Targeting the variable surface of African trypanosomes with variant surface glycoprotein-specific,serum-stable RNA aptamers

African trypanosomes cause sleeping sickness in humans and Nagana in cattle. The parasites multiply in the blood and escape the immune response of the infected host by antigenic variation. Antigenic variation is characterized by a periodic change of the parasite protein surface, which consists of a variant glycoprotein known as variant surface glycoprotein (VSG). Using a SELEX (systematic evolution of ligands by exponential enrichment) approach, we report the selection of small, serum-stable RNAs, so-called aptamers, that bind to VSGs with subnanomolar affinity. The RNAs are able to recognize different VSG variants and bind to the surface of live trypanosomes. Aptamers tethered to an antigenic side group are capable of directing antibodies to the surface of the parasite in vitro. In this manner, the RNAs might provide a new strategy for a therapeutic intervention to fight sleeping sickness.     

Genetics of resistance to the African trypanosomes. VII. Trypanosome virulence is not linked to variable surface glycoprotein expression

The question of linkage of virulence traits to variable surface glycoprotein (VSG) expression in African trypanosomiasis was addressed. Previously we demonstrated that daughter cells arising in mice infected with a genetically homogeneous trypanosome population of Trypanosoma brucei rhodesiense were more virulent than the infecting population (J. A. Inverso and J. M. Mansfield, J. Immunol. 130:412, 1983). These virulent trypanosomes expressed differences in surface phenotype compared with the infecting variant types, and we proposed that virulence may be "linked" to VSG expression. In the present study, however, we have shown that expression of virulence is independent of the VSG phenotype displayed by trypanosome populations. A VSG-identical but highly virulent subpopulation of T. b. rhodesiense LouTat 1 was derived by rapid subpassage and subcloning in immunosuppressed mice. The virulent LouTat 1A subclone derived in this manner killed B10.BR/SgSnJ mice in 3 to 4 days postinfection compared with approximately 60 days for the parent clone, LouTat 1. The virulent subclone LouTat 1A appears to express the same VSG as the less virulent LouTat 1 population, as determined by polyspecific and monoclonal antibody-binding assays, cross-protection tests, and amino acid sequence analyses of the N-terminal portion of the VSG molecules. When LouTat 1 and subclone LouTat 1A were injected into a heterologous host species, multiple variant antigenic types (VATs) arising from each inoculum were isolated and characterized. VATs derived from the virulent subclone were as uniformly virulent for B10.BR mice as LouTat 1A. In summary, these results demonstrate that trypanosome virulence, once expressed, is a stable phenotype that does not seem to be associated with a particular VSG phenotype, nor does virulence change with the expression of different VSG genes.     

Genetics of resistance to the African trypanosomes. III. Variant-specific antibody responses of H-2-compatible resistant and susceptible mice

Genetically based differences in variant-specific immunity to the African trypanosomes were examined. H-2-compatible inbred mouse strains that differed in relative resistance were infected with Trypanosoma rhodesiense clone LouTat 1. Antibody responses to exposed epitopes of the LouTat 1 variant-specific surface glycoprotein (VSG) were measured. Relatively resistant B10.BR mice (H-2k) made predictable IgM antibody responses to the VSG of LouTat 1 which were associated with clearance of the LouTat 1 variant antigenic type from blood; IgG responses to LouTat 1 surface antigen appeared after clearance occurred, and were lower than peak titers of IgM. Intermediately susceptible CBA mice (H-2k) also made predictable IgM and IgG responses which followed the same pattern as the more resistant strain. Peak titers were lower for both Ig classes, however, and a delayed appearance of antibody was correlated with delayed clearance of LouTat 1. In contrast to B10.BR and CBA mice, the susceptible C3H mice (H-2k) failed to make detectable antibodies to LouTat 1 surface antigen and also failed to control the first peak of parasitemia. The absence of immunity in infected C3H mice was selective for antibody to exposed epitopes of LouTat 1 VSG because antibody was detectable to invariant VSG or internal trypanosome antigens. Also, the C3H strain was shown not to be a genetic nonresponder to LouTat 1 surface antigen because VSG-specific antibodies appeared within 1 wk after trypanocidal chemotherapy. Finally, we demonstrated that the susceptibility of C3H mice was not associated with an inability of the mononuclear phagocyte system to clear the parasites because drug cure, passive transfer of immune serum, or sensitization of trypanosomes with antibody all led to trypanosome clearance from blood by the liver. In summary, we show for the first time that major differences in variant-specific immunity occur in MHC-compatible animals after infection with the African trypanosomes.     

