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.     

Expression, purification and characterization of recombinant mitochondrial topoisomerase II of kinetoplastid Crithidia fasciculata in High-five insect cells

Topoisomerase II of kinetoplastid parasites plays an important role in the replication of unusual networks of kinetoplast DNA (kDNA) and is a very useful target for antiparasitic drugs. In this study, we cloned full-length Crithidia fasciculata mitochondrial topoisomerase II gene into pFastBac-HTc vector and successfully expressed an active recombinant full-length mitochondrial topoisomerase II in Bac-to-Bac baculovirus expression system. A rapid and simple purification strategy was established by incorporating a FLAG-tag at the C-terminus of the protein. The purified recombinant topoisomerase II showed a major single band on SDS-PAGE (>96% purity) and was verified through Western blot analysis. The recombinant full-length mitochondrial topoisomerase II exhibited decatenation, catenation and relaxation activity of type II topoisomerase as well as various sensitivities to a series of known topoisomerase inhibitors. These studies explore new way and lay groundwork to express all other similar full-length kinetoplastid topoisomerases, it will also facilitate further elucidation of X-ray structure, catalysis mechanism of kinetoplastid topoisomerases and design of new antiparasitic drugs targeting kinetoplastid topoisomerases.     

Topoisomerases in kinetoplastids

Topoisomerases are enzymes that mediate topological changes in DNA that are essential for nucleic acid biosynthesis and for cell survival. The kinetoplastid protozoa, which include pathogenic trypanosomes and Leishmania, have yielded an interesting variety of purified topoisomerase activities as well as several topoisomerase genes. In these parasites, topoisomerases are involved in the metabolism of both nuclear and mitochondrial (kinetoplast) DNA. In this review, Christian Burri, Armette Bodley and Theresa Shapiro summarize what is known about topoisomerases in kinetoplastids, and consider the intriguing possibility that these enzymes may act as valuable antiparasite drug targets.     

A mitochondrial topoisomerase IA essential for late theta structure resolution in African trypanosomes

Trypanosomes and Leishmania, protozoans that cause major human diseases, have a topologically intricate mitochondrial DNA (kinetoplast or kDNA) in the form of a network of thousands of interlocked circles. This unusual system provides a useful reporter for studying topoisomerase functions in vivo. We now find that these organisms have three type IA topoisomerases, one of which is phylogenetically distinctive and which we designate topoisomerase IA(mt). In Trypanosoma brucei topoisomerase IA(mt) immunolocalizes within the mitochondrion close to the kDNA disk in patterns that vary with the cell cycle. When expression of TOPIA(mt) is silenced by RNAi there is a striking accumulation of kDNA late theta structure replication intermediates, with subsequent loss of kDNA networks and halt in cell growth. This essential enzyme provides clear molecular evidence for the obligatory role of a type IA enzyme in the resolution of late theta structures in vivo. With no close orthologue in humans it also offers a target for the rational development of selectively toxic new antiprotozoal therapies.     

Localization of a type II DNA topoisomerase to two sites at the periphery of the kinetoplast DNA of Crithidia fasciculata

A type II DNA topoisomerase (topollmt), purified to near homogeneity from the trypanosomatid C. fasciculata has been shown to be localized to the single mitochondrion of these kinetoplastid protozoa. Immunoblots show at least a 10-fold higher level of topollmt (per milligram of protein) in preparations of partially purified mitochondria as compared with those from whole cells. Analyses of type I and type II topoisomerase activities in both mitochondrial and whole cell extracts show a 4- to 5-fold higher specific activity of topollmt in mitochondrial extracts while a nuclear type I topoisomerase has a 4- to 5-fold lower specific activity in the same extract. Immunolocalizations using anti-topollmt antibodies show the enzyme to be present in close association with the mitochondrial DNA networks (kinetoplast DNA or kDNA). This association appears at two distinct locations on opposite sides of the kDNA network.     

