Plasmodium falciparum-specific human T cell clones: recognition of different parasite antigens.

T lymphocyte clones specific for malarial (Plasmodium falciparum) blood stage antigens were obtained from acutely infected patients or from donors living in a malaria-endemic area of West Africa. Thirty-four clones carrying the CD4 antigen, and one CD8+ clone, were tested in a proliferation assay for their capacity to recognize P. falciparum isolates of different geographical origins. Only one clone distinguished between different parasite isolates (it failed to react with a parasite isolate originating from East Africa, but did recognize West African and Asian isolates). All of the clones responded well to intact erythrocytes containing viable parasites, but some responded poorly to extracts of parasitized cells. Eight of 19 clones studied (all CD4+) recognized parasite antigens which had characteristic mobilities in sodium dodecyl sulfate-containing polyacrylamide gels. The antigens had apparent molecular weights of about 20,000, 35,000, 40,000, 120,000, 150,000-200,000 and 200,000. These results (together with a previous report of two clones recognizing an antigen of molecular weight about 50,000, Sinigaglia and Pink, EMBO J. 1985. 4:3819) show that T cells in infected individuals react with at least 6 different parasite proteins.

Clones of B lymphocytes in individual follicles of the bursa of Fabricius.

To discover whether individual bursal follicles can contain clones of B lymphocytes, we estimated the numbers of lymphoid cell precursors populating single follicles in two types of chicken chimera. The first type was produced by establishing parabiotic connections between blood vessels of embryo chorioallantoic membranes. Under these conditions, and most likely during normal development, most follicles are populated by more than one, but less than ten, precursor cells. However, in a second type of chimera, a cyclophosphamide-treated chick reconstituted with normal bursal cells, most follicles in the reconstituted bursa are clonal (their lymphocytes are derived from a single precursor cell). Individual follicles can readily be isolated from bursae of reconstituted birds and should be useful in studies of B cell development.

A monoclonal antibody recognizes an epitope common to an avian-specific nuclear antigen and to cytokeratins.

X3, a monoclonal antibody of unusual specificity, is described. This antibody reacts with one or more cytokeratin polypeptides and also reacts with an avian (chicken, quail) nuclear antigen that appears to be present in all cell types (chicken) tested, although with variable staining pattern and intensity. This antigen is distinct from the cytokeratins but does have an epitope in common with this class of proteins. It disappears from the nucleus during the early stages of cell division and reappears during anaphase as a granular cytoplasmic structure. In late telophase the antigen is relocated in the nucleus. This antigen, which we have designated as avian-specific nuclear antigen ( AVNA ), is not associated with chromatin or ribonucleoproteins. From immunoblotting experiments on chicken fibroblast nuclei, AVNA is probably a complex composed of one or several polypeptides, one of which has a molecular weight of approximately 60 kD. The proteins were identified as nuclear matrix proteins rather than pore complex-lamina proteins by immunoblotting experiments on the purified nuclear matrix of chicken erythrocytes. The major polypeptide had a molecular weight of 60 kD and the minor polypeptide a molecular weight of 69 kD.

Monoclonal antibody which recognizes a common antigenic determinant on intermediate filament proteins, actin, and myosin.

A monoclonal antibody is described which reacts with the intermediate filament proteins vimentin, desmin, keratins, actin, and myosin. This is the first report of an epitope common to intermediate filament proteins and myosin. X1, the wide-spectrum monoclonal antibody in question, was isolated in the course of screening monoclonal antibodies to chicken thymocytes. Cross-reactivities were investigated by immunofluorescence on various types of cultured cells and sectioned tissues, ELISA with a panel of purified antigens, immunoprecipitation, immunodot tests, and immunoblotting.

Monoclonal antibodies against chicken lymphocyte surface antigens.

Spleen and lymph node cells of BALB/c mice, previously immunized with chicken thymic or bursa cells, were fused with Sp2/0-Ag14 mouse myeloma cells. Hybridomas from two fusions were selected on the basis of reactivity of their secreted antibodies towards thymic or bursal tissues in an indirect immunofluorescence assay. Four monoclonal antibodies reacting with different cell surface proteins of chicken lymphocytes were characterized, as follows. One antibody (IgM X.14) reacted only with cortical thymocytes, and precipitated material of apparent molecular weight (AMW) 65,000 (65 kD), 125 kD, and 180 kD from these cells. A second antibody (IgGl L.17) reacted with both bursa- and thymus-derived lymphocytes, but with different high molecular weight glycoproteins (AMWs 210 kD and 180 kD, respectively) on the two cell types. These proteins may be homologues of the previously described mouse B-220 and T-200 antigens. A third antibody (IgGl L.22) reacted with a protein of AMW 70 kD present on bursa-derived cells of some, but not all, chicken strains. Genetic analysis suggested that the presence of this protein was controlled by a single gene not closely linked to the major histocompatibility complex. A fourth antibody (IgG2b L.43) reacted with bursa-derived cells, macrophages and fibroblasts, but not with thymus-derived lymphocytes. L.43 precipitated material of AMW 23 kD from bursal cells.

Quantitative aspects of the nonspecific humoral immune response to sheep erythrocytes.

The kinetics and magnitude of the nonspecific humoral immune response was studied at the cellular level in mice immunized with sheep erythrocytes (SRBC). Intravenous injection of the antigen evoked, in addition to a specific anti-SRBC response, a nonspecific response of all immunoglobulin (Ig) classes and subclasses. This nonspecific response peaked on day 4 or 5 after immunization, irrespective of the Ig class. The absolute number of nonspecific Ig-secreting cells induced by immunization varied with the different Ig-classes, and it was not proportional to the background level of Ig-secreting cells of the various classes. The nonspecific IgM-IgG1- and IgG2-response was 3 to 4 times as large as the antigen-specific responses of these classes. The nonspecific IgA-response, however, was many times greater.

