Christiane Giroud

A diamidine-resistant Trypanosoma equiperdum clone contains a P2 purine transporter with reduced substrate affinity

Following the demonstration that the transport of melaminophenyl arsenical drugs in Trypanosoma brucei is dependent upon an unusual adenosine nucleoside transporter (Carter and Fairlamb, Nature 361 (1993) 173-175) we have investigated adenosine transport in the related parasite Trypanosoma equiperdum (Botat1.1) and a cloned derivative resistant to the diamidine drug berenil (diminazene aceturate) with limited cross-resistance to the melaminophenyl arsenical cymelarsen. The parental strain possesses a bipartite adenosine transport system consisting of one component which is inhibited in a dose-dependent and saturable manner with increasing concentrations of inosine and a second component which is similarly inhibited by adenine. Uptake of adenosine on this second transporter is also inhibited in a dose-dependent fashion by berenil and cymelarsen. Both transporters have high affinity for adenosine (apparent Km values of 0.60 and 0.70 mM and Vmax values of 8.4 and 6.9 pmol (s (10(8) trypanosomes))-1 at 25 degrees C, respectively). Thus T. equiperdum shares with T. brucei a system comprising two adenosine transporters named P1 and P2, respectively. The P1 transporter is similar in the sensitive and resistant T. equiperdum clones, whereas the P2 transporter has reduced transport capacity at physiological adenosine concentration and decreased affinity for adenosine in the drug-resistant clone.

Molecular characterisation of mitochondrial and cytosolic trypanothione-dependent tryparedoxin peroxidases in Trypanosoma brucei.

In trypanosomatids, removal of hydrogen peroxide and other aryl and alkyl peroxides is achieved by the NADPH-dependent trypanothione peroxidase system, whose components are trypanothione reductase (TRYR), trypanothione, tryparedoxin (TRYX) and tryparedoxin peroxidase (TRYP). Here, we report the cloning of a multi-copy tryparedoxin peroxidase gene (TRYP1) from Trypanosoma brucei brucei encoding a protein with two catalytic VCP motifs similar to the cytosolic TRYP from Crithidia fasciculata. In addition, we characterise a novel single copy gene encoding a second tryparedoxin peroxidase (TRYP2). TRYP2 shows 51% similarity to TRYP1, possesses a putative mitochondrial import sequence at its N-terminus and has a variant IPC motif replacing the second VCP motif implicated in catalysis in other 2-Cys peroxiredoxins. TRYP1 and TRYP2 were expressed in Escherichia coli, and the purified recombinant proteins shown to utilise hydrogen peroxide in the presence of NADPH, trypanothione, TRYR and TRYX from T. brucei, similar to the C. fasciculata cytoplasmic system. Western blots showed that TRYX, TRYP1 and TRYP2 are expressed in both bloodstream and procyclic forms of the life cycle. To determine the precise localisation of TRYX, TRYP1 and TRYP2 in the parasite, polyclonal antibodies to purified recombinant TRYX and TRYP1 and monoclonal antibody to TRYP2 were generated in mice. In-situ immunofluorescence and immunoelectron microscopy revealed a colocalisation of TRYX and TRYP1 in the cytosol, whereas TRYP2 was principally localised in the mitochondrion.

In vivo and in vitro sensitivity of Trypanosoma evansi and T. equiperdum to diminazene, suramin, MelCy, quinapyramine and isometamidium

The sensitivity of three Trypanosoma equiperdum clones and thirteen Trypanosoma evansi clones originating from the Peoples Republic of China, the Philippines, Ethiopia and elsewhere to a series of drugs was determined in vivo and in vitro. The drugs tested were diminazene aceturate (Berenil), suramin (Naganol), MelCy (Cymelarsan), quinapyramine sulfate (Trypacide) and isometamidium chloride (Samorin). The activity of each drug was expressed as: 1) in vitro: the minimal effective concentration which killed trypanosome population by 100% within 24 h of drug exposure (MEC100); the maximum tolerated concentration in which trypanosomes could propagate at the same rate as the controls during 48 h of drug exposure (MTC100); 2) in vivo: the curative dosage in 100% of infected mice (CD100); the highest ineffective dosage: 100% of infected mice remain infected (ID100). MEC100 values of diminazene aceturate ranged from 0.0556 microgram/ml to 14.24 micrograms/ml for the eleven tested clones (differed by 256-fold); CD100 values of this drug ranged from 2.25 mg/kg to greater than 89 mg/kg (differed by greater than 40-fold). Diminazene aceturate at up to 89 mg/kg had no effect on T. evansi SHBR, T. equiperdum PBR (Berenil resistant organisms selected by continual passage of the organisms through mice treated with increasing concentrations of drug), or T. evansi AH (strain isolated in the field). Comparable MEC100 values for other trypanocides tested were 1-8 micrograms/ml for suramin, 0.005-0.04 microgram/ml for MelCy, 1-16 micrograms/ml for quinapyramine sulfate and 1-4 micrograms/ml for isometamidium chloride. Clones selected for resistance to diminazene aceturate were not cross-resistant to suramin and isometamidium chloride. In contrast, the clones resistant to diminazene were shown to be more sensitive to quinapyramine sulfate than the normal strains in in vivo tests. The results indicate that resistance to diminazene aceturate by T. evansi and T. equiperdum clones in vivo also occurred in vitro. Resistance to isometamidium chloride in the clones tested in vivo was not observed in vitro, except for T. equiperdum SA. It therefore appears that drug bioavailability is altered or drug biotransformation occurs during the in vivo test. We conclude that the in vitro assay procedure may be of potential use for screening new trypanocides and also for the rapid detection of drug resistant isolates of T. evansi and T. equiperdum.

