Enhanced MYCN oncogene expression in human neuroblastoma cells is associated with altered FGF receptor expression and cellular growth response to basic FGF.

We have examined the effect of human basic fibroblast growth factor (bFGF) on the proliferation of human neuroblastoma cells with normal and enhanced MYCN oncogene expression. bFGF stimulated the proliferation of the neuroblastoma cells with enhanced, but not normal, MYCN expression. Both cell species express FGFR-1, but not FGFR-2, receptors and both harbor FGF receptor species of Mr 145.000, but they differ in their pattern of lower and higher-molecular weight FGF receptor species. Our results demonstrate that enhanced MYCN expression confers to neuroblastoma cells the ability to respond to bFGF, possibly by inducing functional FGF receptors. This mechanism may contribute to the advanced malignant phenotype of human neuroblastomas with enhanced MYCN expression.     

Targeted expression of a dominant-negative FGF receptor mutant in the epidermis of transgenic mice reveals a role of FGF in keratinocyte organization and differentiation.

In this study we used a dominant-negative FGF receptor mutant to block FGF function in a specific tissue of transgenic mice. The mutant receptor, which is known to block signal transduction in cells when co-expressed with wild-type receptors, was targeted to suprabasal keratinocytes using a keratin 10 promoter. The transgene was expressed specifically in the skin and highest expression levels were found in the tail. Expression of the mutant receptor disrupted the organization of epidermal keratinocytes, induced epidermal hyperthickening and resulted in an aberrant expression of keratin 6. This suggests that FGF is essential for the morphogenesis of suprabasal keratinocytes and for the establishment of the normal program of keratinocyte differentiation. Our study demonstrates that dominant-negative growth factor receptors can be used to block selectively the action of a growth factor in specific tissues of transgenic mice.     

Soluble dominant-negative receptor uncovers essential roles for fibroblast growth factors in multi-organ induction and patterning.

Despite a wealth of experimental data implicating fibroblast growth factor (FGF) signaling in various developmental processes, genetic inactivation of individual genes encoding specific FGFs or their receptors (FGFRs) has generally failed to demonstrate their role in vertebrate organogenesis due to early embryonic lethality or functional redundancy. Here we show that broad mid-gestational expression of a novel secreted kinase-deficient receptor, specific for a defined subset of the FGF superfamily, caused agenesis or severe dysgenesis of kidney, lung, specific cutaneous structures, exocrine and endocrine glands, and craniofacial and limb abnormalities reminiscent of human skeletal disorders associated with FGFR mutations. Analysis of diagnostic molecular markers revealed that this soluble dominant-negative mutant disrupted early inductive signaling in affected tissues, indicating that FGF signaling is required for growth and patterning in a broad array of organs and in limbs. In contrast, transgenic mice expressing a membrane-tethered kinase-deficient FGFR were viable. Our results demonstrate that secreted FGFR mutants are uniquely effective as dominant-negative agents in vivo, and suggest that related soluble receptor isoforms expressed in wild-type mouse embryos may help regulate FGF activity during normal development.     

Cell type and tissue distribution of the fibroblast growth factor receptor

A receptor for fibroblast growth factor (aFGF, bFGF) was partially characterized in intact cell cultures, cell plasma membranes, and tissue plasma membrane preparations. Analysis of 24 different cell types from four species identified a 165-kDa FGF receptor present on the cell surface of most mesodermal and neuroectodermal cells. Chemical crosslinking of 125I-aFGF to its cell surface receptor was specifically blocked by a 100-fold molar excess of either aFGF or bFGF. In contrast to the similar molecular weight of FGF receptors, different cell types exhibited significant variations in binding of 125I-aFGF to intact cultures with low values of 8 pM and 700, to high values of 60 pM and 30,000, for the Kd and receptor number per cell, respectively. A binding assay was developed for quantitation of 125I-aFGF binding to cell- and tissue-derived membrane preparations. Membranes prepared from baby hamster kidney cells exhibited a Kd of 55 pM, while a similar Kd of 67 pM was determined for intact baby hamster kidney cells. Although ten different adult bovine tissue membrane preparations and human term placental membranes exhibited no specific binding of 125I-aFGF, FGF receptor was detected in embryonic murine tissues (17 days gestation). These results support the existence, in a variety of cells, of either a common FGF receptor that binds both aFGF and bFGF or closely related FGF receptors that cannot be distinguished by molecular weight. The differential binding of FGF to its receptor in embryonic vs. adult tissues suggests a potentially broad role for FGF in embryonic development and a more restrictive role in the adult.     

