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J. Biol. Chem., Vol. 279, Issue 24, 25703-25710, June 11, 2004

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Centrin Gene Disruption Impairs Stage-specific Basal Body Duplication and Cell Cycle Progression in Leishmania^*

Angamuthu Selvapandiyan, Alain Debrabant, Robert Duncan, Jacqueline Muller, Poonam Salotra¶, Gannavaram Sreenivas¶, Jeffrey L. Salisbury||, and Hira L. Nakhasi**

From the Laboratory of Bacterial, Parasitic and Unconventional Agents, Division of Emerging and Transfusion Transmitted Diseases, Office of Blood Research and Review and the Laboratory of Vector Borne Diseases, Division of Viral Products, Office of Vaccines Research and Review, Center for Biologics Evaluation and Research, Food and Drug Administration, Bethesda, Maryland 20892, the ^¶Institute of Pathology (Indian Council of Medical Research), Safdarjung Hospital, New Delhi 110 029, India, and the ^||Tumor Biology Program, Mayo Clinic College of Medicine, Rochester, Minnesota 55905

Received for publication, March 11, 2004

	ABSTRACT

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Centrin is a calcium-binding cytoskeletal protein involved in the duplication of centrosomes in higher eukaryotes. To explore the role of centrin in the protozoan parasite Leishmania, we created Leishmania deficient in the centrin gene (LdCEN). Remarkably, centrin null mutants (LdCEN^-/-) showed selective growth arrest as axenic amastigotes but not as promastigotes. Flow cytometry analysis confirmed that the mutant axenic amastigotes have a cell cycle arrest at the G₂/M stage. The axenic amastigotes also showed failure of basal body duplication and failure of cytokinesis resulting in multinucleated "large" cells. Increased terminal deoxy uridine triphosphate nick end labeling positivity was observed in centrin mutant axenic amastigotes compared with wild type cells, suggesting the activation of a programmed cell death pathway. Growth of LdCEN^-/- amastigotes in infected macrophages in vitro was inhibited and also resulted in large multinucleated parasites. Normal basal body duplication and cell division in the LdCEN knockout promastigote is unique and surprising. Further, this is the first report where disruption of a centrin gene displays stage-specific/cell type-specific failure in cell division in a eukaryote. The centrin null mutant defective in amastigote growth could be useful as a vaccine candidate against leishmaniasis.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
The centrins are basal body/centriole-associated calcium-binding proteins. Centrin has been characterized in eukaryotes from unicellular organisms such as Chlamydomonas (1, 2) to humans (3-5). Fibers composed of centrin and its binding protein Sfi1p act as contractile or elastic connections between centrioles/basal bodies and other elements of the centrosome to mediate dynamic changes in its overall structure (6, 7). Conditional mutations in yeast centrin (CDC31) result in failure of duplication of the spindle pole body (yeast centrosome) and arrest in mitosis (8, 9). Silencing the centrin gene in the water fern Marsilea vestita effectively inhibits the formation of motile cells (10). Similarly, silencing of human centrin 2 (HsCEN2) in HeLa cells impaired centriole duplication and resulted in the failure of cytokinesis (4). A centrin-deficient mutant of Chlamydomonas was nonflagellate because of defects in the flagellar root system (2). Abnormal centrosomes were noticed in human tumor cells because of the presence of excess levels of many centrosome proteins including centrin (11). We recently cloned several centrin genes¹ and characterized one such a gene, which is involved in the growth of the protozoan parasite, Leishmania donovani (12).

