In vitro Transcription of Kinetoplast and Nuclear DNA in Kinetoplastida*†

SYNOPSIS. DNA-dependent RNA polymerases have been solubilized from homogenates of Crithidia fasciculata using gentle extraction procedures. RNA polymerase I and II are separated on DEAE cellulose at 0.07M (NH₄)₂SO₄ and 0.13M (NH₄)₂SO₄ respectively. RNA polymerase II is inhibited 80% by α-amanitin (25 μg/ml). Both RNA polymerases require DNA as a template, ribonucleoside triphosphates and Mn²⁺. The synthesis of RNA as a product is inhibited by DNase. RNase, pronase and actinomycin D. Purified kinetoplast and nuclear DNA can serve as templates for the RNA polymerases. Denatured DNA templates are preferred. The synthesis of RNA continues for at least an hour and is inhibited by trypanocidal drugs including suramin. antrycide, acriflavine, ethidium bromide and berenil. Complementary RNA synthesized in vitro from C. fasciculata kinetoplast DNA hybridizes with C. fasciculata kinetoplast DNA but not with C. fasciculata nuclear DNA or Blastocrithidia culicis kinetoplast DNA, Escherichia coli, T4 or calf thymus DNAs. The complementary RNA synthesized in vitro from C.fasciculata kinetoplast DNA sediments at 4–5S.     

DNA-dependent RNA-polymerase activity of isolated kinetoplasts of crithidia oncopelti]

DNA-dependent RNA-polymerase activity was found in the kinetoplasts of Crithidia oncopelti. Kinetic patterns of 14C-UTP incorporation into the acid-insoluble fraction of isolated kinetoplasts at 25 degrees, 30 degrees and 35 degrees C were estimated. The effects of different antibiotics and intercalating agents on RNA synthesis in kinetoplasts were studied. alpha-amanitin, a specific inhibitor of the nuclear enzyme, does not affect the RNA-polymerase activity of the kinetoplasts. Streptolidigin and rifampicin, inhibitors of bacterial RNA-polymerase, have little effect on RNA synthesis in the kinetoplasts even at high concentrations. Kinetoplasts preincubation in the phosphate buffer increases the permeability of their membranes for rifampicin. Intercalating agents, acriflavin and ethidium bromide, strongly inhibit the kinetoplast RNA synthesis. Similar specific effects of some antibiotics and intercalating agents on RNA synthesis in kinetoplasts and typical mitochondria may be indicative of similarity of functional properties of RNA-polymerases in those organelles.     

Differentiation, Multiplication and Control of Bloodstream Form Trypanosoma (Duttonella) vivax in Mice

.The growth and differentiation of Trypanosoma vivax was studied in intact and irradiated C3H/He and C57B1/6 mice. In irradiated (800 R) or intact C3H/He and irradiated (800 R) C57B1/6 mice, T. vivax parasitaemia increased rapidly then entered a plateau phase and thereafter declined in an antibody-independent remission phase. Throughout the infection, variations were observed in parasite morphology, density, DNA content, number of organisms with 2 nuclei and 2 kinetoplasts and infectivity of parasites for mice. Parasites in exponential phase had the highest number of members in the S, G₂ and M phases of the cell cycle as determined by staining with the interchalating dye Chromomycin A, and analysis on a flow cytometer. During this phase there were numerous parasites with 2 nuclei and 2 kinetoplasts and infectivity was high for mice. As the parasitaemia approached and entered the plateau phase, the proportion of organisms in the S, G₂ and M phases of the cell cycle as well as the number of those with 2 kinetoplasts decreased slightly; the number of organisms with 2 nuclei decreased rapidly; and parasites had a considerably reduced capacity to infect mice. Organisms from the remission phase contained only 1 nucleus and 1 kinetoplast and were not infective for mice. The study suggests that T. vivax organisms transit from dividing to committed non-dividing forms and that some non-dividing, non-infective T. vivax organisms remain trapped in the S, G₂ and M stages of the cell cycle and die without completing binary fission. In contrast to the above, parasite wave remission occurred in T.vivax-infected intact C57B1/6 mice during exponential growth when there were large numbers of dividing form organisms present in the bloodstream as determined by both DNA content and the proportion of parasites with 2 kinetoplasts and 2 nuclei. Clearance of T. vivax from the bloodstream of infected intact C57B1/6 mice coincided with the production of a parasite-specific antibody response. The studies are discussed with reference to the mode of induction of host protective antibody responses to exponentially growing T. vivax.     