Retargeted delivery of adenoviral vectors through fibroblast growth factor receptors involves unique cellular pathways.

A major goal of gene therapy is to improve target specificity by delivering vectors through alternative cellular receptors. We previously reported that adenoviral vector delivery through basic fibroblast growth factor (FGF2) receptors enhances both cellular transduction and in vivo efficacy. We now present studies addressing the cellular pathways and mechanisms underlying these events. Cellular receptors for adenoviruses are not required for transduction by FGF2-retargeted vectors. Moreover, alpha(V) integrins can antagonize FGF2 retargeting, in contrast to their obligatory role in non-retargeted vector delivery. By contrast, high-affinity FGF receptors, which are overexpressed on potential tumor targets, are required for FGF2-retargeted transduction. Low-affinity heparan sulfate proteoglycan interactions, however, are not a prerequisite, in marked contrast to their obligatory role in FGF2 mitogenic signaling. By comparing receptor expression and ligand binding with transgene expression, we also demonstrate that FGF2 retargeting enhances transduction by mechanisms other than increasing the number of targeted cells. Rather, the use of alternative targeting ligands supports the conclusion that specific receptor interactions and intracellular events serve to enhance transgene expression. Together, these studies highlight the unique delivery and transduction pathways used by FGF2-retargeted adenoviruses, and help define the basis for their enhanced in vivo efficacy.     

Inhibition of cell growth and tumorigenesis of human glioblastoma cells by a neutralizing antibody against human basic fibroblast growth factor.

We report here that a neutralizing mouse monoclonal antibody against basic FGF inhibited both anchorage-dependent and anchorage-independent growth of U-87MG and T98G human glioblastoma cells and HeLa cells, all of which express both the basic FGF and the FGF receptor genes. In addition, the subcutaneous administration of this antibody significantly suppressed the tumor development of these tumor cells in nude mice. Therefore, basic FGF plays an important role in neoplastic growth of these cells. The neutralization of basic FGF will be effective in controlling the growth of tumors, such as glioblastoma and other cancer cells which bear basic FGF and FGF receptors.     

FGF receptor availability regulates skeletal myogenesis.

Fibroblast growth factors (FGFs) and their receptors are critical participants in embryonic development, including the genesis of skeletal, cardiac, and smooth muscle. FGF signaling is mediated through interactions between multiple FGF ligands and transmembrane tyrosine kinase receptors, resulting in activation of a number of signal transduction pathways. Skeletal myocytes express FGF ligands and receptors in a coordinated fashion, suggesting that these molecules participate in autocrine signaling in the myocyte. Endogenously produced FGF has been shown to inhibit myogenesis, but the role of FGF receptor availability in directing myocyte proliferation and differentiation has not been established. To determine the contribution of receptor availability to the regulation of myogenesis, receptor availability was either increased by expressing a full-length FGF receptor-1 or decreased by expressing a truncated FGF receptor-1 in cultured skeletal myocytes. Constitutive expression of a full-length FGF receptor-1 increased myocyte proliferation and delayed differentiation. Conversely, a reduction in functional FGF receptor signaling by expression of a truncated FGF receptor-1 decreased proliferation and enhanced differentiation of myocytes. These data demonstrate that FGF receptor availability plays a critical regulatory role in skeletal myogenesis.     

