Differentiation of a culture-adapted mutant bloodstream form of Trypanosoma brucei into the procyclic form results in growth arrest of the cells

Trypanosoma brucei: reduction of GPI-phospholipase C protein during differentiation is dependent on replication of newly transformed cells

The protozoan parasite Trypanosoma brucei lives in the bloodstream of vertebrates or in a tsetse fly. Expression of a GPI-phospholipase C polypeptide (GPI-PLCp) in the parasite is restricted to the bloodstream form. Events controlling the amount of GPI-PLCp expressed during differentiation are not completely understood. Our metabolic "pulse-chase" analysis reveals that GPI-PLCp is stable in bloodstream form. However, during differentiation of bloodstream to insect stage (procyclic) T. brucei, translation GPI-PLC mRNA ceases within 8h of initiating transformation. GPI-PLCp is not lost precipitously from newly transformed procyclic trypanosomes. Nascent procyclics contain 400-fold more GPI-PLCp than established insect stage T. brucei. Reduction of GPI-PLCp in early-stage procyclics is linked to parasite replication. Sixteen cell divisions are required to reduce the amount of GPI-PLCp in newly differentiated procyclics to levels present in the established procyclic. GPI-PLCp is retained in strains of T. brucei that fail to replicate after differentiation of the bloodstream to the procyclic form. Thus, at least two factors control levels of GPI-PLCp during differentiation of bloodstream T. brucei; (i) repression of GPI-PLC mRNA translation, and (ii) sustained replication of newly transformed procyclic T. brucei. These studies illustrate the importance of repeated cell divisions in controlling the steady-state amount of GPI-PLCp during differentiation of the African trypanosome.

Conditional expression of glycosylphosphatidylinositol phospholipase C in Trypanosoma brucei

Trypanosoma brucei glycosylphosphatidylinositol phospholipase C (GPIPLC) is expressed in the bloodstream stage of the life cycle, but not in the procyclic form. It is capable of hydrolyzing GPI-anchored proteins and phosphatidylinositol (PI) in vitro. Several roles have been proposed for GPIPLC in vivo, in the release of variant surface glycoprotein during differentiation or in the regulation of GPI and PI levels, but none has been substantiated. To explore GPIPLC function in vivo, tetracycline-inducible GPIPLC gene (GPIPLC) conditional knock-out bloodstream form and tetracycline-inducible GPIPLC-expressing procyclic cell lines were constructed. We were unable to generate GPIPLC null mutants. Cleavage of GPI-anchored proteins was abolished in extracts from uninduced conditional knock-outs and was restored upon induction. Despite the barely detectable level of GPIPLC activity in uninduced conditional knock-out bloodstream forms, their growth was not affected. GPI-protein cleavage activity could be induced in procyclic cell extracts, up to wild-type bloodstream levels. Myo-[3H]inositol incorporation into [3H]inositol monophosphate was about 14-fold lower in GPIPLC conditional knock-out bloodstream forms than in the wild type. Procyclic cells expressing GPIPLC showed a 28-fold increase in myo-[3H]inositol incorporation into [3H]inositol monophosphate and a 1.5-fold increase in [3H]inositol trisphosphate levels, suggesting that GPIPLC may regulate levels of inositol phosphates, by cleavage of PI and phosphatidylinositol 4,5-bisphosphate.

A Trypanosoma brucei bloodstream form mutant deficient in ornithine decarboxylase can protect against wild-type infection in mice

A Trypanosoma brucei bloodstream mutant in which both copies of the ornithine decarboxylase (ODC) gene were knocked out (ODC mutant) was used to determine the biological functions of ODC in T. brucei. Growth of the mutant cells ceased within 12-24 h in regular culture medium deficient in polyamines, but could be rescued by supplementation with 1 mM putrescine. A mouse model of T. brucei infection was used to determine whether the mutant was still infective and was found to develop either extremely low or undetectable levels of parasitemia, suggesting that in T. brucei, ODC activity is essential for establishing an infection. Furthermore, when these mice were subsequently challenged with wild-type T. brucei cells expressing the same variant surface glycoprotein (VSG), they did not develop any parasitemia, indicating that inoculating the mice with the attenuated ODC mutant had conferred protection against challenge by wild-type cells. These results were reproduced in C57BL/6J mice deficient in alpha-beta and gamma-delta T-cell receptors. However, no protection was observed in rag-2 knockout mice deficient in both B and T lymphocytes or in C57BL/10J mice deficient only in B lymphocytes. The results thus suggest that the ODC mutant could induce a T-lymphocyte-independent but B-lymphocyte-dependent immunity against wild-type cells of the same VSG. Such a mechanism of immunity has been elicited only by live T. brucei cells, but not by isolated VSGs or radiation-killed trypanosomes. This ODC mutant may thus represent a genuinely attenuated T. brucei bloodstream form capable of immunizing mammals against infections by African trypanosomes of the same VSG subtype without causing detectable infection by itself. The observation also raises the interesting likelihood that the in vivo treatment of T. brucei bloodstream forms with alpha-DL-difluoromethylornithine is a de facto attenuation of the parasitic organisms, which may very well result in B-lymphocyte-dependent host immune responses to subsequent infections by parasites of the same VSG subtypes.

