David Moscatelli

THE FGF FAMILY OF GROWTH FACTORS AND ONCOGENES

Publisher Summary The family of fibroblast growth factors (FGF) is the largest family of growth factors involved in soft–tissue growth and regeneration. The FGF family includes seven members that share a varying degree of homology at the protein level and appear to have a similar broad mitogenic spectrum. They are angiogenic and promote the proliferation of a variety of cells of mesodermal and neuroectodermal origin . Three members of the family–namely, K–FGF/HST, FGF–5, INT–2 are identified originally as oncogenes, while two additions, FGF–6 and keratinocyte growth factor (KGF), are isolated by sequence homology or factor purification and cloning. FGF was identified as an activity in pituitary extracts that stimulated the proliferation of 3T3 cells in mice. The two prototypes of basic and acidic protein structure, the FGF genes, and the expressions of FGF are also discussed. FGF consist of three exons, separated by two introns of variable length and FGF genes map on several chromosomes. The molecular regulation of FGF expression, FGF receptors, and their interaction with extracellular matrix is described. The oncogenic potential of FGF members and their involvement in tumors is also discussed. All possible mechanisms operating on the expression of FGFs and their receptors: transcriptional controls, posttranscriptional regulation involving alternative splicing, alternative translation starts resulting in proteins with different properties, and control affecting the secretion of these proteins are discussed.

In vitro neurite extension by granule neurons is dependent upon astroglial-derived fibroblast growth factor

When grown in the absence of astroglial cells, purified mouse cerebellar granule neurons survive less than 36 hr and do not extend neurites. Here we report that low concentrations of basic fibroblast growth factor (bFGF, 1-25 ng/ml) maintained the viability and promoted the differentiation of purified granule neurons. The effect of bFGF on granule cell neurite outgrowth was dose dependent. Neurite outgrowth was stimulated markedly in the presence of 1-25 ng/ml bFGF, but effects were not seen below 1 ng/ml or above 50 ng/ml. When affinity-purified antibodies against bFGF (1-5 micrograms/ml) were added either to purified granule cells or to co-cultures of neurons and astroglial cells, process extension by granule neurons was severely impaired. The inhibition of neurite outgrowth in the presence of anti-bFGF antibodies was reversed by the addition of 25 ng/ml of exogenous bFGF. In addition to neuronotrophic effects, bFGF influenced the rate of growth of the astroglial cells. This result depended on whether the astroglia were grown in isolation from neurons, where low doses of bFGF (10-25 ng) stimulated glial growth, or in coculture with neurons, where much higher doses of bFGF (100-250 ng/ml) were needed for glial mitogenesis. Immunoprecipitation of lysates from 35S-labeled cerebellar astroglial cells with anti-bFGF antibodies revealed a single band after SDS-PAGE at 18,000 Da, the molecular weight of bFGF. These results indicate that glial cells synthesize bFGF and are possibly an endogenous source of bFGF in cerebellar cultures. Thus, astroglial cells synthesize soluble factors needed for neuronal differentiation.

Proximal location of mouse prostate epithelial stem cells: a model of prostatic homeostasis

Stem cells are believed to regulate normal prostatic homeostasis and to play a role in the etiology of prostate cancer and benign prostatic hyperplasia. We show here that the proximal region of mouse prostatic ducts is enriched in a subpopulation of epithelial cells that exhibit three important attributes of epithelial stem cells: they are slow cycling, possess a high in vitro proliferative potential, and can reconstitute highly branched glandular ductal structures in collagen gels. We propose a model of prostatic homeostasis in which mouse prostatic epithelial stem cells are concentrated in the proximal region of prostatic ducts while the transit-amplifying cells occupy the distal region of the ducts. This model can account for many biological differences between cells of the proximal and distal regions, and has implications for prostatic disease formation.

Purification from a human hepatoma cell line of a basic fibroblast growth factor-like molecule that stimulates capillary endothelial cell plasminogen activator production, DNA synthesis, and migration.

