by mung bean nuclease at similar locations. The partial sequences of several new minicircle sequence classes released from the network by mung bean nuclease are also reported.     

Replication of kinetoplast DNA in Trypanosoma equiperdum. Minicircle H strand fragments which map at specific locations

The mitochondrial DNA of trypanosomes, kinetoplast DNA, is a network containing thousands of topologically interlocked minicircles. Minicircles are replicated as free molecules after being detached from the network. The minicircle L strand appears to be synthesized continuously and the H strand discontinuously. This paper describes properties of Trypanosoma equiperdum minicircle H strand fragments which could be Okazaki fragments. These fragments constitute a family of molecules of discrete sizes (ranging from about 70 to 1000 nucleotides) which map to specific locations. Three of the most prominent fragments, a 73-mer, 83-mer, and 138-mer, map at contiguous or overlapping sites. Based on their position relative to the initiation site for L strand synthesis, the 73-mer may be the first Okazaki fragment to be synthesized and either the 83-mer or the 138-mer may be the second. The 5' end of the 73-mer lies within a sequence, GGGCGT, found at a similar location in minicircles of all trypanosomatid species. During the maturation of free minicircles and after their reattachment to the networks there appears to be continued extension and ligation of the H strand fragments. However, the ligation of the 73-mer, 83-mer, and 138-mer to the rest of the H strand is delayed; their eventual ligation results in covalent closure of the minicircles.     

Replication of kinetoplast DNA in isolated kinetoplasts from Crithidia fasciculata. Identification of minicircle DNA replication intermediates

The kinetoplast DNA (kDNA) of trypanosomes is comprised of thousands of DNA minicircles and 20-50 maxicircles catenated into a single network. We show that kinetoplasts isolated from the trypanosomatid species Crithidia fasciculata incorporate labeled nucleotides and support minicircle DNA replication in a manner which mimics two characteristics of minicircle replication in vivo: 1) the minicircles are replicated as free molecules and subsequently reattached to the kDNA network, and 2) a replication intermediate having a structure consistent with a highly gapped minicircle species is generated. In addition, a class of minicircle DNA replication intermediates is observed containing discontinuities at specific sites within each of the newly synthesized DNA strands. By using a strain of C. fasciculata possessing nearly homogenous minicircles, we were able to map the discontinuities to two small regions situated 180 degrees apart on the minicircle. Each region has two sites at which a discontinuity can occur, one on each strand and separated by approximately 100 base pairs. These sites may represent origins of minicircle DNA replication.     

Intramitochondrial localization of universal minicircle sequence-binding protein, a trypanosomatid protein that binds kinetoplast minicircle replication origins

Kinetoplast DNA (kDNA), the mitochondrial DNA of the trypanosomatid Crithidia fasciculata, is a unique structure containing 5,000 DNA minicircles topologically linked into a massive network. In vivo, the network is condensed into a disk-shaped structure. Replication of minicircles initiates at unique origins that are bound by universal minicircle sequence (UMS)-binding protein (UMSBP), a sequence-specific DNA-binding protein. This protein, encoded by a nuclear gene, localizes within the cell's single mitochondrion. Using immunofluorescence, we found that UMSBP localizes exclusively to two neighboring sites adjacent to the face of the kDNA disk nearest the cell's flagellum. This site is distinct from the two antipodal positions at the perimeter of the disk that is occupied by DNA polymerase beta, topoisomerase II, and a structure-specific endonuclease. Although we found constant steady-state levels of UMSBP mRNA and protein and a constant rate of UMSBP synthesis throughout the cell cycle, immunofluorescence indicated that UMSBP localization within the kinetoplast is not static. The intramitochondrial localization of UMSBP and other kDNA replication enzymes significantly clarifies our understanding of the process of kDNA replication.     

Free minicircles of kinetoplast DNA in Crithidia fasciculata.

The major form of kinetoplast DNA in Crithidia fasciculata is a network which contains thousands of minicircles linked together in a two-dimensional array. This paper reports the existence of free minicircles in Crithidia which by several criteria are identical to those in networks. They are the same size (about 2500 base pairs), and they yield the same products upon digestion with restriction enzymes. About 0.4% of the minicircles in exponentially growing nonsynchronized cells are free and the remainder are in networks. After a 5-min pulse with [3H]thymidine, above 10% of all of the incorporated radioactivity in the cell is in free minicircles, and the minicircles have a higher specific radioactivity than the average of other DNAs in the cell. Three-branched structures, which resemble Cairns-type replication intermediates, are occasionally observed by electron microscopy. Kinetic studies of the incorporation of [3H]thymidine into free minicircles indicate that they turn over, and this turnover was confirmed by a pulse-chase experiment. These properties of free minicircles suggest that they may be intermediates in the replication of network minicircles.     

