Nonphosphorylated peptide ligands for the Grb2 Src homology 2 domain.

Critical intracellular signals in normal and malignant cells are transmitted by the adaptor protein Grb2 by means of its Src homology 2 (SH2) domain, which binds to phosphotyrosyl (pTyr) residues generated by the activation of tyrosine kinases. To understand this important control point and to design inhibitors, previous investigations have focused on the molecular mechanisms by which the Grb2 SH2 domain selectively binds pTyr containing peptides. In the current study, we demonstrate that the Grb2 SH2 domain can also bind in a pTyr independent manner. Using phage display, an 11-amino acid cyclic peptide, G1, has been identified that binds to the Grb2 SH2 domain but not the src SH2 domain. Synthetic G1 peptide blocks Grb2 SH2 domain association (IC50 10-25 microM) with a 9-amino acid pTyr-containing peptide derived from the SHC protein (pTyr317). These data and amino acid substitution analysis indicate that G1 interacts in the phosphopeptide binding site. G1 peptide requires a YXN sequence similar to that found in natural pTyr-containing ligands, and phosphorylation of the tyrosine increases G1 inhibitory activity. G1 also requires an internal disulfide bond to maintain the active binding conformation. Since the G1 peptide does not contain pTyr, it defines a new type of SH2 domain binding motif that may advance the design of Grb2 antagonists.

Overexpression and purification of a fimbria-associated adhesin of Streptococcus parasanguis.

A Streptococcus parasanguis adhesin that blocks the attachment of S. parasanguis FW213 to saliva-coated hydroxyapatite (SCHA) has been purified. Previous work demonstrated that the attachment of FW213 to SCHA is mediated by fimbriae and that one component associated with fimbriae is a 36-kDa protein (FimA) that reacts with antifimbria serum in Western blots (immunoblots) and is not present in afimbriated mutants. To obtain amounts of FimA sufficient for adhesion blocking assays, we cloned the gene coding for FimA into an Escherichia coli T7 overexpression system. The resulting strain produced large amounts of FimA, as much as 50% of the total cell protein. FimA was purified by elution from sodium dodecyl sulfate-polyacrylamide gels, and its native conformation was reestablished by sodium dodecyl sulfate removal, resolubilization in guanidine hydrochloride, and 50-fold dilution. Some refolded FimA aggregated into dimers and trimers. Preincubation of SCHA with 100 micrograms of purified, renatured FimA per ml blocked 85% of the binding of FW213. The FimA-SCHA complex was quite stable and could be washed continuously for at least 2 h with only a slight loss of FimA blocking activity. When FimA was added to preformed bacterium-SCHA complexes, it displaced 40% of the bacteria already bound to SCHA. The results suggest that FimA is an adhesin with a high substrate affinity and may prove useful in the development of a therapeutic agent for the prevention of plaque formation and endocarditis initiated by the sanguis streptococci.

A protective monoclonal antibody specifically recognizes and alters the catalytic activity of schistosome triose-phosphate isomerase.

mAb M.1 was previously shown to recognize a 28-kDa Ag in all stages of the human helminth parasite, Schistosoma mansoni, and to bind to the surface membranes of newly transformed schistosomula in a transient manner. Here we demonstrate that M.1 passively transfers partial resistance (41-49%) to cercarial challenge in naive mice. Thus, the 28-kDa Ag recognized by M.1 is a putative vaccine candidate. After immunoaffinity purification, tryptic digests of the 28-kDa Ag were prepared and individual peptides were sequenced. Amino terminus sequences of tryptic peptides of the 28-kDa Ag had high (79-87%) sequence homology with the mammalian glycolytic/gluconeogenic enzyme triosephosphate isomerase (TPI). Purified, native 28-kDa Ag from adult parasites was shown to function enzymatically in an analogous manner to yeast and mammalian TPI in the reverse reaction. Addition of M.1 antibody to the enzyme reaction altered the catalytic activity of schistosome TPI. To determine the immunologic cross-reactivity of this vaccine candidate with mammalian TPI, Western blot analysis was performed and demonstrated that M.1 was immunologically specific for the schistosome enzyme.

Purification and immunochemical characterization of a 22 kilodalton surface antigen from Schistosoma mansoni.

A 22 kDa antigen (Sm22) was purified from schistosomula membrane extracts by immunoaffinity chromatography with monoclonal antibody M.2. Western blotting suggested that the epitope bound by M.2 required a specific conformational folding of the molecule, which was sensitive to reducing agents. Two-dimensional electrophoresis of purified Sm22 demonstrated that the single 22 kDa protein recognized by M.2 on one-dimensional gel analysis was composed of at least two isomorphs. Additional Western blotting showed that Sm2 was one of the major antigens recognized by mouse anti-irradiated cercariae serum, and that this same serum recognized at least one epitope which was not sensitive to reducing agents. The mice vaccinated with irradiated cercariae were shown to be 75% protected from cercarial challenge. Sera from a rabbit immunized with Sm22 contained antibodies which bound to the surface of schistosomula and detected a single protein at 22 kDa by immunoprecipitation or Western blot. The rabbit anti-Sm22 sera also immunoprecipitated a 22 kDa in vitro translation product, indicating that at least one epitope on Sm22 is not dependent on glycosylation.

