Plasmodium falciparum: immune pressure in Saimiri sciureus monkeys can select for a parasite population inducing a protective immunity that is not controlled by antibody.

Protective immunity against a Plasmodium falciparum blood infection can be passively transferred by antibodies in humans and in the primate experimental malaria model Saimiri sciureus. We report here the emergence of a novel virulent parasite population after such passive transfer of hyperimmune serum in splenectomized monkeys. These FUP-2 parasites have been partially genotyped and phenotyped. Although no genotypic variation was detected for four polymorphic loci compared to the original FUP-1 parasite population, FUP-2-infected erythrocytes exhibit little or no detectable surface determinants, including those reacting with antibodies raised against FUP-1 surface antigens. In addition, FUP-2-infected erythrocytes exhibit no rosetting or autoagglutination. Interestingly, although Saimiri monkeys control efficiently FUP-2 parasites after repetitive infections, this protection cannot be passively transferred to naive recipients. Our results suggest that antibody-mediated and antibody-independent T-cell-mediated protective responses may cooperate in controlling P. falciparum infection in splenectomized Saimiri monkeys.

Evaluation of spoligotyping in a study of the transmission of Mycobacterium tuberculosis.

Spoligotyping (for spacer oligotyping) is an easy, economical, and rapid way of typing Mycobacterium tuberculosis complex strains with the DR spacer markers (J. Kamerbeek et al., J. Clin. Microbiol. 35:907-914, 1997; D. van Soolingen et al., 33:3234-3248, 1995). The stability of the markers was demonstrated by showing that all the Mycobacterium bovis BCG strains tested gave the same spoligotyping pattern. None of the 42 atypical mycobacterial strains tested gave a spoligotyping signal, indicating the specificity of the technique for M. tuberculosis complex. The utility of the spoligotyping method was demonstrated by analyzing 106 isolates of M. tuberculosis obtained over 1 year in three Paris hospitals. The results obtained by this technique were compared to those obtained by Torrea et al. (G. Torrea et al., J. Clin. Microbiol. 34:1043-1049, 1996) by IS6110-based restriction fragment length polymorphism (RFLP) analysis. Strains from patients with epidemiological relationships that were in the same IS6110-RFLP cluster were also in the same spoligotyping group. Spoligotyping was more discriminative than RFLP analysis for strains with one or two copies of IS6110. RFLP analysis did not discriminate between the nine strains with one or two IS6110 bands with no known epidemiological relation, whereas spoligotyping distinguished between eight different types. IS6I10-RFLP analysis split some of the spoligotyping clusters, particularly when the IS6110 copy number was high. Therefore, we propose a strategy for typing M. tuberculosis strains in which both markers are used.

Flow cytometry detection of surface antigens on fresh, unfixed red blood cells infected by Plasmodium falciparum.

The immunofluorescence detection of parasite-specific antigens on the surface of red blood cells infected by Plasmodium falciparum parasites is usually performed by visual detection under a fluorescence microscope. We describe here a technique permitting the analysis of surface immunofluorescence labelling by flow cytometry. Infected red blood cells are selected on the basis of their parasitic DNA and RNA content by Hoechst and Thiazole Orange vital dyes. Cytometric analysis of these labels, as well as general erythrocyte characteristics assessed by analysis of forward and side scatter allows the selection of viable intact infected erythrocytes from other blood cells. The integrity of these selected erythrocytes was confirmed by the absence of labelling with antibodies directed against internal components such as spectrin. This technique permits the detection of specific surface immunofluorescence staining on red blood cells infected with mature stages of P. falciparum by antibodies in sera from hyperimmune Saimiri monkeys. Using Thiazole Orange dye for detection of parasitised cells, this analysis was performed on a FACSscan apparatus equipped with a single laser.