Selection for arsenite resistance causes reversible changes in minicircle composition and kinetoplast organization in Leishmania mexicana.

Certain minor minicircle sequence classes in the kinetoplast DNA (kDNA) networks of arsenite- or tunicamycin-resistant Leishmania mexicana amazonensis variants whose nuclear DNA is amplified appear to be preferentially selected to replicate (S. T. Lee, C. Tarn, and K. P. Chang, Mol. Biochem. Parasitol. 58:187-204, 1993). These sequences replace the predominant wild-type minicircle sequences to become dominant species in the kDNA network. The switch from wild-type-specific to variant-specific minicircles takes place rapidly within the same network, the period of minicircle dominance changes being defined as the transition period. To investigate the structural organization of the kDNA networks during this transition period, we analyzed kDNA from whole arsenite-resistant Leishmania parasites by dot hybridization with sequence-specific DNA probes and by electron-microscopic examination of isolated kDNA networks in vitro. Both analyses concluded that during the switch of dominance the predominant wild-type minicircle class was rapidly lost and that selective replication of variant-specific minicircles subsequently filled the network step by step. There was a time during the transition when few wild-type- or variant-specific minicircles were present, leaving the network almost empty and exposing a species of thick, long, fibrous DNA which seemed to form a skeleton for the network. Both minicircles and maxicircles were found to attach to these long DNA fibrils. The nature of the long DNA fibrils is not clear, but they may be important in providing a framework for the network structure and a support for the replication of minicircles and maxicircles.     

Mitochondrial DNA ligases of Trypanosoma brucei

The mitochondrial DNA of Trypanosoma brucei, termed kinetoplast DNA or kDNA, consists of thousands of minicircles and a small number of maxicircles catenated into a single network organized as a nucleoprotein disk at the base of the flagellum. Minicircles are replicated free of the network but still contain nicks and gaps after rejoining to the network. Covalent closure of remaining discontinuities in newly replicated minicircles after their rejoining to the network is delayed until all minicircles have been replicated. The DNA ligase involved in this terminal step in minicircle replication has not been identified. A search of kinetoplastid genome databases has identified two putative DNA ligase genes in tandem. These genes (LIG k alpha and LIG k beta) are highly diverged from mitochondrial and nuclear DNA ligase genes of higher eukaryotes. Expression of epitope-tagged versions of these genes shows that both LIG k alpha and LIG k beta are mitochondrial DNA ligases. Epitope-tagged LIG k alpha localizes throughout the kDNA, whereas LIG k beta shows an antipodal localization close to, but not overlapping, that of topoisomerase II, suggesting that these proteins may be contained in distinct structures or protein complexes. Knockdown of the LIG k alpha mRNA by RNA interference led to a cessation of the release of minicircles from the network and resulted in a reduction in size of the kDNA networks and rapid loss of the kDNA from the cell. Closely related pairs of mitochondrial DNA ligase genes were also identified in Leishmania major and Crithidia fasciculata.     

Role of p38 in replication of Trypanosoma brucei kinetoplast DNA

Trypanosomes have an unusual mitochondrial genome, called kinetoplast DNA, that is a giant network containing thousands of interlocked minicircles. During kinetoplast DNA synthesis, minicircles are released from the network for replication as theta-structures, and then the free minicircle progeny reattach to the network. We report that a mitochondrial protein, which we term p38, functions in kinetoplast DNA replication. RNA interference (RNAi) of p38 resulted in loss of kinetoplast DNA and accumulation of a novel free minicircle species named fraction S. Fraction S minicircles are so underwound that on isolation they become highly negatively supertwisted and develop a region of Z-DNA. p38 binds to minicircle sequences within the replication origin. We conclude that cells with RNAi-induced loss of p38 cannot initiate minicircle replication, although they can extensively unwind free minicircles.     

Conserved sequence blocks in kinetoplast minicircles from diverse species of trypanosomes.

Kinetoplast DNA minicircles from various species of trypanosomes are heterogeneous in nucleotide sequence to various degrees but in all instances contain a conserved sequence region of 100 to 200 base pairs present in one, two, or four copies per minicircle. Comparison of the conserved sequence regions of minicircles from eight species of trypanosomes revealed a common sequence motif consisting of three conserved sequence blocks (CSBs) present in the same order and with similar spacing in all species. In addition to the invariant 12-base-pair universal minicircle sequence (CSB-3), a 10-base-pair sequence (CSB-1) and an 8-base-pair sequence (CSB-2) are highly conserved in all minicircles. The overlap of CSB-1 and CSB-3 with previously identified 5' termini of newly synthesized minicircle H and L strands, respectively, and the presence of this conserved sequence motif in minicircles from diverse species suggest that these CSBs may determine a common mechanism of minicircle replication.     