Immunoglobulin isotype expression. II. Frequency analysis in mitogen-reactive B cells.

The frequency of lipopolysaccharide (LPS)-reactive B cells developing into clones that secrete the various immunoglobulin (Ig) classes has been determined in vitro, in cells from BALB/c mice, under culture conditions which detect all growth-inducible cells. Secretion of the different Ig classes was assessed in the protein A plaque assay for Ig-secreting, plaque-forming cells by using developing antisera specific for either IgM, IgG1, IgG2a, IgG2b, IgG3 or IgA. In all lymphoid organs tested (spleen, bone marrow, mesenteric lymph nodes and thoracic duct), a considerable proportion of all B cells (5-20%) was induced by LPS to yield a clone of IgM-secreting cells. Frequency determinations of LPS-reactive cells giving rise to descendants secreting other Ig isotypes revealed that, on an average, and irrespective of the origin of the cells, 7% of all IgM-secreting clones switched to the synthesis of IgG1, 39% to IgG2, 41% to IgG3 and 1% to IgA. Roughly the same frequencies of B cells switching CH gene expression were found among spleen cells of athymic nude mice. No correlation was found between the clonal frequencies of CH gene expression in polyclonally activated B cells and the in vivo "background" Ig-secreting cells suggesting that the CH gene expression in B cells is influenced by the quality of stimulation and other regulating influences.

Genetic control of lipopolysaccharide-induced mobilization of CFUs. Dissociation between early and delayed mobilization of CFUs in complement C5-deficient mice and LPS non-responder mice.

Lipopolysaccharide (LPS)-induced mobilization of CFUs from haemopoietic tissues into the circulation has a biphasic pattern. The first rise occurs within 30 min of LPS injection, the second 4-7 days later. This second rise coincides with an increase of the CFUs number in the spleen from about 3000 to about 50,000. We have investigated the relationship between the two peaks by making use of complement C5-deficient mouse strains and the LPS non-responder mouse strains C3H/HeJ and C57BL/10ScCr. These latter two strains lack a serologically identifiable structure ('LPS-receptor') which is present in all LPS-responder strains. After injection of eleven different mouse strains with LPS, the numbers of circulating CFUs increased rapidly in all strains, except in the C5-deficient A/J, AKR/J, DBA/2J and B10.D2/oSn mice. On the other hand, the delayed LPS-induced accumulation of CFUs in blood and spleen occurred in all mouse strains tested, including the C5-deficient strains, but not in the LPS non-responder strains C3H/HeJ and C57BL/10ScCr. These results show that (a) early LPS-induced mobilization of CFUs is dependent on the availability of C5, in contrast to the delayed CFUs accumulation in blood and spleen, (b) the presence of the LPS receptor is not required for early CFUs mobilization by LPS and (c) recognition of the mobilizing agent by a specific receptor is required for the delayed accumulation of CFUs in blood and spleen.

Frequency analysis of immunoglobulin V-gene expression and functional reactivities in bone marrow B cells.

Frequency of immunocompetent B cells in bone marrow has been determined in vitro under culture conditions that allow the development in vitro under culture conditions that allow the development of every growth-inducible B cell into a clone of IgM-secreting PFC. Three limiting dilution culture systems were employed: a specific helper assay with SRBC as antigen and using activated T helper cells, a nonspecific helper assay using Con A-induced factors as a source of help, and polyclonal activation with LPS. From unseparated, normal C57BL/6J bone marrow 1 in 2200 to 1 in 2820 B cells were induced to form a clone of PFC to SRBC in each of the 3 systems. This corresponds to a frequency of 1 SRBC-specific clone in every 900 IgM-secreting LPS-reactive clones. The frequencies of specific plaque-forming B cell clones in terms of LPS-reactive B cells was 1 in 36 for NNP1-SRBC, 1 in 58 for TNP30-SRBC, 1 in 75 for NIP1-SRBC, and 1 in 230 for TNP3-SRBC. These frequencies of v-gene expression in bone marrow B cells are of the same magnitude as the corresponding frequencies for splenic B cells. Bone marrow B cells are also fully susceptible to stimulation by antigen in combination with either specific or nonspecific T cell help, as well as polyclonal activation by LPS, since every 3rd Ig-positive cells in marrow could be induced to form a clone of IgM-secreting cells. There is thus no difference in immunocompetence between surface Ig-bearing B cells from bone marrow and spleen.

Glyoxalase I polymorphism in the mouse: a new genetic marker linked to H-2.

Two electrophoretically distinct variants of glyoxalase I (Glo-I) are present in mouse (Mus musculus). The two forms are controlled by two codominant alleles Glo-1a (common) and Glo-1b (rare) at an autosomal locus. A linkage study showed that Glo-1 maps at approximately 3 centimorgans from the Ss locus of the H-2 histocompatibility region. A similar linkage relationship exists in man between GLO and HLA, the human homolog of the H-2 gene complex. Thus, the chromosomal segment evolutionarily preserved in the two species is longer than previously suspected, and it includes genes with no obvious functional relation to the other components of the major histocompatibility complex. Several features of the Glo-1 polymorphism in the mouse recommend it as a marker of choice for the H-2 region.