Induction of platelet-derived growth factor receptor expression in smooth muscle cells and fibroblasts upon tissue culturing

The expression of platelet-derived growth factor (PDGF) receptors in porcine uterus and human skin in situ, was compared with that of cultured primary cells isolated from the same tissues. PDGF receptor expression was examined by monoclonal antibodies specific for the B type PDGF receptor and by RNA/RNA in situ hybridization with a probe constructed from a cDNA clone encoding the B type PDGF receptor. In porcine uterus tissue both mRNA and the protein product for the PDGF receptor were detected in the endometrium; the myometrium, in contrast, contained much lower amounts. Moreover, freshly isolated myometrial cells were devoid of PDGF receptors. However, after 1 d in culture receptors appeared, and after 2 wk of culturing essentially all of the myometrial cells stained positively with the anti-PDGF receptor antibodies and contained PDGF receptor mRNA. Similarly, B type PDGF receptors were not detected in normal human skin, but fibroblast-like cells from explant cultures of human skin possessed PDGF receptors. When determined by immunoblotting, porcine uterus myometrial membranes contained approximately 20% of the PDGF receptor antigen compared with the amount found in endometrial membranes. In addition, PDGF stimulated the phosphorylation of a 175-kD component, most likely representing autophosphorylation of the B type PDGF receptor in endometrial membranes, whereas only a marginal phosphorylation was seen in myometrial membranes. Taken together, these results demonstrate that PDGF receptor expression varies in normal tissues and that fibroblasts and smooth muscle cells do not uniformly express the receptor in situ. Furthermore, fibroblasts and smooth muscle cells that are released from tissues are induced to express PDGF receptors in response to cell culturing. The data suggest that, in addition to the availability of the ligand, PDGF-mediated cell growth in vivo is dependent on factors regulating expression of the receptor.     

Exon switching and activation of stromal and embryonic fibroblast growth factor (FGF)-FGF receptor genes in prostate epithelial cells accompany stromal independence and malignancy.

Stroma and the heparin-binding fibroblast growth factor (FGF) family influence normal epithelial cell growth and differentiation in embryonic and adult tissues. The role of stromal cells and the expression of isoforms of the FGF ligand and receptor family were examined during malignant progression of epithelial cells from a differentiated, slowly growing, nonmalignant model rat prostate tumor. In syngeneic hosts, a mixture of stromal and epithelial cells resulted in nonmalignant tumors which were differentiated and slowly growing. In the absence of the stromal cells, epithelial cells progressed to malignant tumors which were independent of the stroma and undifferentiated. The independence of the malignant epithelial cells from stromal cells was accompanied by a switch from exclusive expression of exon IIIb to exclusive expression of exon IIIc in the FGF receptor 2 (FGF-R2) gene. The FGF-R2(IIIb) isoform displays high affinity for stromal cell-derived FGF-7, whereas the FGF-R2(IIIc) isoform does not recognize FGF-7 but has high affinity for the FGF-2 member of the FGF ligand family. The switch from expression of exclusively exon IIIb to exclusively exon IIIc in the resident FGF-R2 gene was followed by activation of the FGF-2 ligand gene, the normally stromal cell FGF-R1 gene, and embryonic FGF-3 and FGF-5 ligand genes in malignant epithelial cells. Multiple autocrine and potentially intracrine ligand-receptor loops resulting from these alterations within the FGF-FGF-R family may underlie the autonomy of malignant tumor cells.     

Striking differences of LDL receptor-related protein 1B expression in mouse and human

The low density lipoprotein (LDL) receptor-related protein 1B (LRP1B) is a member of the expanding LDL receptor family, and is closely related to LRP. It was discovered as a putative tumor suppressor, and is frequently inactivated in human malignant tissues. However, the expression pattern of LRP1B in normal human tissues was unclear. In the present study, we analyzed LRP1B expression in normal mouse and human tissues. By using RT-PCR, we found that, while mouse LRP1B expression is mostly restricted to the brain, human LRP1B expression is more widespread with highest expression levels detected in the brain, adrenal gland, salivary gland, and testis. Although mouse LRP1B expresses in the forms of both full-length receptor tail and an alternatively spliced form lacking a 33-amino acid insert, human LRP1B is expressed exclusively in the form of full-length receptor tail. Finally, we found that, unlike mouse LRP1B, human LRP1B is cleaved by furin. Taken together, these data demonstrate that there are striking differences between LRP1B expression in mouse and human tissues. The broader expression pattern of LRP1B in human tissues suggests that this putative tumor suppressor may play roles in several types of human cancer.     

