Involvement of protein kinase C-delta in CD28-triggered cytotoxicity mediated by a human leukaemic cell line YT

Nature's bounty - drug discovery from the sea

With ∼ 40 years of research completed after the development of self-contained underwater breathing apparatus, drug discovery opportunities in the sea are still too numerous to count. Since the FDA approval of the direct-from-the-sea calcium channel blocker ziconotide, marine natural products have been validated as a source for new medicines. However, the demand for natural products is extremely high due to the development of high-throughput assays and this bottleneck has created the need for an intense focus on increasing the rate of isolating and elucidating the structures of new bioactive secondary metabolites. In addition to highlighting the drug discovery potential of the marine environment, this review discusses several of the pressing needs to increase the rate of drug discovery in marine natural products, and describes some of the work and new technologies that are contributing in this regard.

Costimulation of T cell receptor-triggered IL-2 production by Jurkat T cells via fibroblast growth factor receptor 1 upon its engagement by CD56

Recent studies have demonstrated that neural cell adhesion molecule (NCAM) is involved in multiple adhesive interactions with several different classes of ligands on the cell surface and in the extracellular matrix. One of these ligands is fibroblast growth factor receptor (FGFR) that is expressed on neural cells. While it is known that CD56 is a molecular isoform of NCAM expressed on human NK cells and a subset of T cells, it remains poorly characterized, with its ligand unidentified. Therefore, we were prompted to examine if CD56 molecules on NK cells interact with FGFR expressed on T cells. We demonstrate that ligation of FGFR1 beta on J.C2-14 Jurkat T cells by CD56 on fixed NK-92 cells costimulates TCR/CD3-triggered IL-2 production. CD56-binding mAbs inhibited the costimulatory effect of NK-92 cells in 50-75%. Flow cytometric analysis and cell adhesion assays showed that FGFR1 beta/Fc and FGFR2 beta/Fc chimeric proteins bind to NK-92 cells. The binding of FGFR1 beta/Fc protein to CD56 molecules was verified by immunoprecipitation of CD56 with anti-CD56 mAb followed by Western blotting with FGFR1 beta/Fc. These findings suggest that ligation of FGFR1 by CD56 may contribute to the interaction between NK cells and T cells that we have postulated in our previous studies.

Inhibition of CD28-mediated natural cytotoxicity by KIR2DL2 does not require p56(lck) in the NK cell line YT-Indy

CD28 functions as a cytotoxicity activation receptor in the NK cell line YT-Indy. To analyze the requirement of p56(lck) kinase in the function of killer inhibitory receptors, we transfected the p56(lck) negative YT-Indy cell line with the cl43 gene encoding for KIR2DL2. Pervanadate treatment revealed KIR2DL2 phosphorylation in YT-Indy-cl43, as well as SHP1/SHP2 recruitment. YT-Indy-cl43 cells were inhibited in their ability to lyse target cells expressing HLA-Cw3, a ligand for KIR2DL2. This inhibition was blocked by anti-KIR2DL2 or anti-HLA class I mAb. CD28 crosslinking on YT-Indy-cl43 enhanced tyrosine phosphorylation of PLC-gamma1. The simultaneous ligation of KIR2DL2 with mAb resulted in a decrease in CD28-induced tyrosine phosphorylation of PLC-gamma1 confirming that dephosphorylation of this protein is involved in the KIR2DL2-induced inhibition of CD28-mediated cytotoxicity. As YT-Indy-cl43 did not express detectable levels of p56(lck), these results indicate that this kinase is not required for transmitting the negative signals generated by KIR2DL2 ligation.

Protective role of IL-2 during activation of T cells with bryostatin 1

Pharmacologic agents such as bryostatin 1 (bryostatin) can regulate cell activation, growth, and differentiation by modulating the activities of protein kinase C isoenzymes. Inhibition of growth of tumor cells and activation of T lymphocytes in vitro are the most recognized consequences of bryostatin treatment. The effect of bryostatin on T cells ranges from induction of apoptotic cell death to T cell activation, expansion, and acquisition of antigen-specific effector functions. Here, we describe the conditions under which these wide ranging effects occur. Mouse mammary tumor 4TO7-IL-2-primed lymph node cells exposed ex vivo to bryostatin upregulated CD25 expression but lost the ability to secrete IL-2. Most of these cells died by apoptosis unless IL-2 was provided for the duration of bryostatin treatment. Analysis of T cell repertoire by screening of T cells for the expression of different Vbeta T cell receptor (TCR) families revealed that bryostatin-induced T cell death was unbiased and Vbeta-nonspecific. Within particular Vbeta clones, only CD25(+) T cells survived exposure to bryostatin and IL-2. Treatment of 4TO7 tumor-bearing mice with a single injection of low dose bryostatin followed by multiple low doses of IL-2, but not with bryostatin alone, delayed tumor growth. These results indicate that activation of T cells with bryostatin should be carried out under protection of exogenous IL-2 to ensure survival and expansion of T cells that may exhibit anti-tumor activity.