Leishmaniasis currently threatens 1.5-2.0 million people annually with an estimated death toll of 50,000 persons/year in 88 countries around the world (13). Most of the fatalities are due to visceral leishmaniasis. Treatment for this disease involves chemotherapy using antimony-based drugs, which is less effective in immunocompromised individuals and usually associated with drug resistance (13). No effective vaccine has been developed successfully for this disease (13). The parasite L. donovani, a causative agent of human visceral leishmaniasis, has a digenic lifestyle with one form called the promastigote form that resides extracellularly in the mid-gut of the sand-fly vector and with another form called the amastigote form that multiplies intracellularly in vertebrate macrophages. These two forms have been adapted to grow under in vitro conditions (14, 15). To understand the molecular mechanisms of growth control, we cloned and characterized the gene encoding a basal body-associated protein centrin (LdCen) (12). L. donovani centrin protein (LdCenp) sequence similarity and immunoreactivity confirmed that Leishmania centrin (LdCEN) is a homolog of human centrin 2 (12). The high level expression of LdCenp during log phase growth and reduction of growth by overexpression of an N-terminally deleted centrin in both promastigote and amastigote forms indicate that centrin has an important role in Leishmania growth (12). To study the mechanism of centrin function in this lower eukaryote, we targeted the LdCEN gene for a null mutation.

As a method to study gene function, targeted deletion has been successful only for few Leishmania genes. Dihydrofolate reductase-thymidylate synthase and Leishmanolysin genes were deleted in Leishmania major (16-19), and genes involved in Lipophosphoglycan were deleted in Leishmania mexicana and L. major (20-22). These mutant parasites clearly demonstrated the physiological role of the genes that were deleted. Unlike many other eukaryotes, Leishmania is diploid throughout its life cycle. Hence it is necessary to delete both the alleles to generate a null mutant for a specific gene (16). In this report we describe a stepwise disruption of the two alleles of LdCEN, using genes resistant to antibiotics hygromycin B and G418 (Geneticin) and characterization of the LdCEN null mutant parasites for their growth both as extracellular promastigotes and axenic amastigotes as well as intracellular amastigotes inside macrophages. The purpose of the study is to establish a correlation between centrin expression and parasite growth and to characterize the LdCEN null mutants as a first step to evaluate their potential as a live attenuated vaccine in the future.

	EXPERIMENTAL PROCEDURES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
In Vitro Culture of Parasites and Molecular Biology—The parasite culture procedure and the routine molecular biology practices were as previously described (12).

Construction of DNA for Targeted Gene Deletion—For L. donovani centrin gene knockout, nearly two-thirds (1-323 bp (12)) of the LdCEN open reading frame (447 bp; orf)² from the 5' end was replaced with the orf of the selectable marker gene comprising either the hyg gene or neo gene. These genes were flanked at the 5' end by the 1198-bp upstream region of the LdCEN gene and at the 3' end by the 124-bp 3' region of the LdCEN orf followed by 716 bp of its downstream region.

The 5'-UTR of LdCEN was amplified by PCR using a cosmid clone containing the LdCEN gene as template (12) and the following forward (P1) and reverse (P2) primers. P1 (5'-GGG ATC CTT ATA GCC ACG GAT G-3') contains a BamHI restriction site (bold). P2 (5'-GGG TCG ACC CAC AAA AAG AAA TTG-3') contains a SalI restriction site (bold). The resulting PCR product was cloned directly at the T/A cloning site of pCRII-TOPO cloning vector (Invitrogen). The recombinant plasmid having the insert with the SalI end toward the Sp6 promoter was cut with SpeI and KpnI and used in the next step.

The 3'-UTR of LdCEN was PCR-amplified using the cosmid clone mentioned above as template and the following forward (P3) and reverse (P4) primers. P3 (5'-GAC TAG TAC TGC TGG GTG AGA ACC-3') contains a SpeI restriction site (bold). P4 (5'-GGG TAC CTA TTT ATC GCC TGC TCG G-3') contains a KpnI restriction site (bold). The PCR product was restricted with SalI and KpnI and ligated at the same sites of the cut plasmid product of step A. The resulting recombinant plasmid was cut with SalI and SpeI and used in the following step.