Characterization of the molecular components in kinetoplast- mitochondrial DNA of Trypanosoma equiperdum. Comparative study of the dyskinetoplastic and wild strains

The structure of the kinetoplast DNA of Trypanosoma equiperdum has been studied and compared to the structure of the circular mitochondrial DNA extracted from a dyskinetoplastic strain of T. equiperdum. In T. equiperdum wild type, the kinetoplast DNA constitutes approximately 6% of the total cellular DNA and is composed of approximately 3,000 supercoiled minicircles of 6.4 x 10(5) daltons and approximately 50 circular supercoiled molecules of 15.4 x 10(6) daltons topologically interlocked; The buoyant density in CsCl of the minicircles is 1.691 g/cm 3. The large circles have a buoyant density of 1.684 g/cm 3, are homogeneous in size and are selectively cleaved by several restriction endonucleases which do not cleave the minicircles. The cleavage sites of six different restriction endonucleases have been mapped on the large circle. The minicircles are cleaved by two other restriction endonucleases, and their cleavage sites have been mapped. The mitochondrial DNA extracted from the dyskinetoplastic strain of T. equiperdum represents 7% of the total DNA of the cell and is composed of supercoiled circles, heterogeneous in size, and topologically associated in catenated oligomers. Its buoyant density in CsCl is 1.688 g/cm 3. These molecules are not cleaved by any of the eight restriction endonucleases tested. The reassociation kinetics of in vitro labeled kDNA minicircles and large circles has been studied. The results indicate that the minicircles as well as the large circles are homogeneous in sequence and that the circular DNA of the dyskinetoplastic strain has no sequence in common with the kDNA of the wild strain.     

Kinetoplast DNA of Trypanosoma brucei: Physical map of the maxicircle

Trypanosoma brucei maxicircle DNA in kinetoplast DNA (kDNA) networks was characterized with restriction endonucleases. The data allow the construction of a circular map of a 22.2-kb molecule. Based on these and previous data each T. brucei kDNA network contains about 45 maxicircles which probably have the same sequence. The maxicircle of strain 164 used in this study was slightly larger and had three EcoRI sites compared to two found in other strains. Fragments generated by digestion with BamHI were largely singly cleaved maxicircles that had a density of 1.681 g/cm³ compared to 1.693 g/cm³ for the intact network. This suggests that maxicircles have a higher A + T content than minicircles. Minicircles in the kDNA network were also characterized with restriction endonucleases. Each enzyme cleaved a specific subset of minicircles from the network. However, no single restriction endonuclease or combination of up to three of these enzymes cleaved all molecules in the network. These results are consistent with earlier results of renaturation kinetic experiments and indicate that there are many different sequence classes of mini-circle DNA.     

Pankinetoplast DNA structure in a primitive bodonid flagellate, Cryptobia helicis.

The mitochondrial DNA (mtDNA) of a primitive kinetoplastid flagellate Cryptobia helicis is composed of 4.2 kb minicircles and 43 kb maxicircles. 85% and 6% of the minicircles are in the form of supercoiled (SC) and relaxed (OC) monomers, respectively. The remaining minicircles (9%) constitute catenated oligomers composed of both the SC and OC molecules. Minicircles contain bent helix and sequences homologous to the minicircle conserved sequence blocks. Maxicircles encode typical mitochondrial genes and are not catenated. The mtDNA, which we describe with the term 'pankinetoplast DNA', is spread throughout the mitochondrial lumen, where it is associated with multiple electron-lucent loci. There are approximately 8400 minicircles per pankinetoplast-mitochondrion, with the pan-kDNA representing approximately 36% of the total cellular DNA. Based on the similarity of the C.helicis minicircles to plasmids, we present a theory on the formation of the kDNA network.     

The rotational dynamics of kinetoplast DNA replication

Kinetoplast DNA (kDNA), from trypanosomatid mitochondria, is a network containing several thousand catenated minicircles that is condensed into a disk-shaped structure in vivo. kDNA synthesis involves release of individual minicircles from the network, replication of the free minicircles and reattachment of progeny at two sites on the network periphery approximately 180 degrees apart. In Crithidia fasciculata, rotation of the kDNA disk relative to the antipodal attachment sites results in distribution of progeny minicircles in a ring around the network periphery. In contrast, Trypanosoma brucei progeny minicircles accumulate on opposite ends of the kDNA disk, a pattern that did not suggest kinetoplast motion. Thus, there seemed to be two distinct replication mechanisms. Based on fluorescence microscopy of the kDNA network undergoing replication, we now report that the T. brucei kinetoplast does move relative to the antipodal sites. Whereas the C. fasciculata kinetoplast rotates, that from T. brucei oscillates. Kinetoplast motion of either type must facilitate orderly replication of this incredibly complex structure.