A comparison of multiplication rates in primary and challenge infections of Trypanosoma brucei bloodstream forms

Cycles within cycles: the interplay between differentiation and cell division in Trypanosoma brucei

The life cycle o f the African trypanosome is divided between the mammal and the tsetse. Those life cycle stages which traverse between these two hosts appear to be pre-adopted for survival in their new habitat They are also non-dividing. Here, Keith Matthews and Keith Gull discuss how and why trypanosomes might enmesh the control o f their cell cycle with their regulation o f the transition between different life cycle forms.

Limitation of Trypanosoma brucei parasitaemia results from density-dependent parasite differentiation and parasite killing by the host immune response

In the bloodstream of its mammalian host, the "slender" form of Trypanosoma brucei replicates extracellularly, producing a parasitaemia. At high density, the level of parasitaemia is limited at a sublethal level by differentiation to the non-replicative "stumpy" form and by the host immune response. Here, we derive continuous time equations to model the time-course, cell types and level of trypanosome parasitaemia, and compare the best fits with experimental data. The best fits that were obtained favour a model in which both density-dependent trypanosome differentiation and host immune response have a role in limiting the increase of parasites, much poorer fits being obtained when differentiation and immune response are considered independently of one another. Best fits also favour a model in which the slender-to-stumpy differentiation progresses in a manner that is essentially independent of the cell cycle. Finally, these models also make the prediction that the density-dependent trypanosome differentiation mechanism can give rise to oscillations in parasitaemia level. These oscillations are independent of the immune system and are not due to antigenic variation.

T-Cell responses during Trypanosoma brucei infections in mice deficient in inducible nitric oxide synthase

We have investigated the possibility that nitric oxide (NO) synthesis may affect the course of a trypanosome infection via T-cell responses using mice deficient in inducible NO synthase (iNOS). Parasitemia levels increased at the same rate in both iNOS-deficient homozygous and control heterozygous mice, and peak parasitemia values were the same in both groups. However, the heterozygous mice maintained higher parasitemia levels after the peak of an infection than the homozygous mice due to a decrease in the rate of clearance of parasites. In iNOS-deficient mice there was an increase in the numbers of total CD4(+) cells and activated (interleukin-2 receptor-expressing) CD4(+) cells in infected mice compared with the numbers in uninfected mice. Spleen cells from infected iNOS-deficient mice displayed increased proliferative responses and gamma interferon secretion when stimulated in vitro than those of control mice. These data suggest that NO production depresses T-helper 1-like responses generated during Trypanosoma brucei infections, thus promoting the survival of the parasite.

Cell density triggers slender to stumpy differentiation of Trypanosoma brucei bloodstream forms in culture

Differentiation from replicating slender forms to non-dividing stumpy bloodstream forms of T. brucei limits the parasite population size in the mammalian host in addition to and independently of the antibody response. Using a culture system for pleomorphic strains of T. brucei we show that slender forms very efficiently differentiate to stumpy forms in vitro and that the induction of differentiation is correlated to cell density. Differentiation in the host and in culture were compared using a battery of markers including cell morphology and volume, cell cycle position, the kinetics of the differentiation, expression of NADH dehydrogenase (diaphorase), expression of several differentially regulated transcripts and the kinetics of transformation to replicating procyclic forms after induction with cis-aconitate. By all available criteria, differentiation in culture reflects the natural process in the mammalian host. Time course experiments reveal a very tight temporal correlation between cell cycle arrest of bloodstream forms, appearance of a stumpy differentiation marker and the competence of a bloodstream form population to initiate transformation to procyclic forms in response to cis-aconitate. Our results show that induction of bloodstream form differentiation can occur independently of host-derived cues. We suggest a density sensing mechanism which induces differentiation to the non-dividing stumpy stage and thereby enables the parasite population to autoregulate its proliferation.

The bloodstream differentiation-division of Trypanosoma brucei studied using mitochondrial markers

In the bloodstream of its mammalian host, the African trypanosome Trypanosoma brucei undergoes a life cycle stage differentiation from a long, slender form to a short, stumpy form. This involves three known major events: exit from a proliferative cell cycle, morphological change and mitochondrial biogenesis. Previously, models have been proposed accounting for these events (Matthews & Gull 1994a). Refinement of, and discrimination between, these models has been hindered by a lack of stage-regulated antigens useful as markers at the single-cell level. We have now evaluated a variety of cytological markers and applied them to investigate the coordination of phenotypic differentiation and cell cycle arrest. Our studies have focused on the differential expression of the mitochondrial enzyme dihydrolipoamide dehydrogenase relative to the differentiation-division of bloodstream trypanosomes. The results implicate a temporal order of events: commitment, division, phenotypic differentiation.

Inhibition of growth of Trypanosoma brucei parasites in chronic infections

The growth of Trypanosoma brucei parasites in chronic infections was investigated by superimposing upon chronic infections, secondary infections in which all parasites expressed the same variable antigen type (VAT). The fate of trypanosomes in secondary infections could then be monitored using the VAT as a marker to discriminate cells in primary and secondary infections and thus enable growth to be observed separately from its interactions with antigenic variation on the part of the parasite and specific immune responses of the host. Our results show that as an infection proceeds, the growth rate is progressively inhibited in mice and sheep, suggesting that inhibition is a general feature of chronic infections. Inhibition was not specific to either the stock or the VAT of the trypanosome, but the degree of inhibition did vary between stocks. Inhibition appeared to be mediated by a lowering of the rate of replication of 'slender'-form parasites rather than by an increase in either the rate of differentiation from dividing slender to non-dividing 'stumpy' forms or the mortality caused by non-specific immune mechanisms. Evidence indicated that the development of specific immune responses to non-variant parasite antigens was also unlikely. These data constitute, we believe, the first evidence for negative regulation of growth in vivo, which may be an important determinant of the virulence of trypanosome infections.

Comparison of the effects of immune killing mechanisms on Trypanosoma brucei parasites of slender and stumpy morphology

Trypanosoma brucei slender forms predominate over stumpy forms as the parasite population grows but at the peak of a parasitaemic wave and during remission of infection stumpy forms predominate. To determine whether this change in predominance might be caused by selective killing of slender forms, the fates of slender and stumpy form trypanosomes in two in vitro assays of immune-mediated killing were compared. Parasite populations in which > 90% of cells were of slender morphology were observed to be killed by antibody-dependent complement-mediated lysis approximately five times faster than populations in which < 15% of cells were slender and most were of intermediate or stumpy morphology. Quantification of the relationship between the proportion of slender forms in the population and the rate of lysis indicated that slender forms were killed approximately 7.3 times faster than other forms. In an opsonization assay, no differences were observed between slender and stumpy forms in the extent to which they attached to macrophages in an antibody-dependent manner. These results suggest that the change in proportions of slender and stumpy forms at the peak of a parasitaemic wave results from slender forms being more susceptible to complement-mediated killing as the antibody response develops.