Gary M. Fox

GDNF-induced activation of the ret protein tyrosine kinase is mediated by GDNFR-α, a novel receptor for GDNF

We report the expression cloning and characterization of GDNFR-alpha, a novel glycosylphosphatidylinositol-linked cell surface receptor for glial cell line-derived neurotrophic factor (GDNF). GDNFR-alpha binds GDNF specifically and mediates activation of the Ret protein-tyrosine kinase (PTK). Treatment of Neuro-2a cells expressing GDNFR-alpha with GDNF rapidly stimulates Ret autophosphorylation. Ret is also activated by treatment with a combination of GDNF and soluble GDNFR-alpha in cells lacking GDNFR-alpha, and this effect is blocked by a soluble Ret-Fc fusion protein. Ret activation by GDNF was also observed in cultured embryonic rat spinal cord motor neurons, a cell type that responds to GDNF in vivo. A model for the stepwise formation of a GDNF signal-transducing complex including GDNF, GDNFR-alpha, and the Ret PTK is proposed.

GFRalpha-2 and GFRalpha-3 are two new receptors for ligands of the GDNF family.

The receptor for glial cell line-derived neurotrophic factor (GDNF) consists of GFRα-1 and Ret. Neurturin is a GDNF-related neurotrophin whose receptor is presently unknown. Here we report that neurturin can bind to either GFRα-1 or GFRα-2, a novel receptor related to GFRα-1. Both GFRα-1 and GFRα-2 mediate neurturin-induced Ret phosphorylation. GDNF can also bind to either GFRα-1 or GFRα-2, and activate Ret in the presence of either binding receptor. Although both ligands interact with both receptors, cells expressing GFRα-1 bind GDNF more efficiently than neurturin, while cells expressing GFRα-2 bind neurturin preferentially. Cross-linking and Ret activation data also suggest that while there is cross-talk, GFRα-1 is the primary receptor for GDNF and GFRα-2 exhibits a preference for neurturin. We have also cloned a cDNA that apparently codes for a third member of the GFRα receptor family. This putative receptor, designated GFRα-3, is closely related in amino acid sequence and is nearly identical in the spacing of its cysteine residues to both GFRα-1 and GFRα-2. Analysis of the tissue distribution of GFRα-1, GFRα-2, GFRα-3, and Ret by Northern blot reveals overlapping but distinct patterns of expression. Consistent with a role in GDNF function, the GFRαs and Ret are expressed in many of the same tissues, suggesting that GFRαs mediate the action of GDNF family ligands in vivo.

Binding of heparin to basic fibroblast growth factor induces a conformational change.

The binding of heparin to basic fibroblast growth factor (bFGF) induces a small but highly reproducible conformational change observable in the amide I region of the proteins infrared spectrum. The observed spectral changes suggest that the conformational change is highly localized most likely in the beta-turn regions of the bFGF molecule. Heparan sulfate, a component of the endothelial extracellular matrix, was also observed to bind to bFGF and induce a similar conformational change to that observed for heparin. Further, sucrose octasulfate, a compound which mimics the effects of heparin biologically, was also observed to induce this same conformational change. This spectroscopically observable change has allowed us to probe the functional determinants necessary for heparin to bind the bFGF and to induce the observed conformational change. We have determined the effects of binding of various monomeric and polymeric, sulfated and nonsulfated glycosaminoglycans and carbohydrate compounds. The results indicate that the binding of heparin involves highly specific interactions. Further, heparin was observed to greatly increase the thermal stability of bFGF, raising the Tm by 25 degrees C. Sucrose octasulfate was also able to enhance the thermal stability of bFGF, but not to the same extent as heparin.

Monkey erythropoietin gene: cloning, expression and comparison with the human erythropoietin gene

The erythropoietin (Epo) gene from Cynomolgus monkeys has been isolated from a kidney cDNA library using mixed 20-mer oligodeoxynucleotide probes. The gene encodes a 168 amino acid (aa) mature protein with a calculated Mr of 18,490 and a presumptive signal peptide of 24 aa. The Epo gene, when transfected into Chinese hamster ovary (CHO) cells, produces a glycosylated protein with an apparent Mr of 34,000. The expressed product is biologically active in vivo. The monkey gene exhibits 92% and 94% homology to the human gene at the aa and nucleotide sequence levels, respectively. When compared with the human Epo, monkey Epo has an additional 3-aa residue at the N terminus of the mature protein and a deletion of an internal lysine residue.

Characterization of a cysteine-free analog of recombinant human basic fibroblast growth factor

Using oligo site-directed mutagenesis, we have modified our synthetic gene for human basic fibroblast growth factor (bFGF) to replace all four cysteine codons with serine codons. The corresponding protein was expressed in Escherichia coli and purified from inclusion bodies by solubilization in urea followed by a series of column chromatographies and a folding step. The resulting protein, having no cysteine residues, is unable to form either intramolecular or intermolecular disulfide bonds. The secondary and tertiary structures of the purified analog, as determined by circular dichroism and fluorescence spectroscopy, were identical within experimental error to recombinant bovine and human bFGF with unaltered amino acid sequences. Reflecting the similar conformation, the analog protein exhibited mitogenic activity on NIH 3T3 cells which was indistinguishable from the natural sequence molecule.

The importance of Arg40 and 45 in the mitogenic activity and structural stability of basic fibroblast growth factor: Effects of acidic amino acid substitutions

High-affinity binding of basic fibroblast growth factor (bFGF) to the tyrosine kinase receptor requires cell-surface heparan sulfate proteoglycan or exogenous addition of heparin. The crystal structure of bFGF shows Arg40 and 45 on the surface opposite to the heparin-binding region, suggesting that these charged residues may be involved in the receptor binding. Therefore, these amino acids were mutated to aspartic acid separately or simultaneously, and also a simultaneous mutation to glutamic acid was introduced. These mutants displayed a mitogenic activity decreased greater than tenfold compared to the wild-type protein. Addition of heparin had no effect on the activity, while these mutants showed heparin-binding characteristics resembling those of the native sequence protein. The mutants exhibited decreased stability compared to the native sequence protein. Gradual changes in conformation were observed by circular dichroic and infrared spectroscopy. Heparin chromatography also showed the presence of denatured form for these mutants. However, in the presence of multivalent anions such as citrate, sucrose octasulfate, and heparin, the conformation of the mutants resembled that of the wild-type protein, as revealed by X-ray crystallography and circular dichroism spectra of the mutant with a Arg40 → Asp substitution.

The Role of Growth Factors in Tissue Repair III

Fibroblast growth factor (FGF) was first described by Gospodarowicz and co-workers as an activity derived from bovine brain or pituitary tissue (Gospodarowicz, 1974). As the name suggests, FGF was found to be mitogenic for fibroblasts in culture as well as endothelial cells and several other types of mesoderm-derived cells. It was first believed that FGF resulted from the degradation of myelin basic protein (Westall et al., 1978), but this was later found not to be the case (Thomas et al., 1980). Further characterization of the activity revealed that the primary mitogen from brain was different than that isolated from pituitary. These two factors were named acidic and basic FGF because they had similar if not identical biologic activities but differed in their iso-electric points.