Working with dangerous bugs.

As part of the national effort in the US to protect civilians from bioterrorist attacks, the US National Institute of Allergy and Infectious Diseases (NIAID) was charged with the development of diverse research resources. The NIAID Resources for Biodefense Research program is forging new collaborations between immunologists and infectious disease experts and is reinvigorating research in the general area of immune protection against pathogenic infection.

Altered CD40 ligand induction in tolerant T lymphocytes.

CD40 ligand (CD40L) is a member of the tumor necrosis factor superfamily and is expressed on the surface of activated T lymphocytes. The interaction of CD40L with CD40 on B cells results in B cell activation, immunoglobulin (Ig) secretion and Ig class switching. To study anergy as a mechanism of murine CD4 T cell tolerance, we determined both in vivo and in vitro that CD3-activated anergic cells are deficient in the ability to stimulate B cell proliferation, and that anergic cells are defective for the T cell receptor/CD3-mediated induction of CD40L expression.

Induction of interleukin 12 responsiveness is impaired in anergic T lymphocytes.

The cytokine, interleukin 12 (IL-12), stimulates both natural killer cells and T cells to proliferate and to secrete interferon gamma (IFN-gamma). The T cell proliferative response to IL-12 must be induced and is evident after T cell receptor-mediated stimulation. As reported here, tolerant CD4+ T cells and clones, that are anergic for IL-2 production, are also anergic for induction of the proliferative response to IL-12.

Reduced CD3-mediated protein tyrosine phosphorylation in anergic CD4+ and CD8+ T cells.

Mice inoculated i.v. with superantigens exhibit long lived Ag-specific T cell tolerance.

Altered protein tyrosine phosphorylation in anergic Th1 cells.

Clonal anergy as a mechanism for tolerance in T lymphocytes can be studied using an in vitro culture system, in which cloned CD4+ Th1-type murine T cells are rendered anergic for IL-2 transcription. The long-lasting molecular changes in anergic cells that prevent the response to Ag restimulation are not yet known. To determine whether the TCR might be uncoupled from normal intracellular signaling pathways, we investigated the response of anergic T cells to Ag, to anti-CD3 antibodies, or to anti-CD4 antibody restimulation in terms of early protein tyrosine phosphorylation events.

A recessive defect in lymphocyte or granulocyte function caused by an integrated transgene.

A line of transgenic mice has been identified with a recessive defect in lymphocyte or granulocyte function, presumably as a result of insertional mutagenesis by the integrated transgene. Transgenic mice homozygous for the transgene integrant showed nearly complete absence of lymphocytes in peripheral lymph nodes and Peyer's patches, a severely diminished thymus medulla, and a greatly enlarged spleen. These animals also developed a syndrome characterized by granulocyte and mononuclear infiltrates in numerous tissues, including skin, liver, and lung, and immunoglobulin deposits in kidney glomeruli.

Anergic Th1 cells express altered levels of the protein tyrosine kinases p56lck and p59fyn.

Tolerance in T lymphocytes can result from clonal anergy, or paralysis, of Ag-specific T cells. To investigate the molecular mechanisms responsible for anergy, a system in which tolerance can be induced in vitro was employed. Anergy, as defined by long-lived nonresponsiveness to normal antigenic stimulation for IL-2 production, was produced in cloned murine CD4+ Th1 cells.

Suppression of antibody synthesis by CD4+ T cell clones and normal T cells stimulated with monoclonal anti-CD3 antibody.

CD4+ve Th1 clones, as well as normal splenic T cells, were found to suppress LPS-driven antibody secretion in a non-Ag-specific and non-MHC-restricted manner when the T cells were activated with the anti-CD3 mAb, 145-2C11. Suppression was observed with both primed and naive B cells, as well as with purified hapten-specific B cells, a result that suggests a direct effect of anti-CD3-activated T cells on B cell differentiation. Th1 clones activated by cognate Ag also suppressed LPS-driven antibody secretion.

Synergistic activation of granulocyte-macrophage colony-stimulating factor production by IL-1 and IL-2 in murine Th1 cells.

Recent reports indicate that murine CD4+ Th1-type cloned T cells are insensitive to IL-1 because specific IL-1R are not detected on these cells and IL-1 does not modulate proliferative responses. However, we have determined that Th1 clones can respond to IL-1, because they function synergistically with IL-2 to induce granulocyte-macrophage-CSF secretion. This response to IL-1 plus IL-2 could be induced by IL-1 alpha or IL-1 beta and by membrane-bound IL-1 on macrophages.

Characterization of two major populations of lung fibroblasts: distinguishing morphology and discordant display of Thy 1 and class II MHC.