A 17,500-dalton protein which stimulates plasminogen activator production in cultured bovine capillary endothelial cells has been purified from a SK-Hep-1 human hepatoma cell lysate by using heparin affinity chromatography and fast protein-liquid ion exchange chromatography. The purified molecule stimulated plasminogen activator production in a dose-dependent manner between 0.01 and 1 ng/ml. It also stimulated collagenase synthesis, DNA synthesis, and motility in capillary endothelial cells in the same concentration range. This molecule was identified as a basic fibroblast growth factor-like molecule on the basis of its biological activity, its affinity for heparin-Sepharose, and its cross-reactivity with a polyclonal antibody raised against the human placental basic fibroblast growth factor.

Processing, secretion, and biological properties of a novel growth factor of the fibroblast growth factor family with oncogenic potential.

We recently reported that the protein encoded in a novel human oncogene isolated from Kaposi sarcoma DNA was a growth factor with significant homology to basic and acidic fibroblast growth factors (FGFs). To study the properties of this growth factor (referred to as K-FGF) and the mechanism by which the K-fgf oncogene transforms cells, we have studied the production and processing of K-FGF in COS-1 cells transfected with a plasmid encoding the K-fgf cDNA. The results show that, unlike basic and acidic FGFs, the K-FGF protein is cleaved after a signal peptide, glycosylated, and efficiently secreted as a mature protein of 176 or 175 amino acids. Inhibition of glycosylation impaired secretion, and the stability of the secreted K-FGF was greatly enhanced by the presence of heparin in the cultured medium. We have used the conditioned medium from transfected COS-1 cells to test K-FGF biological activity. Similar to basic FGF, the K-FGF protein was mitogenic for fibroblasts and endothelial cells and induced the growth of NIH 3T3 mouse cells in serum-free medium. Accordingly, K-fgf-transformed NIH 3T3 cells grew in serum-free medium, consistent with an autocrine mechanism of growth. We have also expressed the protein encoded in the K-fgf protooncogene in COS-1 cells, and it was indistinguishable in its molecular weight, glycosylation, secretion, and biological activity from K-FGF. Taken together, these results suggest that the mechanism of activation of this oncogene is due to overexpression rather than to mutations in the coding sequences.

Tetradecanoyl phorbol acetate stimulates latent collagenase production by cultured human endothelial cells

Abstract Angiogenesis is associated with the fragmentation of blood vessel basement membranes. Since collagen is a major constituent of basement membranes, cultured human endothelial cells derived from umbilical cord veins were assayed for their ability to produce collagenase. Unstimulated cultured human endothelial cells did not secrete detectable levels of active collagenase into the culture medium. However, if the post-culture medium was treated with trypsin or plasmin, low levels of collagenolytic activity were detected, indicating that endothelial cells secrete small amounts of latent collagenase. Addition of the tumor promoter 12-O-tetradecanoyl phorbol-13-acetate (TPA) to the culture medium stimulated the secretion of collagenase by endothelial cells 5–30 fold. More than 90% of the collagenase was secreted in the latent form. Stimulation of collagenase production was detected at 10 −9 M TPA and was maximal at 10 −8 M TPA. An increase in the rate of collagenase production could be detected within 3 hr after the addition of TPA, and full induction occurred by 12 hr. Cycloheximide (3 μg/ml) or actinomycin D (0.1 μg/ml) inhibited both basal levels of collagenase production and the stimulation of collagenase production by TPA. Phorbol-12,13-didecanoate (PDD), a tumor-promoting analog of TPA, also stimulated collagenase production when administered at the same concentrations that were effective for TPA. However, 4-O-methyl TPA and 4-αPDD, two analogs of TPA which are not tumor promoters, did not stimulate collagenase production at concentrations up to 10 −7 M. The collagenase produced by endothelial cells was a typical vertebrate collagenase as judged by the following criteria: it cleaved collagen into only two fragments which were three quarters and one quarter of the length of the intact molecule; it was inhibited by EDTA and human serum; it was not inhibited by inhibitors of serine, thiol or aspartate proteases. Thus TPA causes an increase in the production of latent collagenase by cultured human endothelial cells.