Genetics of resistance to the African trypanosomes. IV. Resistance of radiation chimeras to Trypanosoma rhodesiense infection

The cellular bases of resistance to the African trypanosomes were examined in inbred mice. As part of these studies, reciprocal bone marrow cell transplants were performed between H-2 compatible mice which differ in relative resistance to Trypanosoma brucei rhodesiense infection. Survival times, parasitemias and IgM antibody responses to the surface antigen of the infecting variant type were measured in these semiallogeneic bone marrow chimeras. Relatively resistant C57BL/10 mice, intermediate A.By mice, and least resistant C3H.SW mice that were reconstituted after lethal irradiation with syngeneic bone marrow cells displayed resistance and immunity characteristic of the homologous donor strain. When C57BL/10 mice were reconstituted with C3H.SW mouse bone marrow cells they retained the ability to produce antibodies to trypanosome surface antigen but the antibody titers were significantly reduced. Control of parasitemia and mean survival time were reduced in these chimeras, but differed significantly from C3H.SW mice. A.By mice that received cells from C57BL/10 donors exhibited antibody responses and survival times similar to the C57BL/10 mice. Survival times of A.By mice given syngeneic cells or C3H.SW cells were the same, but the antibody responses of A.By mice given C3H.SW cells were lower than those of A.By mice given syngeneic cells. C3H.SW mice reconstituted with C57BL/10 bone marrow cells were capable of making antibodies and controlling parasitemia, in marked contrast to the absence of such responses in C3H.SW mice reconstituted with syngeneic cells. Survival times, however, were indistinguishable from those of C3H.SW mice given syngeneic cells. Thus, resistance to T. b. rhodesiense was shown for the first time to depend on donor bone marrow derived cells as well as upon radiation-resistant cells/factors associated with host genetic background. Also, parasite-specific IgM antibody responses seem to be regulated by a mechanism which does not depend on bone marrow derived cells alone, and the presence of such immune responses is not linked to survival time.     

The surface of the African trypanosomes

The African trypanosomes bear on the outside of their cell membrane a single 10-15 nm thick coat of a glycoprotein. This glycoprotein may differ in structure in the predominant populations of parasitemic waves found in relapsing infections. Variant Specific Glycoprotein (VSG) range in MW between 53,000-63,000 d and may have variable amounts of carbohydrate attached at one, two, or several loci. Such differences in carbohydrate content may account in part for their range in molecular size. Approximately 30 C-terminal residues demonstrate isotypy ; i.e. these regions fall into classes having similar amino acid sequence. Modest homology has been demonstrated in two VSGs of T. congolense arising in relapsing infections although comparison of many VSG show little or no obvious homology. More recently, lipid-associated forms of VSG have been described and it is believed that these forms may be transmembrane proteins. Different VSGs appear to have different amounts of the primary sequence which have alpha-helix-forming potential. In some VSG, in excess of 80% of the structure is helical as judged by both Chou-Fasman calculations and by circular dichroism. This raises the possibility that different VSG may have different folding patterns. The arrangement of VSG on the trypanosome surface probably places the basic amino acid-rich carbohydrate-bearing C-terminus of the polypeptide chain close to the membrane. There is some protein-protein association between VSGs for which (in T. evansi) the C-terminal tail is not required. The importance of VSG structure lies not only in the fact that the molecule mediates the phenomenon of antigenic variation but also in the recent observation that VSG may act on the cellular immune system to suppress the humoral immune responses of the host.     

