Heparinase treatment of bovine smooth muscle cells inhibits fibroblast growth factor-2 binding to fibroblast growth factor receptor but not FGF-2 mediated cellular proliferation

On the surface of smooth muscle cells there are two types of receptors for the mitogenic and angiogenic growth factor fibroblast growth factor-2 (FGF-2); a high affinity tyrosine kinase FGF receptor (FGFR1) and low affinity heparin./heparan-like glycosaminoglycan (HLGAG) component of surface expressed proteoglycans. It is believed that all three components; FGFR1, FGF-2, and the HLGAG chains, must form a ternary complex for maximal cellular stimulation. To carefully examine the role surface HLGAGs play in FGF-2-mediated proliferation of SMCs we have utilized HLGAG degrading enzymes heparinase I, II and III. We report that heparinase treatment of bovine smooth muscle cells inhibits the binding of (125)I-FGF-2 to FGFR1, but does not inhibit FGF-2 induced cellular proliferation. Through the use of both sodium chlorate and FGF-2 mutants with deficient HLGAG-binding capabilities, we show the FGF-2-HLGAG interaction is important for FGF-2's ability to induce SMC proliferation. Finally, we report conditioned media from heparinase treated SMCs is capable of supporting FGF-2 induced proliferation in an HLGAG-free lymphoid F32 cells, suggesting that the heparinase generated fragments are responsible for the proliferative response. The data presented here suggest FGF-2 is capable of stimulating smooth muscle cell proliferation through an FGFR independent, HLGAG dependent mechanism.

Conservation of structure and function between human and murine IL-16

IL-16 is a proinflammatory cytokine that signals via CD4, inducing chemotactic and immunomodulatory responses of CD4+ lymphocytes, monocytes, and eosinophils. Comparative analysis of murine and human IL-16 homologs could reveal conserved structures that would help to identify key functional regions of these cytokines. To that end, we cloned the murine IL-16 cDNA and found a high degree of amino acid similarity comparing the predicted murine and human IL-16 precursor proteins (pro-IL-16). The highest similarity (82.1%) was found in the C-terminal region, which is cleaved from pro-IL-16 to yield biologically active IL-16. Chemotaxis experiments with IL-16 of murine and human origin, using murine splenocytes or human T lymphocytes as targets, showed cross-species stimulation of motility. Synthetic oligopeptides and anti-peptide Ab were produced, based on the sequences of three predicted hydrophilic domains of IL-16 potentially presented in exposed positions. None of these peptides had intrinsic IL-16 bioactivity, but one (corresponding to a hydrophilic C-terminal domain of IL-16) partially displaced binding of OKT4 mAb to human lymphocytes. This peptide, and its cognate Ab, also inhibited IL-16 chemoattractant activity for human and murine cells. These studies demonstrate a high degree of structural and functional similarity between human and murine IL-16 and suggest that amino acids in the C terminus are critical for its chemoattractant function. The data suggest cross-species conservation of IL-16 receptor structures as well. Inhibitory peptides may be useful in disease states where the proinflammatory functions of IL-16 are detrimental to the host.

Molecular and functional analysis of a lymphocyte chemoattractant factor: association of biologic function with CD4 expression

Lymphocyte chemoattractant factor (LCF) is a lymphocyte cell product that stimulates a migratory response in CD4+ lymphocytes, monocytes, and eosinophils. In concert with its chemoattractant activity, LCF induces human T-lymphocyte expression of interleukin 2 receptor. Here we describe the molecular cloning of cDNA encoding human LCF. It is a novel interleukin with no significant homology to any previously described cytokine families. There is an absolute requirement for both autoaggregation of LCF monomers and for membrane-expressed CD4 molecules for LCF-induced migration in lymphocytes.