We have determined that murine lung fibroblasts are divisible into two major subpopulations based on expression of Thy 1. Twenty-four to fifty-three percent of freshly isolated lung cells displayed Thy 1 and were separated using FACS into Thy 1+ and Thy 1- fractions for morphologic examination. Analysis by electron microscopy revealed that both the Thy 1+ and Thy 1- fractions contained fibroblasts.

Prostaglandin E2-dependent induction of granulocyte-macrophage colony-stimulating factor secretion by cloned murine helper T cells.

PG are known to inhibit T cell proliferation, at least in part by suppressing IL-2 production, but effects of PG on the production of other lymphokines have not been well studied. We have found that PGE2 and PGE1, but not PGF2 alpha, inhibit both proliferation and production of granulocyte-macrophage (GM)-CSF by murine TH clones stimulated with Ag or anti-CD3 antibody. Thus, signals generated via the Ag receptor:CD3 complex were inhibited by PGE.

Stimulation of normal inducer T cell clones with antigen presented by purified Ia molecules in planar lipid membranes: specific induction of a long-lived state of proliferative nonresponsiveness.

Culture of normal inducer T cell clones with antigen and purified Ek beta:Ek alpha incorporated into planar lipid membranes resulted in specific T cell activation as determined by cell volume increase and IL 3 production. However, in contrast to results obtained with T cell hybridomas, antigen presentation by planar membranes did not induce measurable IL 2 production, and proliferative responses were not detected. Rather, recognition of only Ek beta:Ek alpha and antigen resulted in the specific induction of a long-lived state of proliferative nonresponsiveness to subsequent stimulation by conventional APC and antigen.

Quantitative analysis of the T cell response to antigen and planar membranes containing purified Ia molecules.

Planar lipid membranes containing the purified Ia molecule E beta k:E alpha k can present a peptide antigen derived from cytochrome c to the T cell hybridoma 2B4.11. The incorporation of E beta k:E alpha k into planar membranes was linear over a 120-fold range of Ia molecule concentrations, permitting the dependence of the T cell response on the Ia molecule concentration to be examined.

Optimization of antigen presentation to T cell hybridomas by purified Ia molecules in planar membranes. Ia molecule polymorphism determines the antigenic fine specificity of the response to cytochrome c peptides.

Ia molecule (Ek,b beta:Ek alpha or Ak beta:Ak alpha)-containing planar membranes were constructed with cholesterol and a 9:1 molar ratio of the phospholipids dipalmitoyl phosphatidylcholine and dilinoleoyl phosphatidylcholine. This lipid composition was found to be optimal for the stimulation of T cell hybridomas of different specificities. Use of this system allowed the detection of weak responses not measurable when other artificial membranes were used.

Ek beta mutant antigen-presenting cell lines expressing altered Ak alpha molecules.

Antigen-presenting cells (APC) expressing mutant Ek beta and Ak alpha proteins were isolated after chemical mutagenesis of TA3 cells and negative immunoselection for altered Ek beta molecules. Mutant clones were analyzed for biosynthesis, assembly, and cell surface expression of altered Ia molecules, and were assayed for antigen-presenting function by using a variety of T cell clones. Three types of mutants were detected: type 1, which had lost expression of the Ek beta chain and produced altered Ak alpha chains; type 2, which also expressed altered Ak alpha chains, and which expressed Ek beta proteins that had lost reactivity to the 17.

Unexpected expression of a unique mixed-isotype class II MHC molecule by transfected L-cells.

Class II (Ia) major histocompatibility complex (MHC) molecules are heterodimeric integral membrane proteins composed of non-covalently linked alpha and beta glycoprotein chains. Studies of both normal cells and L-cell transfectants have shown that neither alpha- nor beta-chains are found on the cell surface alone, and that alpha beta dimers are required for membrane expression. In both mouse and man, several distinct non-allelic alpha and beta genes exist.

Influence of allelic polymorphism on the assembly and surface expression of class II MHC (Ia) molecules.

Cell surface Ia expression was examined following transfection of murine alpha and beta class II major histocompatibility complex (MHC) genes into L cells. Although haplotype-matched (e.g.

Comparison and partial characterization of guinea pig Ia alpha- and beta-chain oligosaccharides.

The structures of the N-linked oligosaccharides of mature guinea pig Ia molecules were partially characterized by serial lectin affinity analysis. Those Ia antigens that are thought to be allelic products (Ia.3,5 and Ia.

Subunit structure of guinea pig Ia.1 antigens.

Since their discovery in 1976, the guinea pig Ia.1 and Ia1,6 antigens were thought to be borne on a single protein species of approximately 26,000 m.w.