Subcellular localization of a variable surface glycoprotein phosphatidylinositol-specific phospholipase-C in African trypanosomes

African trypanosomes contain a membrane-bound enzyme capable of removing dimyristylglycerol from the membrane-attached form of the variable surface glycoprotein (mfVSG; Ferguson, M. A. J., K. Halder, and G. A. M. Cross, 1985, J. Biol Chem., 260:4963-4968). Although mfVSG phospholipase-C has been implicated in the removal of the VSG from the trypanosome surface (Cardoso de Almeida, M. L., and M. J. Turner, 1983, Nature (Lond.)., 302:349-352; Ferguson, M. A. J., K. Halder, and G. A. M. Cross, 1985, J. Biol Chem., 260:4963-4968), its precise function and subcellular location have not been determined. We have developed a procedure for the separation of the cell fractions and organelles of Trypanosoma brucei brucei (and other trypanosome species) by differential sucrose and isopycnic PercollR centrifugation. These fractions were tested for mfVSG phospholipase activity using Trypanosoma brucei mfVSG labeled with 3H-myristic acid as substrate. The highest enzyme-specific activity was associated with the flagella and evidence is presented to suggest that it is localized in the flagellar pocket. Some activity was also associated with the Golgi complex. These results suggest that the mfVSG phospholipase is localized primarily in the membrane of the flagella pocket and possibly other membrane organelles derived from and associated with this structure, and may be part of the VSG-membrane recycling system in African trypanosomes. The activity of mfVSG phospholipase amongst various trypanosome species was determined. We show that, in contrast to the bloodstream forms of Trypanosoma brucei, cultured procyclic Trypanosoma brucei and bloodstream Trypanosoma vivax had little or no mfVSG phospholipase activity. The activity found in bloodstream forms of Trypanosoma congolense was intermediate between Trypanosoma vivax and Trypanosoma brucei.     

Genetics of resistance to the African trypanosomes. V. Qualitative and quantitative differences in interferon production among susceptible and resistant mouse strains

The induction of interferon (IFN) was examined in different inbred mouse strains infected with Trypanosoma brucei rhodesiense. Relatively susceptible C3HeB/FeJ mice that do not exhibit variant-specific immunity or control parasitemia did not exhibit detectable IFN throughout the infection. Relatively resistant B10.BR mice that exhibit variant-specific immunity and control the first peak of parasitemia exhibited detectable IFN at two intervals. The appearance of IFN in B10.BR serum first coincided with the onset of the parasitemia 4 days after infection and then disappeared; this IFN peak was predominantly IFN-alpha/beta. The second time of appearance coincided with high titers of antibody and remission of the parasitemia. This IFN was predominantly IFN-gamma. Intermediately susceptible CBA/J mice also exhibited two detectable peaks of IFN; the first IFN-alpha/beta peak coincided with the onset of the parasitemia as in B10.BR mice. The second peak of IFN in the serum of CBA mice, however, was delayed in appearance and lower in concentration compared with B10.BR mice. This peak was characterized as being predominantly IFN alpha/beta. BALB/c mice (also intermediately susceptible) did not exhibit a first peak of IFN-alpha/beta production, but the second peak of IFN-alpha/beta production was similar to that seen in CBA mice. In contrast to infected mice, IFN was induced in both susceptible (C3H) and resistant (B10.BR) mice after immunization with glutaraldehyde-fixed trypanosomes or after chemotherapy of infection. We conclude that both the levels of IFN as well as the type of IFN induced during infection with T. b. rhodesiense depend upon the genetic background of the mouse strain infected. The induction of IFN-gamma in mice of the C57BL background may be linked functionally to more effective parasite control and to the presence of an effective immune response to T. b. rhodesiense.     