The selectable marker sequence hyg was amplified using plasmid pX63-HYG (16) as template and forward (P5) and reverse (P6) primers. The neo gene was amplified using plasmid pKSNEO (23) as template and forward (P7) and reverse (P8) primers. To ensure translation of these marker genes, nucleotides -16 to +12 of the 3'-nucleotidase/nuclease gene including the translation initiation site ATG was added upstream of the hyg and neo genes during PCR amplification (see Fig. 1, M-seq). P5 (5'-G GTC GAC GCT ACG GCA GAC ATG GCT CGA GCT CTG atg aaa aag cct gaa ctc-3') contains sequentially a SalI restriction site (bold), a 3'-nucleotidase/nuclease sequence as mentioned earlier (single underlined), and the first 18 nucleotides of hyg orf (lowercase). P6 (5'-GGA CTA GTC TAT TCC TTT GCC CTC G-3') has a SpeI restriction site (bold) followed by 3' end sequence of hyg gene. P7 (5'-G GTC GAC GCT ACG GCA GAC ATG GCT CGA GCT CTG atg att gaa caa gat gga-3') is similar to primer P5 except the 3' end has the first 18 nucleotides of neo orf (lowercase). P8 (5'-GAC TAG TCA GAA GAA CTC GTC AAG-3') has a SpeI restriction site (bold) followed by the 3' end sequence of the neo gene. Both the PCR-amplified hyg and neo fragments were cut with SalI and SpeI restriction enzymes, and the fragments were ligated at the cut plasmid obtained in the second step. The authenticity of each of the constructs and the fidelity of the PCR-amplified fragments were verified by nucleotide sequencing. The resulted hyg and neo recombinant plasmids were cut with BamHI and KpnI, and the fragments of either hyg or neo flanked with the UTR sequences of LdCEN (constructs 1 and 2, respectively; see Fig. 1) were individually used for transfection to disrupt LdCEN gene in L. donovani.

View larger version (14K): [in this window] [in a new window]   FIG. 1. Schematic diagram showing design and use of constructs for LdCEN gene disruption in the L. donovani genome. Constructs 1 and 2 show hyg and neo genes, respectively, flanked on the 5' and 3' sides with LdCEN 5'-UTR and 3'-UTR, respectively. The lengths of the antibiotic-resistant genes and the LdCEN untranslated regions have been described under "Experimental Procedures." M-seq, 14 nucleotides upstream, the initiation codon and three codons downstream in the L. donovani 3'-nucleotidase/nuclease gene (39) fused in frame to the antibiotic resistance coding sequences to improve translation. BamHI, KpnI, SalI, and SpeI are the restriction sites.

Transfection with construct 1 was performed as described above and finally plated on culture plate containing 80 µg/ml of hygromycin B. Clones isolated from the plates were subsequently expanded in liquid medium containing 40 µg/ml of hygromycin B. Genomic DNA isolated from these cloned parasites was used in Southern blot analyses (12) to confirm the loss of one allele of centrin. Such a cell line in which one allele of the centrin gene was substituted by the hyg gene was subjected to the next round of transfection using Construct 2, and clones were selected on culture containing 80 µg/ml of hygromycin B and 40 µg/ml of G418 antibiotics. The clones were analyzed for the complete knockout of centrin and the presence of both hyg and neo genes using Southern and Western blot analyses as described previously (12). The parasites were grown both as promastigotes and axenic amastigotes in the absence of antibiotics except the single knockout (+/-) that was grown in the presence of hygromycin B 40 µg/ml to avoid elimination of the hyg gene by the duplication of the single centrin allele.

Light and Fluorescence Microscopy—For DAPI fluorescence the parasites grown at different time points were washed once with 1x PBS, treated with trypan blue, air-dried on the microscopic slide, and mounted in Vectashield containing DAPI (Vector Laboratories, Inc.). DAPI stains both nucleus and kinetoplast DNA. The cells were examined for fluorescence under the ECLIPSE TE2000-U microscope (Nikon Corporation, Tokyo, Japan) with epifluorescence, and the images were captured with a digital camera (Hamamatsu C4742-95; Hamamatsu Photonics K.K.) and processed with Open Lab software (Improvision, Inc.). For indirect immunofluorescence studies, 200 µl of cultured cells were harvested and mounted on slides using a Cytospin3 (Shandon, Pittsburgh, PA). The preparation was fixed in -20 °C methanol for 10 min, blocked (10% goat serum, 5% glycerol, 0.1% Nonidet P-40 in PBS) for 30 min, and incubated with 1:2000 anti-centrin (20H5 ascites fluid) for 30 min. The preparation was then washed thoroughly with PBS, incubated in fluorescein isothiocyanate-conjugated secondary antibody for 30 min, washed again, and stained for DNA using DAPI. The cells were subsequently analyzed by fluorescence microscopy as above.

