Structural asymmetry and discrete nucleic acid subdomains in the Trypanosoma brucei kinetoplast

The mitochondrial genome of Trypanosoma brucei is contained in a specialized structure termed the kinetoplast. Kinetoplast DNA (kDNA) is organized into a concatenated network of mini and maxicircles, positioned at the base of the flagellum, to which it is physically attached. Here we have used electron microscope cytochemistry to determine structural and functional domains involved in replication and segregation of the kinetoplast. We identified two distinct subdomains within the kinetoflagellar zone (KFZ) and show that the unilateral filaments are composed of distinct inner and outer filaments. Ethanolic phosphotungstic acid (E-PTA) and EDTA regressive staining indicate that basic proteins and DNA are major constituents of the inner unilateral filaments adjoining the kDNA disc. This evidence for an intimate connection of the unilateral filaments in the KFZ with DNA provides support for models of minicircle replication involving vectorial export of free minicircles into the KFZ. Unexpectedly however, detection of DNA in the KFZ throughout the cell cycle suggests that other processes involving kDNA occur in this domain. We also describe a hitherto unrecognized, intramitochondrial, filamentous structure rich in basic proteins that links the kDNA discs during their segregation and is maintained between them for an extended period of the cell cycle.     

Expression and subcellular localization of kinetoplast-associated proteins in the different developmental stages of Trypanosoma cruzi

Background  

The kinetoplast DNA (kDNA) of trypanosomatids consists of an unusual arrangement of circular molecules catenated into a single network. The diameter of the isolated kDNA network is similar to that of the entire cell. However, within the kinetoplast matrix, the kDNA is highly condensed. Studies in Crithidia fasciculata showed that kinetoplast-associated proteins (KAPs) are capable of condensing the kDNA network. However, little is known about the KAPs of Trypanosoma cruzi, a parasitic protozoon that shows distinct patterns of kDNA condensation during their complex morphogenetic development. In epimastigotes and amastigotes (replicating forms) the kDNA fibers are tightly packed into a disk-shaped kinetoplast, whereas trypomastigotes (non-replicating) present a more relaxed kDNA organization contained within a rounded structure. It is still unclear how the compact kinetoplast disk of epimastigotes is converted into a globular structure in the infective trypomastigotes.     

The assembly of kinetoplast DNA

The unusual structure of the kinetoplast DNA (kDNA) of trypanosomatids requires unique replication mechanisms. Deciphering the mechanisms that regulate the network assembly has been a challenge for many years. A better understanding of these processes was facilitated by recent studies on the fine structure of resting and replicating kDNA networks. In this review, Joseph Shlomai discusses our current view of the structural and mechanistic aspects of the assembly of kinetoplast DNA.     

Nucleus-encoded histone H1-like proteins are associated with kinetoplast DNA in the trypanosomatid Crithidia fasciculata.

Kinetoplast DNA (kDNA), the mitochondrial DNA of trypanosomatids, consists of thousands of minicircles and 20 to 30 maxicircles catenated into a single large network and exists in the cell as a highly organized compact disc structure. To investigate the role of kinetoplast-associated proteins in organizing and condensing kDNA networks into this disc structure, we have cloned three genes encoding kinetoplast-associated proteins. The KAP2, KAP3, and KAP4 genes encode proteins p18, p17, and p16, respectively. These proteins are small basic proteins rich in lysine and alanine residues and contain 9-amino-acid cleavable presequences. Proteins p17 and p18 are closely related to each other, with 48% identical residues and carboxyl tails containing almost exclusively lysine, alanine, and serine or threonine residues. These proteins have been expressed as Met-His6-tagged recombinant proteins and purified by metal chelate chromatography. Each of the recombinant proteins is capable of compacting kDNA networks in vitro and was shown to bind preferentially to a specific fragment of minicircle DNA. Expression of each of these proteins in an Escherichia coli mutant lacking the HU protein rescued a defect in chromosome condensation and segregation in the mutant cells and restored a near-normal morphological appearance. Proteins p16, p17, and p18 have been localized within the cell by immunofluorescence methods and appear to be present throughout the kDNA. Electron-microscopic immunolocalization of p16 shows that p16 is present both within the kDNA disc and in the mitochondrial matrix at opposite edges of the kDNA disc. Our results suggest that nucleus-encoded H1-like proteins may be involved in the organization and segregation of kDNA networks in trypanosomatids.     