A new function of Trypanosoma brucei mitochondrial topoisomerase II is to maintain kinetoplast DNA network topology

The mitochondrial genome of Trypanosoma brucei, called kinetoplast DNA, is a network of topologically interlocked DNA rings including several thousand minicircles and a few dozen maxicircles. Kinetoplast DNA synthesis involves release of minicircles from the network, replication of the free minicircles and reattachment of the progeny. Here we report a new function of the mitochondrial topoisomerase II (TbTOP2mt). Although traditionally thought to reattach minicircle progeny to the network, here we show that it also mends holes in the network created by minicircle release. Network holes are not observed in wild‐type cells, implying that this mending reaction is normally efficient. However, RNAi of TbTOP2mt causes holes to persist and enlarge, leading to network fragmentation. Remarkably, these network fragments remain associated within the mitochondrion, and many appear to be appropriately packed at the local level, even as the overall kinetoplast organization is dramatically altered. The deficiency in mending holes is temporally the earliest observable defect in the complex TbTOP2mt RNAi phenotype.     

Thirteen-exon-motif signature for vertebrate nuclear and mitochondrial type IB topoisomerases

DNA topoisomerases contribute to various cellular activities that involve DNA. We previously identified a human nuclear gene that encodes a mitochondrial DNA topoisomerase. Here we show that genes for mitochondrial DNA topoisomerases (type IB) exist only in vertebrates. A 13-exon topoisomerase motif was identified as a characteristic of genes for both nuclear and mitochondrial type IB topoisomerases. The presence of this signature motif is thus an indicator of the coexistence of nuclear and mitochondrial type IB DNA topoisomerases. We hypothesize that the prototype topoisomerase IB with the 13-exon structure formed first, and then duplicated. One topoisomerase specialized for nuclear DNA and the other for mitochondrial DNA.     

Natural and induced dyskinetoplastic trypanosomatids: how to live without mitochondrial DNA

Salivarian trypanosomes are the causative agents of several diseases of major social and economic impact. The most infamous parasites of this group are the African subspecies of the Trypanosoma brucei group, which cause sleeping sickness in humans and nagana in cattle. In terms of geographical distribution, however, Trypanosoma equiperdum and Trypanosoma evansi have been far more successful, causing disease in livestock in Africa, Asia, and South America. In these latter forms the mitochondrial DNA network, the kinetoplast, is altered or even completely lost. These natural dyskinetoplastic forms can be mimicked in bloodstream form T. brucei by inducing the loss of kinetoplast DNA (kDNA) with intercalating dyes. Dyskinetoplastic T. brucei are incapable of completing their usual developmental cycle in the insect vector, due to their inability to perform oxidative phosphorylation. Nevertheless, they are usually as virulent for their mammalian hosts as parasites with intact kDNA, thus questioning the therapeutic value of attempts to target mitochondrial gene expression with specific drugs. Recent experiments, however, have challenged this view. This review summarises the data available on dyskinetoplasty in trypanosomes and revisits the roles the mitochondrion and its genome play during the life cycle of T. brucei.     

Topoisomerases of kinetoplastid parasites: why so fascinating?

DNA topoisomerases are the key enzymes involved in carrying out high precision DNA transactions inside the cells. However, they are detrimental to the cell when a wide variety of topoisomerase-targeted drugs generate cytotoxic lesions by trapping the enzymes in covalent complexes on the DNA. The discovery of unusual heterodimeric topoisomerase I in kinetoplastid family added a new twist in topoisomerase research related to evolution, functional conservation and their preferential sensitivity to Camptothecin. On the other hand, structural and mechanistic studies on kinetoplastid topoisomerase II delineate some distinguishing features that differentiate the parasitic enzyme from its prokaryotic and eukaryotic counterparts. This review summarizes the recent advances in research in kinetoplastid topoisomerases, their evolutionary significance and the death of the unicellular parasite Leishmania donovani induced by topoisomerase I inhibitor camptothecin.     