In situ hybridization to the Crithidia fasciculata kinetoplast reveals two antipodal sites involved in kinetoplast DNA replication.

Kinetoplast DNA is a network of interlocked minicircles and maxicircles. In situ hybridization, using probes detected by digital fluorescence microscopy, has clarified the in vivo structure and replication mechanism of the network. The probe recognizes only nicked minicircles. Hybridization reveals prereplication kinetoplasts (with closed minicircles), donut-shaped replicating kinetoplasts (with nicked minicircles on the periphery and closed minicircles in the center), and postreplication kinetoplasts (with nicked minicircles). Replicating kinetoplasts are associated with two peripheral structures containing free minicircle replication intermediates and DNA polymerase. Replication may involve release of closed minicircles from the center of the kinetoplast and their migration to the peripheral structures, replication of the free minicircles therein, and then peripheral reattachment of the progeny minicircles to the kinetoplast.     

Effects of Ethidium Bromide and Several Acridine Dyes on the Kinetoplast DNA of Leishmania tropica*†

Whole cell DNA from Leishmania tropica has 2 peaks when banded by CsCl equilibrium density centrifugation. The main band has a buoyant density of 1.721 and the satellite band a buoyant density of 1.705, with Clostridium perfringens DNA (ρ= 1.6915) used as a reference. The satellite band has been identified as the kinetoplast DNA by purifying DNA from isolated kinetoplasts. L. tropica has the highest G + C content of both nuclear and kinetoplastic DNA thus far reported for trypanosomatids. The effects of ethidium bromide, acriflavin, proflavin, and 5-aminoacridine on the kinetoplast of L. tropica have been compared. Ethidium bromide and acriflavin, but not proflavin or 5-aminoacridine, induce dyskinetoplasty. L. tropica is one of the most sensitive trypanosomatids to ethidium bromide and acriflavin. Examination of the DNA from drug-treated cells in CsCl gradients revealed a loss of the satellite band after ethidium bromide or acriflavin treatment, but not after proflavin or 5-aminoacridine treatment. Cell division was required to produce these effects on the kinetoplast.     

The involvement of two cdc2-related kinases (CRKs) in Trypanosoma brucei cell cycle regulation and the distinctive stage-specific phenotypes caused by CRK3 depletion

Cyclin-dependent protein kinases are among the key regulators of eukaryotic cell cycle progression. Potential functions of the five cdc2-related kinases (CRK) in Trypanosoma brucei were analyzed using the RNA interference (RNA(i)) technique. In both the procyclic and bloodstream forms of T. brucei, CRK1 is apparently involved in controlling the G(1)/S transition, whereas CRK3 plays an important role in catalyzing cells across the G(2)/M junction. A knockdown of CRK1 caused accumulation of cells in the G(1) phase without apparent phenotypic change, whereas depletion of CRK3 enriched cells of both forms in the G(2)/M phase. However, two distinctive phenotypes were observed between the CRK3-deficient procyclic and bloodstream forms. The procyclic form has a majority of the cells containing a single enlarged nucleus plus one kinetoplast. There is also an enhanced population of anucleated cells, each containing a single kinetoplast known as the zoids (0N1K). The CRK3-depleted bloodstream form has an increased number of one nucleus-two kinetoplast cells (1N2K) and a small population containing aggregated multiple nuclei and multiple kinetoplasts. Apparently, these two forms have different mechanisms in cell cycle regulation. Although the procyclic form can be driven into cytokinesis and cell division by kinetoplast segregation without a completed mitosis, the bloodstream form cannot enter cytokinesis under the same condition. Instead, it keeps going through another G(1) phase and enters a new S phase resulting in an aggregate of multiple nuclei and multiple kinetoplasts in an undivided cell. The different leakiness in cell cycle regulation between two stage-specific forms of an organism provides an interesting and useful model for further understanding the evolution of cell cycle control among the eukaryotes.     