Identification of a tryptophan-like epitope borne by the variable surface glycoprotein (VSG) of African trypanosomes

Antibodies (Ab) directed against a tryptophan-like epitope (WE) were previously detected in patients with human African trypanosomiasis (HAT). We investigated whether or not these Ab resulted from immunization against trypanosome antigen(s) expressing a WE. By Western blotting, we identified an antigen having an apparent molecular weight ranging from 60 to 65 kDa, recognized by purified rabbit anti-WE Ab. This antigen, present in trypomastigote forms, was absent in procyclic forms and Trypanosoma cruzi trypomastigotes. Using purified variable surface glycoproteins (VSG) from various trypanosomes, we showed that VSG was the parasite antigen recognized by these rabbit Ab. Anti-WE and anti-VSG Ab were purified from HAT sera by affinity chromatography. Immunoreactivity of purified antibodies eluted from affinity columns and of depleted fractions showed that WE was one of the epitopes borne by VSG. These data underline the existence of an invariant WE in the structure of VSG from several species of African trypanosomes.     

Independent regulation of B cell responses to surface and subsurface epitopes of African trypanosome variable surface glycoproteins

Regulation of B cell responses to the trypanosome surface Ag was examined in H-2k compatible "responder" B10.BR and "nonresponder" C3H mice after infection with two variant clones of Trypanosoma brucei rhodesiense. Development of a selective RIA for independent detection of antibody binding to surface (exposed) and subsurface (buried) epitopes of the trypanosome variable surface glycoprotein (VSG) molecule permitted sensitive quantitation and kinetic characterization of immune responses to these epitopes. The infected B10.BR mice responded to both exposed and buried VSG epitopes of clone LouTat 1 trypanosomes, whereas a B cell response by C3H mice to exposed VSG epitopes was not detected by RIA analyses at any time. However, VSG-specific IgM and IgG responses were produced to buried VSG epitopes, demonstrating that LouTat 1 induced immunoregulation was specific only for the B cell responses to exposed VSG epitopes. Subsequently, comparisons of B10.BR and C3H B cell responses to a heterologous variant, LouTat 1.5, were made. The results revealed that both infected mouse strains produced VSG 1.5-specific antibody to exposed and buried epitopes with different kinetics and maximal sera concentrations, showing, therefore, that these responses are not coordinately regulated. In addition, it was clear that the observed immunosuppression to exposed LouTat 1 VSG epitopes in C3H mice could be regulated by the parasite since functional C3H B cell responses were mounted against exposed VSG epitopes of a closely related variant (LouTat 1.5) after infection.     

TatD DNases of African trypanosomes confer resistance to host neutrophil extracellular traps

African trypanosomatid parasites escape host acquired immune responses through periodic antigenic variation of their surface coat. In this study, we describe a mechanism by which the parasites counteract innate immune responses. Two Tat D DNases were identified in each of Trypanosoma evansi and Trypanosoma brucei. These DNases are bivalent metal-dependent endonucleases localized in the cytoplasm and flagella of the parasites that can also be secreted by the parasites. These enzymes possess conserved functional domains and have efficient DNA hydrolysis activity. Host neutrophil extracellular traps(NETs) induced by the parasites could be hydrolyzed by native and recombinant Tat D DNases. NET disruption was prevented, and the survival rate of parasites was decreased, in the presence of the DNase inhibitor aurintricarboxylic acid. These data suggest that trypanosomes can counteract host innate immune responses by active secretion of Tat D DNases to degrade NETs.     