Electron Microscopy—Parasites from 48-h cultures were prepared and examined by electron microscopy as described previously (24).

Flow Cytometry—Flow cytometry was carried out as described (12). Briefly, axenic amastigotes from 24- and 48-h cultures were collected, fixed in 70% ethanol, stained with 50 µg/ml propidium iodide (PI from Sigma) in PBS, and analyzed. For each sample 20,000 fluorescent events were measured. To analyze the plasma membrane integrity, promastigotes were inoculated at 1 x 10⁶ cells/ml into axenic amastigote culture medium, and samples of axenic amastigote cells were collected at various times after inoculation. Fluorescence of the cells treated with propidium iodide (PI) was measured following our published protocols (24). The data are expressed as percentages of PI positive parasites. For each sample 10,000 fluorescent events were measured. All the above analyses were carried out using FACScan flow cytometer (Becton Dickinson Immunocytometry Systems, San Jose, CA) and CELLQuest software, and the data were analyzed using the Modfit Lt. Software (Verity Software House, Inc., Topshan, ME).

TUNEL Assay—LdCEN^-/- and wild type promastigotes were inoculated into axenic amastigote culture medium and allowed to grow for different periods of time. At each time point the cells were harvested by centrifugation and prepared for TUNEL staining according to the manufacturer's protocol (Roche Applied Science). A negative control was included in each staining wherein only the labeling solution was added. The samples were stained, by mounting with Vectashield containing DAPI (Vector Laboratories, Inc.). The specimens were then observed and counted under a fluorescence microscope.

In Vitro Macrophage Infections—Human elutriated monocytes were resuspended at 1.8 x 10⁵ cells/ml in RPMI medium containing macrophage colony-stimulating factor (25), plated in 0.5 ml on eight chamber Lab-Tek tissue culture slides (Miles Laboratories), and incubated for 8 days for differentiation into macrophages. The differentiated macrophages were infected with stationary phase cultures of promastigotes (10:1, parasite to macrophage ratio) as described previously (25). After incubation for 5 h at 37 °C in 5% CO_2, the free extracellular parasites were removed by repeated washings in RPMI, and the cultures were incubated in macrophage culture medium for maximum of 240 h. At 5, 24, 48, 120, and 240 h post-infection, the culture medium was removed from a sample of the culture slides, and the slides were air-dried, fixed by immersion in absolute methanol for 5 min at room temperature, and stained using Diff-Quick Stain set (Baxter Healthcare Corporation, Miami, FL). For each culture, a minimum of 300 macrophages were counted. The results are expressed either as percentages of macrophages that were infected by Leishmania or as the mean number of parasites/infected macrophage.

Restoration of Centrin in LdCEN^-/- Parasites—To restore centrin in the LdCEN^-/- parasites, LdCEN orf was first PCR-amplified using a LdCEN containing plasmid (12) as template and the following forward (P9) and reverse (P10) primers. P9 (5'-GGG ATC CAT GGC TGC GCT GAC GGA T-3') contains a BamHI restriction site (bold). P10 (5'-GGG ATC CCT ACG CGT AGT CCG GCA CGT CGT ACG GGT Act ttc cac gca tgt gca g-3') contains sequentially a BamHI restriction site (bold), a sequence for an hemagglutinin tag (underlined), and 18 nucleotides of 3' end of the LdCEN gene sequence (lowercase letters). The amplified product was initially cloned at the T/A cloning site of pCRII-TOPO cloning vector. The fidelity of the cloned sequence was verified by nucleotide sequencing. The BamHI insert was subsequently cloned at the same cite of pXG-PHLEO vector (26), and the recombinant plasmid, pXG-PHLEO-LdCEN, was transfected into the LdCEN^-/- promastigotes as described previously (12). Transfected promastigotes were selected with minimal doses of phleomycin (Sigma) (10 µg/ml). In our experience, expression of protein through an episome is enhanced by increasing the concentration of selection drug in the medium.³ Hence, the selected promastigotes after each culture cycle were grown in gradually increasing phleomycin levels up to 150 µg/ml. Parasites grown in the presence of 150 µg/ml of drug were used in subsequent experiments.