Developments in the differentiation of Trypanosoma brucei

During the course of their life cycle, African trypanosomes encounter many differing environments and respond to these by dramatic changes in cell shape, metabolism and patterns of gene expression. Many of these life cycle transitions can now be carried out in vitro, allowing their underlying controls to be studied. Here, Keith Matthews presents an overview of recent advances in the understanding of the regulation of these complex differentiation events.

Directing differentiation in Theileria annulata: old methods and new possibilities for control of apicomplexan parasites

Apicomplexan parasites are major pathogens of humans and domesticated animals. The ability of these organisms to evade the host immune response and the emergence of drug-resistant parasites indicates a need for the identification of novel control strategies. Ideally, selected targets should be shared by a range of apicomplexans and fundamental to parasite biology. One process of apicomplexan biology which may provide this type of target is the molecular regulation of stage differentiation. This paper has reviewed studies carried out on differentiation of Theileria annulata and has highlighted general similarities with other apicomplexan differentiation steps. Similarities include asynchrony of differentiation, the loss (attenuation) of differentiation potential and an association between reduced proliferation and differentiation. In addition, novel data are presented assessing a possible role for a signal transduction mechanism or a direct involvement of classical heat-shock polypeptides in regulating differentiation of T. annulata in vitro. These studies, and previously published data, have led to the postulation that progression to the next stage of the life-cycle can be predetermined and involves the attainment of a quantitative threshold by regulators of gene expression. A modification of this model takes into account that for certain in-vitro systems, or differentiation steps in vivo, the process has to be initiated by alteration of the extracellular environment. Work which has shown that the time taken to achieve differentiation can be increased or decreased is also outlined. The ability to change the timing of differentiation suggests that the associated regulatory mechanism could be manipulated directly to significantly influence the outcome of an apicomplexan infection. The observation that a number of existing drugs and control strategies may exert their protective effect by altering differentiation potential supports this possibility.

The role of proteolysis during differentiation of Trypanosoma brucei from the bloodstream to the procyclic form

The in vitro differentiation of Trypanosoma brucei from bloodstream to procyclic (insect) forms is accompanied by diminishing variant surface glycoprotein (VSG) and increasing levels of procyclin and phosphoenolpyruvate carboxykinase (PEPCK). In this study, we examined the fate of several glycolytic enzymes of T. brucei during differentiation. We observed a down-regulation of glycosomal phosphoglycerate kinase (gPGK) during differentiation. In contrast, intracellular levels of glycosomal glyceraldehyde-3-phosphate dehydrogenase (gGAPDH), aldolase (ALD), and phosphoglucoisomerase (PGI) remained unchanged during differentiation and apparently continued to be synthesized in the procyclic form. To determine the potential role of proteasomes and other proteases during the differentiation process, we tested the effect of lactacystin, a specific inhibitor of proteasome activity, and morpholinourea-Phe-homoPhe-benz-alpha-pyrone (P27), a selective inhibitor of cysteine proteases, on the in vitro differentiation of T. brucei. Cells differentiated normally in the presence of 1 microM lactacystin, which confirmed our previous observation that this differentiation does not require crossing any phase boundaries in the cell cycle (Mutomba and Wang, Mol Biochem Parasitol 1996;80:89-102). But the cells thus differentiated did not increase in number and retained gPGK. Cells differentiated under 2 microM P27 also proceeded at a normal rate but failed to multiply and retained gPGK. However, most of the differentiated cells under 2 microM P27 also retained VSG on the cell membrane surface and expressed higher levels of procyclin suggesting that a cysteine protease(s) may be involved in releasing VSG and partially reducing procyclin during differentiation. This cysteine protease(s) has been tentatively identified in the procyclic cells as a 48 kDa protein through labeling of cysteine protease(s) with a biotinylated P27 homolog K02 (morpholinourea-Phe-homoPhe-vinylsulfone).