Occurrence of a kinetoplast DNA-protein complex in Trypanosoma cruzi

The kinetoplast DNA has been purified in high yield from $\text{Trypanosoma cruzi}$ by centrifugation on 3 M CsCl after lysis with a detergent. In exponentially growing trypanosomes, a light component causing a density shift of the kinetoplast DNA in CsCl density gradients is observed. This component is presumably a protein since it is removed by digestion with proteolytic enzymes. The DNA-protein complex is resistant to phenol extraction and 4 M guanidinium chloride, which indicates the possibility of a covalent bond between the protein and the DNA. The Kinetoplast DNA isolated from trypanosomes at the stationary phase by centrifugation on 3 M CsCl is free of proteins.     

Kinetoplast DNA replication: mechanistic differences between Trypanosoma brucei and Crithidia fasciculata

Kinetoplast DNA, the mitochondrial DNA of trypanosomatid parasites, is a network containing several thousand minicircles and a few dozen maxicircles. We compared kinetoplast DNA replication in Trypanosoma brucei and Crithidia fasciculata using fluorescence in situ hybridization and electron microscopy of isolated networks. One difference is in the location of maxicircles in situ. In C. fasciculata, maxicircles are concentrated in discrete foci embedded in the kinetoplast disk; during replication the foci increase in number but remain scattered throughout the disk. In contrast, T. brucei maxicircles generally fill the entire disk. Unlike those in C. fasciculata, T. brucei maxicircles become highly concentrated in the central region of the kinetoplast after replication; then during segregation they redistribute throughout the daughter kinetoplasts. T. brucei and C. fasciculata also differ in the pattern of attachment of newly synthesized minicircles to the network. In C. fasciculata it was known that minicircles are attached at two antipodal sites but subsequently are found uniformly distributed around the network periphery, possibly due to a relative movement of the kinetoplast disk and two protein complexes responsible for minicircle synthesis and attachment. In T. brucei, minicircles appear to be attached at two antipodal sites but then remain concentrated in these two regions. Therefore, the relative movement of the kinetoplast and the two protein complexes may not occur in T. brucei.     

Microtubule polarity and dynamics in the control of organelle positioning,segregation, and cytokinesis in the trypanosome cell cycle

Trypanosoma brucei has a precisely ordered microtubule cytoskeleton whose morphogenesis is central to cell cycle events such as organelle positioning, segregation, mitosis, and cytokinesis. We have defined microtubule polarity and show the + ends of the cortical microtubules to be at the posterior end of the cell. Measurements of organelle positions through the cell cycle reveal a high degree of coordinate movement and a relationship with overall cell extension. Quantitative analysis of the segregation of the replicated mitochondrial genome (the kinetoplast) by the flagellar basal bodies identifies a new G2 cell cycle event marker. The subsequent mitosis then positions one "daughter" nucleus into the gap between the segregated basal bodies/kinetoplasts. The anterior daughter nucleus maintains its position relative to the anterior of the cell, suggesting an effective yet cryptic nuclear positioning mechanism. Inhibition of microtubule dynamics by rhizoxin results in a phenomenon whereby cells, which have segregated their kinetoplasts yet are compromised in mitosis, cleave into a nucleated portion and a flagellated, anucleate, cytoplast. We term these cytoplasts "zoids" and show that they contain the posterior (new) flagellum and associated basal-body/kinetoplast complex. Examination of zoids suggests a role for the flagellum attachment zone (FAZ) in defining the position for the axis of cleavage in trypanosomes. Progression through cytokinesis, (zoid formation) while mitosis is compromised, suggests that the dependency relationships leading to the classical cell cycle check points may be altered in trypanosomes, to take account of the need to segregate two unit genomes (nuclear and mitochondrial) in this cell.     