	RESULTS

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Generation of LdCEN Null L. donovani Promastigotes—We sequentially disrupted the two alleles of the centrin gene by homologous recombination with two different antibiotic-resistant genes as selectable markers. The hyg gene that confers resistance to hygromycin B and the neo gene that confers resistance to Geneticin were flanked at the 5' and 3' ends with the 5'- and 3'-UTRs of the centrin gene, respectively, and used in the recombination procedure (Fig. 1). The centrin gene status of clones was determined by Southern blot analysis using labeled gene-specific probes for centrin, hyg, and neo (Fig. 2A). The Southern blot analysis shows complete loss of the coding region of the LdCEN in double knockout mutants (Fig. 2B, lane 9). Loss of centrin expression in the LdCEN^-/- parasite was also confirmed by Western blot analysis using anti-LdCen antibody (Fig. 2C, lane 3).

View larger version (34K): [in this window] [in a new window]   FIG. 2. A, schematic drawing of the centrin locus in L. donovani with SalI restriction sites. Disrupting the centrin gene with either hyg or neo gene generates an additional SalI site at the 5' end of the selectable marker genes. B, Southern blot analysis of the genomic DNA of Leishmania wild type (+/+), LdCEN single (+/-), and double (-/-) allele disrupted parasites with hyg, neo, and LdCEN genes as 32P-labeled probes. The genomic DNA from the parasites was cut with the restriction enzyme SalI and used in the analysis. C, Western blot analysis of the lysates of +/+, +/-, and -/- parasites using anti-LdCen antibody (12). Lower panel, after the protein transfer the membrane was stained with Ponceau S to show equivalence of protein loading. D, the effect of LdCEN disruption on the in vitro growth of Leishmania promastigotes and axenic amastigotes of wild type (+/+), centrin single allele disrupted (+/-), and centrin null mutant (-/-). The cells were grown in the absence of antibiotics. Initial cell density in the culture was 0.1 x 107 cells/ml. The data represent the means ± S.D. of four independent experiments. No significant difference in growth was observed between +/- and +/+ parasites.

LdCEN^-/- Axenic Amastigotes Accumulate at the G₂/M Stage of the Cell Cycle—To analyze the cause of the growth arrest of the axenic LdCEN^-/- amastigote cells, the axenic amastigote cultures at the 24- and 48-h time points were subjected to cell cycle analysis. Cell cycle analysis by flow cytometry showed that the arrest in growth of the LdCEN^-/- axenic amastigotes at 24 h occurred with a significant accumulation of cells in the G₂/M phase (Fig. 3A). This accumulation became increasingly significant in cells after 48 h of culture (Fig. 3A). To further analyze the growth arrest of LdCEN^-/- axenic amastigotes, 2-day-old cultures were labeled with the DNA-binding stain DAPI and observed under the fluorescence microscope. All wild type axenic amastigote cells showed a single nucleus with one kinetoplast (the mitochondrial genome) (27) (Fig. 3B, upper panels). However, the LdCEN^-/- axenic amastigotes showed large cells with multiple nuclei and kinetoplasts (Fig. 3B, lower panels). To obtain a more detailed picture of these multinucleated cells, LdCEN^-/- axenic amastigotes were examined by electron microscopy (Fig. 3C). The large cells were multinucleated and typically had more than one kinetoplast. These cells were highly plieomorphic in shape as opposed to the wild type control cells that are spherical (Fig. 3C). Some of the multinucleated cells, probably the older ones, displayed condensed nuclei, a feature of cells undergoing apoptosis (data not shown). To quantitate the multinuclear status of the LdCEN^-/- axenic amastigotes, we counted the multinucleated cells after various days in culture, stained with DAPI by fluorescent microscopy. The analysis showed a progressive increase of multi-nucleated cells with time in axenic amastigote cultures of the centrin knockout parasites (Fig. 3D). Conversely, there was a gradual decrease in the number of cells having a single nucleus (Fig. 3D).