Molecular cloning of mtp70, a mitochondrial member of the hsp70 family.

We have isolated a gene from the protozoan parasite Trypanosoma cruzi that encodes a previously unidentified member of the 70-kilodalton heat shock protein (hsp70) family. Among all the eucaryotic hsp70 proteins described to date, this trypanosome protein, mtp70, is uniquely related in sequence and structure to the hsp70 of Escherichia coli, DnaK, which functions in the initiation of DNA replication. This relationship to DnaK is especially relevant in view of the intracellular location of the protein. Within the trypanosome, mtp70 is located in the mitochondrion, where it associates with kinetoplast DNA (kDNA), the unusual mitochondrial DNA that distinguishes this order of protozoa. Moreover, mtp70 is located in the specific region of the kinetoplast in which kDNA replication occurs. In view of the known functions of DnaK, the localization of mtp70 to the site of kDNA replication suggests that mtp70 may participate in eucaryotic mitochondrial DNA replication in a manner analogous to that of DnaK in E. coli.     

Polymorphic and differential expression of the Trypanosoma cruzi alleles containing universal minicircle binding protein

DNA replication mechanisms are poorly understood in most of trypanosomatids, in particular the replication of the peculiar mitochondrial DNA, the kinetoplast DNA (kDNA). To contribute to the knowledge on the mechanism of kDNA replication in Trypanosoma cruzi, we have previously characterized the Universal Minicircle Sequence Binding Protein of this parasite (TcUMSBP), which was first called PDZ5 [E.R. Coelho, T.P. Urmenyi, J. Franco da Silveira, E. Rondinelli, R. Silva, Identification of PDZ5, a candidate universal minicircle sequence binding protein of Trypanosoma cruzi, Int. J. Parasitol. 33 (2003) 853-858]. In this work, we describe two highly polymorphic alleles of the TcUMSBP locus in the T. cruzi reference clone CL Brener and the differential expression pattern of these alleles. A 62 bp sequence in the TcUMSBP upstream intergenic region in one of its alleles affects the efficiency of polycistronic RNA processing and the polyadenylation sites, and therefore regulates the differential expression of TcUMSBP alleles of this locus.     

Leishmania actin binds and nicks kDNA as well as inhibits decatenation activity of type II topoisomerase

Leishmania actin (LdACT) is an unconventional form of eukaryotic actin in that it markedly differs from other actins in terms of its filament forming as well as toxin and DNase-1-binding properties. Besides being present in the cytoplasm, cortical regions, flagellum and nucleus, it is also present in the kinetoplast where it appears to associate with the kinetoplast DNA (kDNA). However, nothing is known about its role in this organelle. Here, we show that LdACT is indeed associated with the kDNA disc in Leishmania kinetoplast, and under in vitro conditions, it specifically binds DNA primarily through electrostatic interactions involving its unique DNase-1-binding region and the DNA major groove. We further reveal that this protein exhibits DNA-nicking activity which requires its polymeric state as well as ATP hydrolysis and through this activity it converts catenated kDNA minicircles into open form. In addition, we show that LdACT specifically binds bacterial type II topoisomerase and inhibits its decatenation activity. Together, these results strongly indicate that LdACT could play a critical role in kDNA remodeling.     

The configuration of DNA replication sites within the Trypanosoma brucei kinetoplast

The kinetoplast is a concatenated network of circular DNA molecules found in the mitochondrion of many trypanosomes. This mass of DNA is replicated in a discrete "S" phase in the cell cycle. We have tracked the incorporation of the thymidine analogue 5-bromodeoxyuridine into newly replicated DNA by immunofluorescence and novel immunogold labeling procedures. This has allowed the detection of particular sites of replicated DNA in the replicating and segregating kinetoplast. These studies provide a new method for observing kinetoplast DNA (kDNA) replication patterns at high resolution. The techniques reveal that initially the pattern of replicated DNA is antipodal and can be detected both on isolated complexes and in replicating kDNA in vivo. In Trypanosoma brucei the opposing edges of replicating kDNA never extend around the complete circumference of the network, as seen in other kinetoplastids. Furthermore, crescent-shaped labeling patterns are formed which give way to labeling of most of the replicating kDNA except the characteristic midzone. The configuration of these sites of replicated DNA molecules is different to previous studies on organisms such as Crithidia fasciculata, suggesting differences in the timing of replication of mini and maxicircles and/or organization of the replicative apparatus in the kinetoplast of the African trypanosome.     