Differentiation, multiplication and control of bloodstream form Trypanosoma (Duttonella) vivax in mice

The growth and differentiation of Trypanosoma vivax was studied in intact and irradiated C3H/He and C57Bl/6 mice. In irradiated (800 R) or intact C3H/He and irradiated (800 R) C57Bl/6 mice, T. vivax parasitaemia increased rapidly then entered a plateau phase and thereafter declined in an antibody-independent remission phase. Throughout the infection, variations were observed in parasite morphology, density, DNA content, number of organisms with 2 nuclei and 2 kinetoplasts and infectivity of parasites for mice. Parasites in exponential phase had the highest number of members in the S, G2 and M phases of the cell cycle as determined by staining with the interchalating dye Chromomycin A3 and analysis on a flow cytometer. During this phase there were numerous parasites with 2 nuclei and 2 kinetoplasts and infectivity was high for mice. As the parasitaemia approached and entered the plateau phase, the proportion of organisms in the S, G2 and M phases of the cell cycle as well as the number of those with 2 kinetoplasts decreased slightly; the number of organisms with 2 nuclei decreased rapidly; and parasites had a considerably reduced capacity to infect mice. Organisms from the remission phase contained only 1 nucleus and 1 kinetoplast and were not infective for mice. The study suggests that T. vivax organisms transit from dividing to committed non-dividing forms and that some non-diving, non-infective T. vivax organisms remain trapped in the S, G2 and M stages of the cell cycle and die without completing binary fission.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytochemical study of free-living flagellates of suborder Bodonina. I. Morphology and nucleic acids]

Nucleic acids (DNA and RNA) have been discovered in the kinetoplast of free-living Bodonina: Bodo caudatus, Pleuromonas jaculans, Rhynchomonas nasuta--by means of cytochemical methods. The kinetoplast has variable contents of nucleic acids whose chemoarchitectonics is due to their non-homogeneous distribution within the kinetoplast. The Feulgen reaction in the kinetoplast is more intensive than in the nucleus. Kinetoplast is closely connected with the cytoplasmic RNA metabolism. Many individuals of R. nasuta were found to have two kinetoplasts, no other signs of cell division being observed. P. jaculans has up to 45% of dyskinetoplastic forms.     

Role of Centrins 2 and 3 in Organelle Segregation and Cytokinesis in Trypanosoma brucei

Centrins are calcium binding proteins involved in cell division in eukaryotes. Previously, we have shown that depletion of centrin1 in Trypanosoma brucei (T. brucei) displayed arrested organelle segregation resulting in loss of cytokinesis. In this study we analyzed the role of T. brucei centrin2 (TbCen2) and T. brucei 3 (TbCen3) in the early events of T. brucei procyclic cell cycle. Both the immunofluorescence assay and electron microscopy showed that TbCen2 and 3-deficient cells were enlarged in size with duplicated basal bodies, multinuclei and new flagella that are detached along the length of the cell body. In both TbCen2 and TbCen3 depleted cells segregation of the organelles i.e. basal bodies, kinetoplast and nucleus was disrupted. Further analysis of the cells with defective organelle segregation identified three different sub configurations of organelle mis-segregations (Type 1–3). In addition, in majority of the TbCen2 depleted cells and in nearly half of the TbCen3 depleted cells, the kinetoplasts were enlarged and undivided. The abnormal segregations ultimately led to aborted cytokinesis and hence affected growth in these cells. Therefore, both centrin2 and 3 are involved in organelle segregation similar to centrin1 as was previously observed. In addition, we identified their role in kinetoplast division which may be also linked to overall mis-segregation.     