View larger version (70K): [in this window] [in a new window]   FIG. 3. A, cell cycle analysis by flow cytometry of L. donovani LdCEN+/+ (+/+) and LdCEN-/- (-/-) parasites. Promastigotes inoculated at 1 x 106 cells/ml in axenic amastigote medium were allowed to grow 24 or 48 h. The resulting axenic amastigotes were harvested, fixed, stained with propidium iodide, and analyzed by flow cytometry. The percentage of cells in each cell cycle stage, G1, S, or G2/M, is plotted for the 24-h time point (left panel) and 48-h time point (right panel). The solid bars indicate the wild type cells (+/+), and the open bars indicate the centrin-deficient ([minus]/-) cells. The data represent the means ± S.D. of three independent experiments. *, p < 0.008; **, p < 0.0005 Student's t test. B, axenic amastigote cells of +/+ and -/- from the 48-h culture were stained with DAPI and viewed under a fluorescent microscope. Right panel, the pale blue spots are kinetoplasts, and the larger dark blue regions are nuclei. Left panel, phase contrast image of the same field shown in the right panel. Scale bar, 5 µm. C, transmission electron micrograph of Leishmania wild type (+/+) and mutant (-/-) axenic amastigotes after 48 h in culture. The kinetoplast (K) and nucleus (N) are indicated. Scale bar,2 µm. D, Quantitative analysis of the number of DAPI-stained nuclei in the LdCEN-/- axenic amastigotes with increasing time in culture. Cells, with one, two, or more than four nuclei, were counted and individually plotted as percentages of cells showing each number of multi-nucleated cell. The results were obtained from at least 150 viable cells (cells not staining to trypan blue) observed in each case. The data represent the means ± S.D. of three independent experiments. E, indirect immunofluorescence analysis of centrin distribution in wild type promastigote (Pro, panel a) and axenic amastigote (Am, panel b), and LdCEN-/- promastigote (panel c) and axenic amastigote (panel d) cells. DAPI stains DNA of nucleus and kinetoplast (blue) and monoclonal antibody to Chlamydomonas centrin (20H5) stains a centrin other than LdCenp (green). Centrin staining at the flagellar base and along the axoneme is evident in promastigote cells (single cell enlarged and shown in the inset in panel a) of both wild type (panel a) and LdCEN-/- (panel c) and at the flagellar basal apparatus in wild type amastigote cells (panel b). LdCEN-/- amastigote cells are largely devoid of 20H5 staining (panel d). Scale bar, 5 µm. F, electron microscopy of the flagellar apparatus of wild type promastigote (panel a) and axenic amastigote (panel b), and LdCEN-/- promastigote (panel c) and axenic amastigote (panel d) cells. Evidence of duplication with more than two basal bodies was frequently observed in wild type promastigote (panel e) and amastigote (panel f) and LdCEN-/- promastigote (panel g) cells but not in LdCEN-/- amastigote cells (panel h) where more than two basal bodies were never seen. Scale bars, 0.5 µm.

LdCEN^-/- Axenic Amastigotes Initiate a Programmed Cell Death Pathway after Their Growth Arrest—To assess the fate of the large multinucleated LdCEN^-/- axenic amastigote cells, we analyzed them by PI staining and fluorescence-activated cell sorter analysis. There was a progressive increase in the number of PI-positive cells, indicating a loss of membrane integrity and cell death in LdCEN^-/- axenic amastigote culture over time (Fig. 4A). The LdCEN^-/- parasites showed at least 2-fold more PI-positive cells than the wild type at both 24 and 48 h of culture (Fig. 4A). The death of cells after becoming multinucleated suggested that an internal mechanism had triggered a programmed cell death. To characterize the death pathway, axenic amastigotes of LdCEN^-/- or wild type cells were subjected to the TUNEL assay for the nicked DNA characteristic of the nuclei of apoptotic cells (24). The TUNEL assay in Fig. 4B (panels a-d) shows the fluorescent microscopic pictures of cells showing DAPI staining as red and TUNEL labeling as green. In Fig. 4B (panels e and f), the merged DAPI and the TUNEL images reveal that the LdCEN^-/- axenic amastigote cells were TUNEL-positive. A few TUNEL-positive cells were observed in the wild type cells (Fig. 4C). In contrast, in the LdCEN^-/- axenic amastigotes a much greater percentage of cells showed TUNEL positivity both 24 and 48 h after shifting to amastigote medium (Fig. 4C). As further evidence for the programmed cell death pathway in centrin null mutant cells, we have observed a higher portion of PhiPhiLux-positive cells in the LdCEN^-/- axenic amastigotes than in the LdCEN^+/+ parasites (data not shown). PhiPhiLux cleavage is a measure of caspase-like activity and was shown to induce in L. donovani parasites either in response to anti-leishmanial drugs or during growth arrest (24). Thus these results suggested that the LdCEN^-/- axenic amastigotes undergo a programmed cell death pathway after they become multinucleated and stop growing.