Murine Models for Trypanosoma brucei gambiense disease progression--from silent to chronic infections and early brain tropism.

Background Human African trypanosomiasis (HAT) caused by Trypanosoma brucei gambiense remains highly prevalent in west and central Africa and is lethal if left untreated. The major problem is that the disease often evolves toward chronic or asymptomatic forms with low and fluctuating parasitaemia producing apparently aparasitaemic serological suspects who remain untreated because of the toxicity of the chemotherapy. Whether the different types of infections are due to host or parasite factors has been difficult to address, since T. b. gambiense isolated from patients is often not infectious in rodents thus limiting the variety of isolates. Methodology/Principal findings T. b. gambiense parasites were outgrown directly from the cerebrospinal fluid of infected patients by in vitro culture and analyzed for their molecular polymorphisms. Experimental murine infections showed that these isolates could be clustered into three groups with different characteristics regarding their in vivo infection properties, immune response and capacity for brain invasion. The first isolate induced a classical chronic infection with a fluctuating blood parasitaemia, an invasion of the central nervous system (CNS), a trypanosome specific-antibody response and death of the animals within 6–8 months. The second group induced a sub-chronic infection resulting in a single wave of parasitaemia after infection, followed by a low parasitaemia with no parasites detected by microscope observations of blood but detected by PCR, and the presence of a specific antibody response. The third isolate induced a silent infection characterised by the absence of microscopically detectable parasites throughout, but infection was detectable by PCR during the whole course of infection. Additionally, specific antibodies were barely detectable when mice were infected with a low number of this group of parasites. In both sub-chronic and chronic infections, most of the mice survived more than one year without major clinical symptoms despite an early dissemination and growth of the parasites in different organs including the CNS, as demonstrated by bioluminescent imaging. Conclusions/Significance Whereas trypanosome characterisation assigned all these isolates to the homogeneous Group I of T. b. gambiense, they clearly induce very different infections in mice thus mimicking the broad clinical diversity observed in HAT due to T. b. gambiense. Therefore, these murine models will be very useful for the understanding of different aspects of the physiopathology of HAT and for the development of new diagnostic tools and drugs.

Molecular and Biochemical Characterization of a Cathepsin B-Like Protease Family Unique to Trypanosoma congolense

ABSTRACT Cysteine proteases have been shown to be essential virulence factors and drug targets in trypanosomatids and an attractive antidisease vaccine candidate for Trypanosoma congolense. Here, we describe an important amplification of genes encoding cathepsin B-like proteases unique to T. congolense. More than 13 different genes were identified, whereas only one or two highly homologous genes have been identified in other trypanosomatids. These proteases grouped into three evolutionary clusters: TcoCBc1 to TcoCBc5 and TcoCBc6, which possess the classical catalytic triad (Cys, His, and Asn), and TcoCBs7 to TcoCBs13, which contains an unusual catalytic site (Ser, Xaa, and Asn). Expression profiles showed that members of the TcoCBc1 to TcoCBc5 and the TcoCBs7 to TcoCBs13 groups are expressed mainly in bloodstream forms and localize in the lysosomal compartment. The expression of recombinant representatives of each group (TcoCB1, TcoCB6, and TcoCB12) as proenzymes showed that TcoCBc1 and TcoCBc6 are able to autocatalyze their maturation 21 and 31 residues, respectively, upstream of the predicted start of the catalytic domain. Both displayed a carboxydipeptidase function, while only TcoCBc1 behaved as an endopeptidase. TcoCBc1 exhibited biochemical differences regarding inhibitor sensitivity compared to that of other cathepsin B-like proteases. Recombinant pro-TcoCBs12 did not automature in vitro, and the pepsin-matured enzyme was inactive in tests with cathepsin B fluorogenic substrates. In vivo inhibition studies using CA074Me (a cell-permeable cathepsin B-specific inhibitor) demonstrated that TcoCB are involved in lysosomal protein degradation essential for survival in bloodstream form. Furthermore, TcoCBc1 elicited an important immune response in experimentally infected cattle. We propose this family of proteins as a potential therapeutic target and as a plausible antigen for T. congolense diagnosis.