Detection and Classification of Trypanosoma cruzi by DNA Hybridization with Nonradioactive Probes

ABSTRACT. Total or kinetoplast DNA (kDNA) from 72 isolates and clones of Trypanosoma cruzi as well as from nine related trypanosomatids were analyzed by dot hybridization using nonradioactive kDNA or cloned minicircle fragments as probes. Biotinylated-kDNA probes generated by nick-translation proved reliable for distinguishing Zymodeme 1 and Zymodeme 2bol of T. cruzi parasites. In contrast, digoxigenin-labeled kDNA obtained by random-priming did not distinguish among T. cruzi isolates but did distinguish among New World leishmanias. Cloned minicircle fragments labeled with digoxigenin gave the same results as digoxigenin-labeled kDNA, except for a 10-fold decrease in sensitivity. Digoxigenin-labeled DNA probes proved useful in unambiguously detecting T. cruzi from different geographic regions of America. However, T. rangeli and T. cruzi marinkellei were not distinguished by these probes.     

Detection and classification of Trypanosoma cruzi by DNA hybridization with nonradioactive probes.

Total or kinetoplast DNA (kDNA) from 72 isolates and clones of Trypanosoma cruzi as well as from nine related trypanosomatids were analyzed by dot hybridization using nonradioactive kDNA or cloned minicircle fragments as probes. Biotinylated-kDNA probes generated by nick-translation proved reliable for distinguishing Zymodeme 1 and Zymodeme 2bol of T. cruzi parasites. In contrast, digoxigenin-labeled kDNA obtained by random-priming did not distinguish among T. cruzi isolates but did distinguish among New World leishmanias. Cloned minicircle fragments labeled with digoxigenin gave the same results as digoxigenin-labeled kDNA, except for a 10-fold decrease in sensitivity. Digoxigenin-labeled DNA probes proved useful in unambiguously detecting T. cruzi from different geographic regions of America. However, T. rangeli and T. cruzi marinkellei were not distinguished by these probes.     

Comparative study of kinetoplast DNA in culture, blood and intracellular forms of Trypanosoma cruzi.

A comparative study has been made on the kinetoplast DNA (kDNA) from I in culture epimastigote, blood trypomastigote and intracellular amastigote stages of Trypanosoma cruzi. The basic properties of the kDNA in all 3 forms were identical. Thus the DNA was in the form of networks of density 1.698-9 g/cm3 and with sedimentation coefficients (S20w) of approximately 5500, the networks being composed of large complexes of minicircular and apparently linear molecules, the former having contour lengths of 0.45 MICROMETer. Several differences were noted. The ultrastructural arrangement of the kDNA in the kinetoplast of the blood stage consisted of three to four double rows of DNA as compared to one double layered row in the other two stages. There was proportionately more kDNA in the blood stages, suggesting that, since the networks have apparently the same size (see above), more than one is present. DNA loops situated at the periphery of the kDNA networks were observed in higher proportion in blood and intracellular forms. Dimeric and oligomeric circles were present in the kDNA of the blood and intracellular stages in much greater proportion than in culture epimastigote stages. Few large circular molecules, heterogeneous in size, were also observed in intracellular blood stages. There were some differences, mainly quantitative, in the gel electrophoresis patterns after endonuclease digestion.     

A Passion for Parasites

I knew nothing and had thought nothing about parasites until 1971. In fact, if you had asked me before then, I might have commented that parasites were rather disgusting. I had been at the Johns Hopkins School of Medicine for three years, and I was on the lookout for a new project. In 1971, I came across a paper in the Journal of Molecular Biology by Larry Simpson, a classmate of mine in graduate school. Larry''s paper described a remarkable DNA structure known as kinetoplast DNA (kDNA), isolated from a parasite. kDNA, the mitochondrial genome of trypanosomatids, is a DNA network composed of several thousand interlocked DNA rings. Almost nothing was known about it. I was looking for a project on DNA replication, and I wanted it to be both challenging and important. I had no doubt that working with kDNA would be a challenge, as I would be exploring uncharted territory. I was also sure that the project would be important when I learned that parasites with kDNA threaten huge populations in underdeveloped tropical countries. Looking again at Larry''s paper, I found the electron micrographs of the kDNA networks to be rather beautiful. I decided to take a chance on kDNA. Little did I know then that I would devote the next forty years of my life to studying kDNA replication.     