Centrin1 is required for organelle segregation and cytokinesis in Trypanosoma brucei

Centrin is a calcium-binding centrosome/basal body-associated protein involved in duplication and segregation of these organelles in eukaryotes. We had shown that disruption of one of the centrin genes (centrin1) in Leishmania amastigotes resulted in failure of both basal body duplication and cytokinesis. Here, we undertook to define the role of centrin1 (TbCen1) in the duplication and segregation of basal body and its associated organelles kinetoplast and Golgi, as well as its role in cytokinesis of the procyclic form of Trypanosoma brucei by depleting its protein using RNA inhibition methodology. TbCen1-depleted cells showed significant reduction in growth compared with control cells. Morphological analysis of these cells showed they were large and pleomorphic with multiple detached flagella. Both immunofluorescence assays using organelle-specific antibodies and electron microscopic analysis showed that TbCen1-deficient cells contained multiple basal bodies, kinetoplasts, Golgi, and nuclei. These multiple organelles were, however, closely clustered together, indicating duplication without segregation in the absence of centrin. This failure in organelle segregation may be the likely cause of inhibition of cytokinesis, suggesting for the first time a new and unique role for centrin in the segregation of organelles without affecting their multiplication in the procyclic form of T. brucei.     

Electron Microscopic Observations of the Bloodstream Form of Cryptobia salmositica Katz, 1951 (Kinetoplastida: Bodonina)1

The ultrastructure of the bloodstream form of Cryptobia salmositica in rainbow trout was examined during the acute phase of experimental infection. The arrangement of the major groupings of cytoplasmic microtubules originating near the basal bodies is similar to that in other bodonids. The cytostome is reinforced both by pellicular microtubules and an electron-dense plaque. Certain microtubules associated with the flagellar pocket serve as nucleating sites for pellicular microtubules. A flagellar rootlet, consisting of two parallel fibers which are bound together intermittently by electron-dense plaques, curves posteriorly from the basal body of the recurrent flagellum towards the kinetoplast. The basal body associated plaque on the kinetoplast membranes is duplicated at the same time as the basal bodies. Cytoplasmic microtubules are found in association with the plaque and the outer kinetoplastic membrane. A pulsatile vacuole, described for the first time in a hemoparasitic cryptobiid, lies adjacent to the post-flagellar pit. Smaller, interconnected vesicles of the spongiome are continuous with the pulsatile vacuole. Since a pulsatile vacuole occurs not only in free-living and ectoparasitic cryptobiids but in the hemoparasitic (=trypanoplasm) forms as well, this is no longer a character by which the genus Trypanoplasma may be separated from the genus Cryptobia. Possession of this osmoregulatory complex may allow the organism to survive outside of a host and fulfill a monoxenous life cycle, in addition to the usual heteroxenous cycle involving a leech as vector.     

Effect of acriflavin on the kinetoplast of Leishmania tarentolae. Mode of action and physiological correlates of the loss of kinetoplast DNA

The loss of kinetoplast DNA in Leishmania tarentolae, which occurs in the presence of low concentrations of acriflavin, was found to be a result of selective inhibition of replication of this DNA. Nuclear DNA synthesis was relatively unaffected and cell and kinetoplast division proceeded normally for several generations. An approximately equal distribution of parental kinetoplast DNA between daughter kinetoplasts resulted in a decrease in the average amount of DNA per kinetoplast. The final disappearance of the stainable kinetoplast DNA occurred at a cell division in which all the remaining visible kinetoplast DNA was retained by one of the daughter cells. The selective inhibition of kinetoplast DNA synthesis was caused by a selective localization of acriflavin in the kinetoplast. The apparent intracellular localization of dye and the extent of uptake at a low dye concentration could be manipulated, respectively, by varying the hemin (or protoporphyrin IX) concentration in the medium and by adding red blood cell extract (or hemoglobin). Hemin and protoporphyrin IX were found to form a complex with acriflavin. During growth in acriflavin, cells exhibited an increasing impairment of colony-forming ability and rate of respiration. No change in the electrophoretic pattern of total cell soluble proteins was apparent. The data fit the working hypothesis that the loss of kinetoplast DNA leads to a respiratory defect which then leads to a decrease in biosynthetic reactions and eventual cell death. A possible use of the selective localization of acriflavin in the kinetoplast to photooxidize selectively the kinetoplast DNA is suggested.     