View larger version (15K): [in this window] [in a new window]   FIG. 4. A, percentage of cells positive for the uptake of PI. fluorescence-activated cell sorter analysis of parasites of the LdCEN+/+ (+/+) (solid bars) and LdCEN-/- (-/-) (open bars) genotypes sampled over time after inoculation into axenic amastigote culture medium. The cell populations were measured for PI on FL-3 channel. The data represent the means ± S.D. of three independent experiments. *, p < 0.003 Student's t test. B, fluorescent microscope images of cells stained by the TUNEL assay. DAPI images false colored red show the staining of both the kinetoplasts and the nuclei (panels a and b). The TUNEL-positive nuclei and kinetoplasts show green fluorescence (panels c and d). DAPI and TUNEL images were merged and shown (panels e and f). Scale bar, 5 µm. C, percentage of TUNEL positive LdCEN+/+ and LdCEN-/- axenic amastigotes at the 0-, 24-, and 48-h incubation periods. The culture at the 0-h time point indeed was the exponentially growing promastigote parasites used to initiate the axenic amastigote culture for the assay. At each time point a minimum of 200 cells were counted. The data represent the means ± S.D. of three independent experiments. *, p < 0.008 Student's t test.

View larger version (43K): [in this window] [in a new window]   FIG. 5. Macrophage infection. A, light microscopy of the Wright-stained human macrophages infected with the LdCEN+/+ (+/+) and LdCEN-/- (-/-) parasites incubated for 120 and 240 h. Am, amastigotes; M, multinucleated parasites. Scale bar, 10 µm. B and C, percentage of infected macrophages (B) and number of parasites/infected macrophage (C) at various time points post-infection. The data represent the means ± S.D. of three independent experiments. *, p < 0.005; **, p < 0.0001 Student's t test.

View larger version (24K): [in this window] [in a new window]   FIG. 6. A, growth analysis of the axenic amastigote parasites of the LdCEN+/+ (+/+), LdCEN-/- (-/-), LdCen knockout parasites with centrin added back by transfection of a centrin expression plasmid (pXG-PHLEO-LdCEN) (-/-AB), and wild type parasite similarly over expressing centrin (+/+AB). The data represent the means ± S.D. of three independent experiments. B, Western blot analysis of the cell lysates from axenic amastigotes of Leishmania +/+, -/-, +/+AB, and -/-AB. The blots were developed using anti-LdCen antibody.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

View larger version (20K): [in this window] [in a new window]   FIG. 7. Model for the stage-specific impairment of cytokinesis in the absence of centrin expression in Leishmania. A, the promastigote of either wild type (WT) or LdCEN-/- shows normal cell division. Apparently, the basal body duplication and cell division do not require the LdCenp in the promastigote stage. Other proteins must be fulfilling this function. B, the amastigote of either wild type or LdCEN-/- that expresses Ldcenp episomally (LdCEN-/-AB) shows normal cell division. C, the amastigote of LdCEN-/- undergoes nuclear and kinetoplast division but does not undergo cell division. There is neither basal body duplication nor cytokinesis. Such cells become large and finally die through a programmed cell death pathway.