TAC102 Is a Novel Component of the Mitochondrial Genome Segregation Machinery in Trypanosomes

Trypanosomes show an intriguing organization of their mitochondrial DNA into a catenated network, the kinetoplast DNA (kDNA). While more than 30 proteins involved in kDNA replication have been described, only few components of kDNA segregation machinery are currently known. Electron microscopy studies identified a high-order structure, the tripartite attachment complex (TAC), linking the basal body of the flagellum via the mitochondrial membranes to the kDNA. Here we describe TAC102, a novel core component of the TAC, which is essential for proper kDNA segregation during cell division. Loss of TAC102 leads to mitochondrial genome missegregation but has no impact on proper organelle biogenesis and segregation. The protein is present throughout the cell cycle and is assembled into the newly developing TAC only after the pro-basal body has matured indicating a hierarchy in the assembly process. Furthermore, we provide evidence that the TAC is replicated de novo rather than using a semi-conservative mechanism. Lastly, we demonstrate that TAC102 lacks an N-terminal mitochondrial targeting sequence and requires sequences in the C-terminal part of the protein for its proper localization.     

Characterization of Kinetoplast DNA from Phytomonas serpens

ABSTRACT. The restriction enzyme digestion of kinetoplast DNA from four Phytomonas serpens isolates shows an overall similar band pattern. One minicircle from isolate 30T was cloned and sequenced, showing low levels of homology but the same general features and organization as described for minicircles of other trypanosomatids. Extensive regions of the minicircle are composed by G and T on the H strand. These regions are very repetitive and similar to regions in a minicircle of Crithidia oncopelti and to telomeric sequences of Saccharomyces cerevisiae. Conserved Sequence Block 3, present in all trypanosomatids, is one nucleotide different from the consensus in P. serpens and provides a basis to differentiate P. serpens from other trypanosomatids. Electron microscopy of kinetoplast DNA evidenced a network with organization similar to other trypanosomatids and the measurement of minicircles confirmed the size of about 1.45 kb of the sequenced minicircle.     

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.     

Fellowship of the rings: the replication of kinetoplast DNA

Kinetoplastid protozoa such as trypanosomes and Leishmania are important because they cause human disease. These parasites are named after one of their most unusual features, a mitochondrial DNA known as kinetoplast DNA (kDNA). Unlike all other DNA in nature, kDNA comprises a giant network of interlocked DNA rings with a topology resembling that of medieval chain mail. The replication of the kDNA network is more complex than previously thought, and the discovery of new proteins involved in this process is currently the best approach for illuminating the replication mechanism.     

Characterization of Phytomonas isolated from fruits by electrophoretic isoenzymes and kinetoplast-DNA analysis

Abstract Two flagellates of the family trypanosomatidae were isolated from the fruits of Lycopersicon esculentum (tomato) and Annona cherimolia (cherimoya) in the southeastern region of Spain. The isolates were characterized by isoenzyme analysis using nine different isoenzymes and by analysis of kinetoplast DNA (kDNA) restriction fragment length polymorphism using four different restriction endonucleases. Most of the isoenzymes were unable to distinguish between the two fruit isolates, while they were all able to distinguish these two from four other Phytomonas isolates, three of which were from laticiferous plants i.e. Euphorbia characias E. hirta and E. hyssopifolia , and one was a phloem-restricted isolate associated with Hartrot disease. Only the enzyme Superoxide dismutase was able to differentiate between the two fruit isolates. Electrophoretic and restriction endonuclease analysis of kDNA minicircles, using four restriction enzymes, showed similar if not identical restriction cleavage patterns of the minicircles of the two isolates from fruits, while the patterns were different for the other isolates. These results confirm the hypothesis that the two isolates from fruits constitute a group of trypanosomatids that are the same or closely related and that this group can parasitize more than one host plant.