Stem-loop silencing reveals that a third mitochondrial DNA polymerase, POLID, is required for kinetoplast DNA replication in trypanosomes

Kinetoplast DNA (kDNA), the mitochondrial genome of trypanosomes, is a catenated network containing thousands of minicircles and tens of maxicircles. The topological complexity dictates some unusual features including a topoisomerase-mediated release-and-reattachment mechanism for minicircle replication and at least six mitochondrial DNA polymerases (Pols) for kDNA transactions. Previously, we identified four family A DNA Pols from Trypanosoma brucei with similarity to bacterial DNA Pol I and demonstrated that two (POLIB and POLIC) were essential for maintaining the kDNA network, while POLIA was not. Here, we used RNA interference to investigate the function of POLID in procyclic T. brucei. Stem-loop silencing of POLID resulted in growth arrest and the progressive loss of the kDNA network. Additional defects in kDNA replication included a rapid decline in minicircle and maxicircle abundance and a transient accumulation of minicircle replication intermediates before loss of the kDNA network. These results demonstrate that POLID is a third essential DNA Pol required for kDNA replication. While other eukaryotes utilize a single DNA Pol (Pol gamma) for replication of mitochondrial DNA, T. brucei requires at least three to maintain the complex kDNA network.     

Molecular Comparison of the Mitochondrial and Cytoplasmic hsp 70 of Trypanosoma cruzi, Trypanosoma brucei and Leishmania major

ABSTRACT. We compared the expression and localization of the mitochondrial and cytoplasmic hsp70 of the protozoans Trypanosoma cruzi, Trypanosoma brucei and Leishmania major. The mitochondrial protein is encoded by multiple mRNA in all species, while the cytoplasmic protein is encoded by a single mRNA. In all three species, the mitochondrial hsp70 is concentrated in the kinetoplast, a submitochondrial structure that houses the unusual DNA (kDNA) that characterizes this group of organisms, while the cytoplasmic protein is distributed throughout the cell. These results suggest that, in all kinetoplastid species, mt-hsp70 has a specific function in kDNA biology, possibly in the processes of kDNA replication, RNA editing or kinetoplast structure.     

Dual Functions of α-Ketoglutarate Dehydrogenase E2 in the Krebs Cycle and Mitochondrial DNA Inheritance in Trypanosoma brucei

The dihydrolipoyl succinyltransferase (E2) of the multisubunit α-ketoglutarate dehydrogenase complex (α-KD) is an essential Krebs cycle enzyme commonly found in the matrices of mitochondria. African trypanosomes developmentally regulate mitochondrial carbohydrate metabolism and lack a functional Krebs cycle in the bloodstream of mammals. We found that despite the absence of a functional α-KD, bloodstream form (BF) trypanosomes express α-KDE2, which localized to the mitochondrial matrix and inner membrane. Furthermore, α-KDE2 fractionated with the mitochondrial genome, the kinetoplast DNA (kDNA), in a complex with the flagellum. A role for α-KDE2 in kDNA maintenance was revealed in α-KDE2 RNA interference (RNAi) knockdowns. Following RNAi induction, bloodstream trypanosomes showed pronounced growth reduction and often failed to equally distribute kDNA to daughter cells, resulting in accumulation of cells devoid of kDNA (dyskinetoplastic) or containing two kinetoplasts. Dyskinetoplastic trypanosomes lacked mitochondrial membrane potential and contained mitochondria of substantially reduced volume. These results indicate that α-KDE2 is bifunctional, both as a metabolic enzyme and as a mitochondrial inheritance factor necessary for the distribution of kDNA networks to daughter cells at cytokinesis.     

RNA interference of a trypanosome topoisomerase II causes progressive loss of mitochondrial DNA

We studied the function of a Trypanosoma brucei topoisomerase II using RNA interference (RNAi). Expression of a topoisomerase II double-stranded RNA as a stem-loop caused specific degradation of mRNA followed by loss of protein. After 6 days of RNAi, the parasites' growth rate declined and the cells subsequently died. The most striking phenotype upon induction of RNAi was the loss of kinetoplast DNA (kDNA), the cell's catenated mitochondrial DNA network. The loss of kDNA was preceded by gradual shrinkage of the network and accumulation of gapped free minicircle replication intermediates. These facts, together with the localization of the enzyme in two antipodal sites flanking the kDNA, show that a function of this topoisomerase II is to attach free minicircles to the network periphery following their replication.     