Inhibition of proteasome activity blocks cell cycle progression at specific phase boundaries in African trypanosomes

Proteasomes are one of the cellular complexes controlling protein degradation from archaebacteria to mammalian cells. We recently purified and characterized the catalytic core of the proteasome, the 20S form, from Trypanosoma brucei, a flagellated protozoa which causes African trypanosomiasis. To identify the role of proteasomes in African trypanosomes, we used lactacystin, a specific inhibitor of proteasome activity. Lactacystin showed potent inhibition of the activity of 20S proteasomes purified from both bloodstream and procyclic (insect) forms of T. brucei (IC50 = 1 microM). It also inhibited proliferation of T. brucei cells in culture assays, with 1 microM inhibiting growth of bloodstream forms, whereas 5 microM was required to block proliferation of procyclic forms. Analysis of the DNA content of these cells by flow cytometry showed that 5 microM lactacystin arrested procyclic cells in the G2 + M phases of the cell cycle. Fluorescence microscopy revealed that most of the cells had one nucleus and one kinetoplast each, indicating that the cells had replicated their DNA, but failed to undergo mitosis. This suggests that transition from G2 to M phase was blocked. On the other hand, incubation of bloodstream forms with 1 microM lactacystin led to arrest of 30-35% of the cell population in G1 and 55-60% of the cells in G2, indicating that both transition from G1 to S and from G2 to M were blocked. These observations were also confirmed by using another inhibitor of proteasome, N-carbobenzoxy-L-leucyl-L-leucyl-L-norvalinal (LLnV), which arrested procyclic forms in G2, and bloodstream forms in both G1 and G2. These results suggest that proteasome activity is essential for driving cell cycle progression in T. brucei, and that proteasomes may control cellular functions differently in bloodstream and procyclic forms of T. brucei.

Effects of aphidicolin and hydroxyurea on the cell cycle and differentiation of Trypanosoma brucei bloodstream forms

The effects of aphidicolin (APH) and hydroxyurea (HU) on the cell cycle and differentiation of Trypanosoma brucei bloodstream forms were studied. APH (0.1 microgram ml-1) inhibited cell division, but did not inhibit DNA synthesis. Most of the cells were arrested in the G2 phase of the cell cycle, with each cell containing two kinetoplasts, but only one nucleus. Recovery of the arrested cells showed a 24-h lag period compared to controls. Higher concentrations of APH (1 and 10 micrograms ml-1) were required to inhibit DNA synthesis, but the cells failed to resume growth after removal of the drug. Incubation of cells with HU (7.5 micrograms ml-1) did not inhibit DNA synthesis, but arrested cells after duplicating both the kinetoplast and the nucleus. Recovery from drug arrest also showed a 24-h lag period. We therefore conclude that neither APH nor HU arrests T. brucei at the G1/S phase boundary as anticipated. The mechanisms of cell cycle arrest by APH and HU are not through inhibition of DNA synthesis, but rather through unidentified pathways, leading to growth arrest prior to nuclear division and cytokinesis respectively. Since the arrested cells do not resume normal development immediately following drug removal, APH and HU should be regarded as unsuitable agents for synchronizing T. brucei bloodstream forms. T. brucei bloodstream forms arrested with either APH or HU differentiated normally into procyclic forms in vitro, indicating that a cycle of cell division is not required for initiation of differentiation, and that the process can be initiated and completed when cells are arrested at the G2/M and M/G1 phase boundaries.

Cloning by functional complementation in Trypanosoma brucei

A procyclic Trypanosoma brucei double-knockout mutant lacking the ornithine decarboxylase (ODC) gene was transfected with a T. brucei genomic library in the expression vector pTSO-HYG4, which utilizes the PARP promoter and replicates extrachromosomally by virtue of a minicircle origin of replication. Transfectants which grew in the absence of exogenous putrescine, the product of the ODC-catalyzed reaction, were obtained at a frequency of 1.6 x 10(-7) and shown to restore ODC protein synthesis and enzymatic activity. Restriction enzyme patterns and Southern blot analysis of plasmids recovered from these cells and propagated in E. coli showed that the inserts contained a single copy of the T. brucei ODC gene. These results demonstrate for the first time the feasibility of identifying novel T. brucei genes by direct complementation of mutant T. brucei cell lines.