The occurrence of rosetting of Plasmodium falciparum-infected human red blood cells (IRBC) with uninfected red blood cells (RBC) and its potential pathophysiologic consequences were investigated under flow conditions using the perfused rat mesocecum vasculature. Perfusion experiments were performed using two knobby (K+) lines of P falciparum, ie, rosetting positive (K+R+) and rosetting negative (K+R-). The infusion of K+R+ IRBC resulted in higher peripheral resistance (PRU) than K+R- IRBC (P less than .0012). Video microscopy showed that under conditions of flow, in addition to cytoadherence of K+R+ IRBC to the venular endothelium, rosette formation was also restricted to venules, especially in the areas of slow flow. Rosettes were absent in arterioles and were presumably dissociated by higher wall shear rates. The presence of rosettes in the venules must therefore reflect their rapid reformation after disruption. Cytoadherence of K+R+ IRBC was characterized by formation of focal clusters along the venular wall. In addition, large aggregates of RBC were frequently observed at venular junctions, probably as a result of interaction between flowing rosettes, free IRBC, and uninfected RBC. In contrast, the infusion of K+R+ IRBC resulted in diffuse cytoadherence of these cells exclusively to the venular endothelium but not in rosetting or large aggregate formation. The cytoadherence of K+R+ IRBC showed strong inverse correlation with the venular diameter (r = -.856, P less than .00001). Incubation of K+R+ IRBC with heparin and with monoclonal antibodies to glycoprotein IV/CD36 abolished the rosette formation and resulted in decreased PRU and microvascular blockage. These findings demonstrate that rosetting of K+R+ IRBC with uninfected RBC enhances vasocclusion, suggesting an important in vivo role for rosetting in the microvascular sequestration of P falciparum-infected RBC.
The course of infection of Plasmodium fragile in its natural host, the toque monkey Macaca sinica, consists of a primary peak of parasitemia followed by several distinct, successive peaks of lower parasitemia. In the S+ host, the late intraerythrocytic asexual developmental stages of P. fragile induce the expression of antigens on the surface of infected erythrocytes, which could be detected using the technique of surface immunofluorescence. Immunofluorescence using unfixed erythrocytes in suspension has shown that antigens are recognized by immune serum on the surface of the erythrocytes infected with more mature stages of the parasite. These antigens undergo variation, each successive peak of parasitemia being characterized by a different variant antigenic type (VAT). The appearance of the successive VATs occurs in a sequential manner, following the same order in different sets of animals. This constitutes the first example of a sequential expression of antigens in a malaria parasite; it indicates that, in P. fragile, antigenic variation is not the result of random mutations selected by antibody. Parasite-induced antigens on the surface of infected erythrocytes could not be detected in the S- host. However, when nonexpressing parasites from the S- host were transferred by blood passage into a naive S+ animal, they began to express antigens on the surface of infected erythrocytes within two erythrocytic cycles. We have demonstrated that the ability of S- parasites to switch to a particular VAT when passaged into a S+ animal changes during the course of an infection in the S- animal, indicating that, although surface antigens are not expressed, the processes leading to antigenic variation occurs even in the S- host. Antibodies directed against these surface antigens inhibit the growth of intra-erythrocytic parasites. The growth inhibition effects of antibodies are also variant specific, indicating that these variant surface antigens are functionally important for parasite survival.
Two genes encoding membrane antigens of Plasmodiumfalciparum were isolated by transient expression in mammalian cells and selection with human immune sera from African adults exposed to P. falciparum malaria. COS-7 cells were transfected with a plasmid expression library constructed from P. falciparum genomic DNA, and cells expressing reactive malaria antigens on their surface were enriched by adherence to antibody-coated dishes. One of the genes isolated is distinctive in that it does not contain repeat sequences typical of many malarial genes cloned by immunoscreening of bacterial expression libraries. The second gene apparently encodes a polymorphic version of the P. falciparum merozoite surface antigen Ag513, since the two sequences are identical in the 5' and 3' coding regions but diverge completely in the center. The COS-7 expression system provides an alternate means for cloning genes encoding malarial membrane antigens by using those antibodies in complex immune sera that bind membraneassociated, nondenatured molecules.Proteins expressed on the surface of parasites constitute potential target antigens for vaccine development. These molecules are accessible to the immune system and also may mediate functions vital for parasite survival such as cell attachment, host-cell invasion, or membrane transport. In the case of Plasmodium falciparum, surface membrane antigens of the asexual blood stages are of special interest because these stages are responsible for the high morbidity and mortality of P. falciparum malaria. The P. falciparum genes characterized to date have been cloned largely in bacterial expression systems, typically by using Agtll cDNA or genomic libraries in Escherichia coli and screening with human immune serum (1, 2). However, with these methods few genes for malarial surface antigens have been cloned, possibly due to poor expression of membrane proteins in E. coli and the fact that bacterial fusion proteins lack epitopes dependent on native secondary or higher order protein conformations. In this paper we show that genes encoding parasite membrane proteins can be isolated directly by expression in mammalian cells and selection for cells bearing heterologous surface antigens by using human immune serum from individuals exposed to the infection of interest. This method should be generally applicable to a number of parasitic diseases. Although the genes for a number of different human cell surface antigens have been cloned by transient expression in mammalian cells, these have been isolated exclusively from cDNA libraries, and immunological selection has depended on specific monoclonal antibodies (3-6). We demonstrate that genomic libraries can also be used in similar expression cloning and that polyspecific antibodies from human serum can be used for selection of transfected cells. MATERIALS AND METHODScDNA Expression Vector pJFE14. This simian virus 40 (SV40)-based COS cell expression vector is derived from pSSD2. The vector pSSD2 is similar to the original Okayama and Berg vector pcD...
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