High Aldehyde Dehydrogenase Activity: A Novel Functional Marker of Murine Prostate Stem/Progenitor Cells

We have shown previously that prostatic stem/progenitor cells can be purified from isolated prostate ducts, based on their high expression of the Sca‐1 surface antigen. We now report that high levels of aldehyde dehydrogenase (ALDH) activity are present in a subset of prostate epithelial cells that coexpress a number of antigens found on stem/progenitor cells of other origins (CD9, Bcl‐2, CD200, CD24, prominin, Oct 3/4, ABCG2, and nestin). Almost all of these cells expressing high levels of ALDH activity also express Sca‐1 and a third of them express high levels of this antigen. The cells with high levels of ALDH activity have greater in vitro proliferative potential than cells with low ALDH activity. Importantly, in an in vivo prostate reconstitution assay, the cells expressing high levels of ALDH activity were much more effective in generating prostatic tissue than a population of cells with low enzymatic activity. Thus, a high level of ALDH activity can be considered a functional marker of prostate stem/progenitor cells and allows for simple, efficient isolation of cells with primitive features. The elucidation of the role of ALDH in prostate stem/progenitor cells may lead to the development of rational therapies for treating prostate cancer and benign prostatic hyperplasia. STEM CELLS 2009;27:2220–2228

Lack of ERK activation and cell migration in FGF-2-deficient endothelial cells

The formation of blood capillaries from preexisting vessels (angiogenesis) and vascular remodeling secondary to atherosclerosis or vessel injury are characterized by endothelial cell migration and proliferation. Numerous growth factors control these cell functions. Basic fibroblast growth factor (FGF‐2), a potent angiogenesis inducer, stimulates endothelial cell proliferation, migration, and proteinase production in vitro and in vivo. However, mice genetically deficient in FGF‐2 have no apparent vascular defects. We have observed that endothelial cell migration in response to mechanical damage in vitro is accompanied by activation of the extracellular signal‐regulated kinase (ERK) pathway, which can be blocked by neutralizing anti‐FGF‐2 antibodies. Endothelial cells from mice that are genetically deficient in FGF‐2 neither migrate nor activate ERK in response to mechanical wounding. Addition of exogenous FGF‐2 restores a normal cell response, which shows that impaired migration results from the genetic deficiency of this growth factor. Injury‐induced ERK activation in endothelial cells occurs only at the edge of the wound. In addition, FGF‐2‐induced ERK activation mediates endothelial cell migration in response to wounding without a significant effect on proliferation. These data show that FGF‐2 is a key regulator of endothelial cell migration during wound repair.

TGF-β maintains dormancy of prostatic stem cells in the proximal region of ducts

We have previously shown that prostatic stem cells are located in the proximal region of mouse prostatic ducts. Here, we show that this region responds differently to transforming growth factor (TGF)-β than the distal ductal region and that under physiological conditions androgens and TGF-β are crucial overall regulators of prostatic tissue homeostasis. This conclusion is supported by the observations showing that high levels of TGF-β signaling are present in the quiescent proximal region of ducts in an androgen-replete animal and that cells in this region overexpress Bcl-2, which protects them from apoptosis. Moreover, androgen ablation reverses the proximal-distal TGF-β signaling gradient, leading to an increase in TGF-β signaling in the unprotected distal region (low Bcl-2 expression). This reversal of TGF-β–mediated signaling accompanies apoptosis of cells in the distal region and gland involution after androgen withdrawal. A physiological TGF-β signaling gradient (high proximally and low distally) and its functional correlates are restored after androgen replenishment. In addition to highlighting the regulatory role of androgens and TGF-β, these findings may have important implications for the deregulation of the stem cell compartment in the etiology of proliferative prostatic diseases.

Growth factor control of extracellular proteolysis

The involvement of proteases and growth factors in angiogenesis is complex. The angiogenic factor basic fibroblast growth factor (bFGF) induces increased synthesis of both plasminogen activator and collagenase in endothelial cells. In addition, bFGF increases the number of plasminogen activator receptors on the cell surface. Increased production of plasmin may be responsible for the release of soluble complexes of heparan sulfate-bFGF which may be the active form of bFGF. The activity of a negative regulator of angiogenesis, transforming growth factor beta (TGF-beta), is also regulated by proteases since the released latent form of TGF-beta is activated by a surface proteolytic assembly plasminogen activator and plasmin. Since TGF-beta induces an inhibitor of plasminogen activator, the activation reaction is self-regulatory.