African trypanosomes: inheritance of factors involved in resistance

The C3HeB/FeJ mouse strain has a shorter survival time and is therefore more susceptible to a Trypanosoma brucei rhodesiense infection than the B10.BR/SgSnJ strain. The work reported here demonstrated that survival time is inherited as a recessive trait, whereas the ability to produce antibody to the first variant antigen population is inherited as a dominant trait. It was therefore not possible to correlate survival time with the ability to produce antibody in the F-1 and F-2 offspring. Both characteristics appeared to be multigenic. In addition, it was not possible to link the ability of an animal to control its early parasitemia, or its change in hematocrit, with either antibody production or survival time. The work strongly suggests that the increased survival time of the B10.BR/SgSnJ mouse is due at least partially to nonspecific but unidentified factors which do not segregate with VSG-specific immune responses. These nonspecific factors could include differences in susceptibility to toxic trypanosome catabolites.     

Transporters in African trypanosomes: role in drug action and resistance

Sleeping sickness is an increasing problem in many parts of sub-Saharan Africa. The problems are compounded by the lack of new medication, and the increasing resistance against traditional drugs such as melarsoprol, berenil and isometamidium. Over the last few years, much progress has been made in understanding how drug action, and the development of resistance, is related to the mechanisms by which the parasite ingests the drugs. In some cases novel transporters have been identified. In other cases, transporters do not appear to be involved in drug uptake, and selectivity must lie with other parasite features, such as a specific target or activation of the drug. Lessons learned from studying the uptake of drugs currently in use may assist the design of a much needed new generation of trypanocides.     

Inhibition of murine humoral immune responses by substances derived from trypanosomes

Previous studies of depressed immune responses in mice infected with the mouse-specific Trypanosoma musculi have produced no evidence of major involvement of typical suppressor lymphocytes or macrophages. We continue this line of investigation in the present report by demonstrating that: a) T. musculi strongly suppress the responses of nude mouse spleen cells to the T-independent antigen, TNP-LPS; b) spleen cell preparations of infected mice display a substantial proportion of cells bearing trypanosome-derived substances (TDS) demonstrable by specific rabbit antibody against T. musculi (RATS); c) treatment of spleen cells from infected mice with RATS plus C eliminates the inhibitory effect of these spleen cells on the immune responses of co-cultivated normal spleen cells; d) incubation in vitro of normal spleen cells with an extract of T. musculi results in progressive loss of the cells to respond to antigens and, in addition, confers on the treated cells to respond to antigens and, in addition, confers on the treated cells the property of inhibiting the responses of co-cultivated normal spleen cells; e) T. lewisi, the rat-specific trypanosome, fails to inhibit murine immune responses. We conclude that the immunoinhibitory effects of T. musculi on murine immune responses are associated with the cytophilic binding of TDS (possibly in the form of immune complexes) and that this vigorous mechanism of inhibition will be shown to involve nonspecific mitogenic and/or biosynthetic activation of lymphocytes.     

Genetics of resistance to tetraethyllead.

A Drosophila melanogaster population was exposed for 25 generations to 60 micrograms tetraethyllead per gram of medium. Selection over this period resulted in an increase in fecundity, hatchability and larva-to-adult viability. Chromosome assay showed that response in these traits was generally under additive genetic control in conformity with existing results in the literature on the genetics of resistance to acute environmental stress in D. melanogaster.     

On the role of repeated sequences 5' to variant surface glycoprotein genes in African trypanosomes

In African trypanosomes, the DNA region situated upstream from all active and some silent variant surface glycoprotein genes (VSG genes) has a repetitive structure. This region is composed of a variable number of tandem repeats of an A + T-rich sequence which lacks the recognition sites for most commonly used restriction endonucleases, and is thus called 'barren region'. The length of the barren regions varies in different trypanosome variants from 0.2 to many kb. We have characterized the barren region upstream from the active VSG gene in two independent Trypanosoma equiperdum variants expressing the same VSG gene in the same expression site. To analyse the junction point between the expression site and the inserted gene, these two barren regions were cloned and sequenced. The longer barren region contains 14 repeats and the other contains two repeats. In both cases the junction point has been shown to lie within a repeat but different repeats were used in each case. These results argue that the repeats are important for the insertion of the duplicated-transposed gene into the expression site and that any repeat can be used.