Kinetoplast DNA analysis of four Trypanosoma evansi strains

Kinetoplast DNA (kDNA), the mitochondrial DNA of trypanosomes, is a network of thousands of topologically interlocked DNA minicircles and about 50 maxicircles. In this study, we have analysed the kDNA molecules of 6 strains of Trypanosoma evansi from different geographical areas. 2 strains were found to be dyskinetoplastic mutants and other 4 kinetoplastic strains absent of maxicircles. The electrophoretic analysis of the minicircles digested with various restriction endonucleases clearly shows that all of the kinetoplastic strains lack profound minicircle heterogeneity typical of T. brucei. However, a slight restriction fragment length polymorphism could be observed with 2 enzymes (Dde I and HinfI) within the minicircle population of each cloned strain. We propose that this sequence diversity is the result of point mutations. Further analysis of the minicircles by nucleotide sequencing revealed that the 4 minicircles of T. evansi strains share extensive regions of homology with each other but only about 50% homology with other species. This homogeneity of T. evansi minicircle sequences may provide a useful tool for classification and identification.

Synthesis and evaluation of the in vivo trypanocidal activity of water soluble organotin compounds

A series of (3-(2-methoxy)ethoxypropyl)tin derivatives were synthesized as potential trypanocidal drugs. The series included an alkyltin trichloride, a dialkyltin dichloride and the corresponding dialkyltin oxide, and six dialkyltin dithio derivatives. Compounds were evaluated for trypanocidal activity using in vitro cultures of Trypanosoma equiperdum and mice infected with the same strain of parasite for in vivo tests. Two of the title derivatives, the bis (3-(2-methoxy)ethoxypropyl)tin dichloride 2 and the corresponding bis (3-(2-methoxy)ethoxypropyl)tin oxide 3, appeared to be water soluble reagents. Furthermore, they are the first examples of organotin compounds presenting interesting in vivo trypanocidal activity.

An essential cell cycle-regulated nucleolar protein relocates to the mitotic spindle where it is involved in mitotic progression in Trypanosoma brucei.

TbNOP86 and TbNOP66 are two novel nucleolar proteins isolated in Trypanosoma brucei. They share 92.6% identity, except for an additional C-terminal domain of TbNOP86 of 182 amino acids in length. Both proteins are found in Trypanosomatidae, but similarity to other eukaryotic proteins could not be found. TbNOP86 and TbNOP66 are expressed at similar level in procyclic and bloodstream forms, although the relative level of expression of TbNOP66 is 11 times lower. TbNOP86 undergoes post-translational modifications, as it is found predominantly at 110 kDa compared with the predicted 86 kDa. Immunofluorescence of overexpressed ty-tagged TbNOP86 and TbNOP66 showed that both proteins accumulated in the nucleolus of G1 cells. This was confirmed by the co-localization of an endogenous TbNOP86-myc with the nucleolar protein Nopp140. TbNOP86-ty localization is cell cycle-regulated, because it colocalizes with the mitotic spindle in mitotic cells. TbNOP86 is required for mitotic progression in both life stages as depleted cells are enriched in the G2/M phase. In procyclic cells, a reduced growth rate is accompanied by an accumulation of zoids (0N1K), 2N1K, and multinucleated cells (xNyK). The 2N1K cells are blocked in late mitosis as nucleolar segregation is completed. TbNOP86 depletion in bloodstream form caused a drastic growth inhibition producing cells bearing two kinetoplasts and an enlarged nucleus (1N*2K), followed by an accumulation of 2N2K cells with connected nuclei and xNyK cells. These studies of TbNOP86 provide a more comprehensive account of proteins involved in mitotic events in trypanosomes and should lead to the identification of partners with similar function.

The in vitro trypanocidal activity of organotin compounds

Summary A series of alkyl (aryl) thio organotin compounds were synthesized as potential trypanocidal drugs. These derivatives were prepared by the treatment of alkyl (or aryl) tin chlorides or oxides with thiols. Compounds were evaluated for trypanocidal activity using in vitro cultures of Trypanosoma equiperdum . Their efficiency for killing the parasites appeared to be under control of both the alkyl (or aryl) part of the molecule and the thio moiety. Several of the synthesized compounds exhibited a high in vitro levels of activity compared with the arsenic derivatives used for chemotherapy.