Pairwise knockdowns of cdc2-related kinases (CRKs) in Trypanosoma brucei identified the CRKs for G1/S and G2/M transitions and demonstrated distinctive cytokinetic regulations between two developmental stages of the organism

Expression of the cdc2-related kinase 3 (CRK3) together with expression of CRK1, -2, -4, or -6, were knocked down in pairs in the procyclic and bloodstream forms of Trypanosoma brucei, using the RNA interference technique. Double knockdowns of CRK3 and CRK2, CRK4, or CRK6 exerted significant growth inhibition and enriched the cells in G2/M phase, whereas a CRK3 plus CRK1 (CRK3 + CRK1) knockdown arrested cells in both G1/S and G2/M transitions. Thus, CRK1 and CRK3 are apparently the kinases regulating the G1/S and G2/M checkpoint passages, respectively, whereas the other CRKs are probably playing only minor roles in cell cycle regulation. A CRK1 + CRK2 knockdown in the procyclic form was found to cause aberrant posterior cytoskeletal morphogenesis (X. M. Tu and C. C. Wang, Mol. Biol. Cell 16:97-105, 2005). A CRK3 + CRK2 knockdown, however, did not lead to such a change, suggesting that CRK2 depletion can lead to the abnormal morphogenesis only when procyclic-form cells are arrested in the G1 phase. The G2/M-arrested procyclic form produces up to 20% stumpy anucleated cells (zoids) in the population, suggesting that cytokinesis and cell division are not blocked by mitotic arrest but are apparently driven to completion by the kinetoplast cycle. In the bloodstream form, however, G2/M arrest resulted in little zoid formation but, instead, enriched a population of cells each containing multiple kinetoplasts, basal bodies, and flagella and an aggregate of multiple nuclei, indicating failure in entering cytokinesis. The two different cytokinetic regulations between two distinct stage-specific forms of the same organism may provide an interesting and useful model for further understanding the evolution of cytokinetic control among eukaryotes.     

PNT1 Is a C11 Cysteine Peptidase Essential for Replication of the Trypanosome Kinetoplast

The structure of a C11 peptidase PmC11 from the gut bacterium, Parabacteroides merdae, has recently been determined, enabling the identification and characterization of a C11 orthologue, PNT1, in the parasitic protozoon Trypanosoma brucei. A phylogenetic analysis identified PmC11 orthologues in bacteria, archaea, Chromerids, Coccidia, and Kinetoplastida, the latter being the most divergent. A primary sequence alignment of PNT1 with clostripain and PmC11 revealed the position of the characteristic His-Cys catalytic dyad (His⁹⁹ and Cys¹³⁶), and an Asp (Asp¹³⁴) in the potential S₁ binding site. Immunofluorescence and cryoelectron microscopy revealed that PNT1 localizes to the kinetoplast, an organelle containing the mitochondrial genome of the parasite (kDNA), with an accumulation of the protein at or near the antipodal sites. Depletion of PNT1 by RNAi in the T. brucei bloodstream form was lethal both in in vitro culture and in vivo in mice and the induced population accumulated cells lacking a kinetoplast. In contrast, overexpression of PNT1 led to cells having mislocated kinetoplasts. RNAi depletion of PNT1 in a kDNA independent cell line resulted in kinetoplast loss but was viable, indicating that PNT1 is required exclusively for kinetoplast maintenance. Expression of a recoded wild-type PNT1 allele, but not of an active site mutant restored parasite viability after induction in vitro and in vivo confirming that the peptidase activity of PNT1 is essential for parasite survival. These data provide evidence that PNT1 is a cysteine peptidase that is required exclusively for maintenance of the trypanosome kinetoplast.