In addition, the current study showed for the first time that nuclear duplication in the absence of cytokinesis could trigger a programmed cell death pathway in a protozoan parasite (Fig. 7), a phenomenon observed so far only in higher eukaryotic cells when there is a loss of cell cycle control (31, 32). Thus a programmed cell death pathway in Leishmania could be triggered by an internal signal as well as the external stimuli observed previously in our laboratory (24, 33).

Stage-specific Growth Defect of LdCEN^-/- Parasites—It is unique and surprising to see normal basal body duplication and cell division in the promastigote stage of the LdCEN knockout parasites. We observed that the level of expression of LdCenp was similar in both promastigotes and axenic amastigotes (12). However, we also had observed the existence of more than one centrin type in the L. donovani (12). Our recent search of the L. major genome data bank revealed several additional Leishmania centrin-related genes. Therefore, it is possible that different centrin genes may have stage-specific differential expression and that one of these may complement LdCen function only for promastigotes in the LdCEN^-/- parasite and not in the amastigotes (Fig. 7). Alternatively, the existence of amastigote-specific growth-regulating protein(s) that interact with centrin could fail to function in the LdCEN^-/- amastigotes. In yeast, CDC31 protein (yeast centrin) interacts with KAR1 protein during the initial stages of spindle pole body duplication (34). Discovery of a novel centrin-binding partner, Sfi1p, lends new insight into the functional properties of centrin (6, 7). SfiI protein binds multiple centrin molecules along a series of internal repeats, and the Sfi1p-centrin complex forms Ca²⁺-sensitive contractile fibers that function to orient or position centrioles/basal bodies and to alter centrosome structure. Genetic analysis in yeast and Chlamydomonas by centrin gene knockout clearly demonstrates that centriole/basal body duplication depends on proper Sfi1p-centrin function (see Ref. 6 for a review). Taken together these results from other organisms suggest that multiple mechanisms could be operating to control the function of centrin in Leishmania.

The lack of centrin expression in axenic amastigotes affected specifically their growth in vitro as well as in macrophages. Such a defect in survivability in macrophages is an indication of the lack of parasite virulence, and therefore these LdCEN-deficient parasites could be further tested as a potential vaccine against leishmaniasis. Studies of gene knockouts and their effect on Leishmania virulence have also been performed by several other investigators (16, 17, 35-38), although such alterations did not differentiate between the promastigote and amastigote forms of Leishmania. The present report describes for the first time a gene knockout for a cytoskeletal structural protein in Leishmania and the importance of such a gene for the growth of the parasite. Inactivation of the centrin gene in the amastigote form of other related Leishmania species, which cause other forms of leishmaniasis, such as cutaneous and mucocutaneous diseases, will ultimately be pursued to develop attenuated strains for those species. Such attenuated strains could be vaccine candidates for these diseases as well. Vaccine candidates for other parasitic diseases, such as malaria and Chagas, also could be considered by similar inactivation of the centrin gene, which is likely to play an essential role in those organisms too.

	FOOTNOTES

 
^* The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

^** To whom correspondence should be addressed: DETTD/OBRR/CBER/FDA, Bldg. 29, Rm. 222, 8800 Rockville Pike, Bethesda, MD 20892. Tel.: 301-496-2205; Fax: 301-480-7928; E-mail: nakhasi{at}cber.fda.gov.

¹ A. Selvapandiyan, unpublished data.

² The abbreviations used are: orf, open reading frame; UTR, untranslated regions; PBS, phosphate-buffered saline; DAPI, 4',6-diamidino-2'-phenylindole-dihydrochrolide; PI, propidium iodide; TUNEL, terminal deoxy uridine triphosphate nick end labeling.

³ A. Selvapandiyan, A. Debrabant, R. Duncan, J. Muller, P. Salotra, G. Sreenivas, J. L. Salisbury, and H. L. Nakhasi, unpublished observation.

	ACKNOWLEDGMENTS

 
We thank S. M. Beverley (Washington University School of Medicine, St. Louis, MO) for providing plasmids pXG-PHLEO and pX63-HYG, G. Matlashewski (McGill University, Montreal, Canada) for providing plasmid pKS-NEO, and the Department of Transfusion Medicine, National Institute of Health, for providing the elutriated human monocytes.

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TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 

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