Molecular characterization of type II topoisomerase in the endosymbiont-bearing Trypanosomatid Blastocrithidia culicis

DNA topoisomerases are involved in DNA metabolism. These enzymes are inhibited by antimicrobial and antitumoral agents and might be important targets in the chemotherapy of diseases caused by parasites. We have cloned and characterized the gene encoding topoisomerase II from the monoxenic trypanosomatid Blastocrithidia culicis (BcTOP2). The BcTOP2 gene has a 3693 nucleotide-long open reading frame that encodes a 138 kDa polypeptide. The B. culicis topoisomerase II (BctopoII) amino-acid sequence shares high similarity (>74%) with topoisomerases from other trypanosomatids, and shares a lower similarity (41%) with other eukaryotic topoisomerases II from yeast to humans. BcTOP2 is a single copy gene and encodes a 4.4 kb mRNA. Western blotting of B. culicis extracts using the antiserum raised against a C-terminal portion of BctopoII showed a 138 kDa polypeptide. Immunolocalization assays showed that the antiserum recognized the nuclear topoisomerase II.     

Mitoxantrone resistance in HL-60 leukemia cells: reduced nuclear topoisomerase II catalytic activity and drug-induced DNA cleavage in association with reduced expression of the topoisomerase II beta isoform.

Mitoxantrone-resistant variants of the human HL-60 leukemia cell line are cross-resistant to several natural product and synthetic antineoplastic agents. The resistant cells (HL-60/MX2) retain sensitivity to the Vinca alkaloids vincristine and vinblastine, drugs that are typically associated with the classical multidrug resistance phenotype. Mitoxantrone accumulation and retention are equivalent in the sensitive and resistant cell types, suggesting that mitoxantrone resistance in HL-60/MX2 cells might be associated with an alteration in the type II DNA topoisomerases. We discovered that topoisomerase II catalytic activity in 1.0 M NaCl nuclear extracts from the HL-60/MX2 variant, as measured by the decatenation of Crithidia fasciculata kinetoplast DNA, was reduced 4- to 5-fold compared to that in the parental HL-60 cells. Total cellular topoisomerase II activity in HL-60/MX2 cells was only 50% lower than that in HL-60 cells, however, because the "cytosolic fraction" of the HL-60/MX2 nuclear preparation contained high levels of decatenating activity. Antisera to calf thymus topoisomerase II defined a distinctive immunoreactive pattern of topoisomerase II proteins in crude nuclear extracts from the HL-60/MX2 cells. Both alpha (170 kDa) and beta (180 kDa) forms of topoisomerase II were detected in the HL-60 cell extracts, but only the alpha form was detected in extracts from HL-60/MX2 cells. This finding was associated with the appearance of a new 160-kDa immunoreactive species in nuclear extracts from HL-60/MX2 but not HL-60 cells. Studies were designed to minimize the proteolytic degradation of the topoisomerase II enzymes by extraction of whole cells with hot SDS.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative analysis of mitochondrial and nuclear DNA topoisomerase I from maize

We conducted a comparative study of the properties of topoisomerase I isolated from maize nuclei and mitochondria. We found that nuclear and mitochondrial enzymes possess different ability to bind single stranded DNA. Study of the enzyme activity dependence on Mg2+ demonstrated an absolute dependence of the mitochondrial topoisomerase activity. Contrary, nuclear enzyme activity was not absolutely dependent but stimulated by the magnesium cation. Mitochondrial topoisomerase formed covalent bond with the 5'-end of the cleaved DNA what is unique property of prokaryotic topoisomerase I. Nuclear enzyme bound covalently to the 3'-end like all eukaryotic topoisomerases I. The search through databases revealed genes which could encode mitochondrial topoisomerase I in the genomes of higher plants. Using both cDNA sequencing and in silico methods we demonstrated an existence of the ortholog gene in the maize genome. This gene shares significant homology with prokaryotic topoisomerase I genes that may explain differences in the properties of the mitochondrial and nuclear enzyme. Data obtained is of a significant interest both from the point of view of plant organelle evolution and mitochondrial genome expression mechanisms study.