Identification by monoclonal antibody of a major (28 kDa) surface membrane antigen of Schistosoma mansoni.

Monoclonal antibody M.1 was generated from mice immunized with membrane enriched extracts of mechanically transformed schistosomula. M.1 bound to the surface membranes of cercariae and young (0-24 h post-transformation) schistosomula but did not bind to older schistosomula or cultured worms. M.1 immunoprecipitated an antigen of approximate molecular weight 27-28 kDa from schistosomula. Experiments using metabolic labeling showed that the antigen was actively synthesized by developing schistosomula. Further M.1 immunoprecipitated a similar 27-28 kDa antigen from membrane-enriched extracts of miracidia, lung and adult worms as well as from schistosomula.

Parasite sequestration in Plasmodium falciparum malaria: spleen and antibody modulation of cytoadherence of infected erythrocytes.

Sequestration, the adherence of infected erythrocytes containing late developmental stages of the parasite (trophozoites and schizonts) to the endothelium of capillaries and venules, is characteristic of Plasmodium falciparum infections. We have studied two host factors, the spleen and antibody, that influence sequestration of P. falciparum in the squirrel monkey. Sequestration of trophozoite/schizont-infected erythrocytes that occurs in intact animals is reduced in splenectomized animals; in vitro, when infected blood is incubated with monolayers of human melanoma cells, trophozoite/schizont-infected erythrocytes from intact animals but not from splenectomized animals bind to the melanoma cells. The switch in cytoadherence characteristics of the infected erythrocytes from nonbinding to binding occurs with a cloned parasite. Immune serum can inhibit and reverse in vitro binding to melanoma cells of infected erythrocytes from intact animals. Similarly, antibody can reverse in vivo sequestration as shown by the appearance of trophozoite/schizont-infected erythrocytes in the peripheral blood of an intact animal after inoculation with immune serum. These results indicate that the spleen modulates the expression of parasite alterations of the infected erythrocyte membrane responsible for sequestration and suggest that the prevention and reversal of sequestration could be one of the effector mechanisms involved in antibody-mediated protection against P. falciparum malaria.

Surface alterations of erythrocytes in Plasmodium falciparum malaria. Antigenic variation, antigenic diversity, and the role of the spleen.

The surface of erythrocytes infected with late developmental stages of Plasmodium falciparum is profoundly altered and new antigenic determinants can be detected by surface immunofluorescence using immune squirrel monkey serum. The expression of these parasite-specific antigenic determinants on the surface of the host erythrocyte can be modulated by the presence or absence of the spleen and by immune pressure. An antigenic switch occurred when a cloned population of the Ugandan Palo Alto strain of P. falciparum was transferred from a splenectomized into an intact monkey and this switch was reversible. In another strain (Indochina-1), we showed that the parasites isolated during secondary and recrudescent peaks expressed erythrocyte-associated surface antigens different from the parasites isolated during the primary infection; six variant antigenic types distinct from the original population were isolated in this way. The passive transfer of immune serum can induce antigenic variation and this can occur in a cloned parasite. The various mechanisms of antigenic variation in P. falciparum are discussed in the context of strain-specific diversity and the role of antigenic diversity in acquired immunity.

Expression of strain-specific surface antigens on Plasmodium falciparum-infected erythrocytes.

Antigenic determinants present on the surface of squirrel monkey erythrocytes infected with late developmental stages of P. falciparum were recognized through their ability to bind antibodies present in the serum of immune monkeys. Two different assays were used to demonstrate the presence of these antigenic determinants on the cell surface: the fluorescent labelling of intact cells in suspensions and the binding to protein A-Sepharose. Such determinants appear to be strain-specific and have, for a given strain, a variable expression according to whether the parasites are taken from intact or splenectomized animals or whether they have been grown in vitro.

Interactions of Plasmodium falciparum infected erythrocytes with ligand-coated agarose beads.

The binding of normal and Plasmodium falciparum-infected squirrel monkey erythrocytes to columns of ligand-coated agarose beads was compared. Concanavalin A, ricin, soybean and peanut agglutinin-coated beads retain erythrocytes containing large developmental stages of the parasite preferentially to ring-containing erythrocytes or to normal erythrocytes. Binding is inhibited by the sugar corresponding to the lectin's specificity. Preferential binding does not occur with wheat germ or Ulex europaeus agglutinin-coated beads. When infected blood is preincubated in immune serum, infected erythrocytes are specifically retained by Protein A-coated beads. These peculiar binding properties reflect modifications of the infected erythrocyte membrane.