The human fibroblast growth factor receptor genes: a common structural arrangement underlies the mechanisms for generating receptor forms that differ in their third immunoglobulin domain.

To determine the mechanisms by which multiple forms of fibroblast growth factor (FGF) receptors are generated, we have mapped the arrangement of exons and introns in the human FGF receptor 1 (FGFR 1) gene (flg). We found three alternative exons encoding a portion of the third immunoglobulin (Ig)-like domain of the receptor. One of these alternatives encodes a sequence that is part of a secreted form of FGFR 1. The other two encode sequences that are likely part of transmembrane forms of FGFR 1. One of these forms has not been previously reported in published cDNAs. Also, we have determined the structural organization of a portion of the human FGFR 2 gene (bek) and found a similar arrangement of alternative exons for the third Ig-like domain. The arrangement of these genes suggests that there are conserved mechanisms governing the expression of secreted FGF receptors as well as the expression of at least two distinct membrane-spanning forms of the FGF receptors. The diverse forms appear to be generated by alternative splicing of mRNA and selective use of polyadenylation signals.     

Involvement of substance P and the NK-1 receptor in cancer progression

Many data suggest the deep involvement of the substance P (SP)/neurokinin (NK)-1 receptor system in cancer: (1) Tumor cells express SP, NK-1 receptors and mRNA for the tachykinin NK-1 receptor; (2) Several isoforms of the NK-1 receptor are expressed in tumor cells; (3) the NK-1 receptor is involved in the viability of tumor cells; (4) NK-1 receptors are overexpressed in tumor cells in comparison with normal ones and malignant tissues express more NK-1 receptors than benign tissues; (5) Tumor cells expressing the most malignant phenotypes show an increased percentage of NK-1 receptor expression; (6) The expression of preprotachykinin A is increased in tumor cells in comparison with the levels found in normal cells; (7) SP induces the proliferation and migration of tumor cells and stimulates angiogenesis by increasing the proliferation of endothelial cells; (8) NK-1 receptor antagonists elicit the inhibition of tumor cell growth; (9) The specific antitumor action of NK-1 receptor antagonists on tumor cells occurs through the NK-1 receptor; (10) Tumor cell death is due to apoptosis; (11) NK-1 receptor antagonists inhibit the migration of tumor cells and neoangiogenesis. The NK-1 receptor is a therapeutic target in cancer and NK-1 receptor antagonists could be considered as broad-spectrum antitumor drugs for the treatment of cancer. It seems that a common mechanism for cancer cell proliferation mediated by SP and the NK-1 receptor is triggered, as well as a common mechanism exerted by NK-1 receptor antagonists on tumor cells, i.e. apoptosis.     

正常猕猴与树鼩神经系统和免疫系统组织中大麻素与阿片受体的表达

为应用猕猴和树鼩动物模型研究毒品成瘾对神经/免疫系统的影响提供基础数据,对大麻素及阿片受体在正常猕猴和树鼩神经系统和免疫系统的表达进行初步确定.采集正常猕猴和树鼩新鲜组织(皮质、小脑、脑干、海马、脊髓、脾脏),应用半定量逆转录PCR和实时定量PCR的方法检测大麻素与阿片受体mRNA在猕猴和树鼩各组织中的表达情况.猕猴脑部各区包括脾脏均表达大麻索受体1(CNR1),而大麻素受体2(CNR2)只表达于脾脏内.三类阿片受体中,mu(μ)受体表达最为广泛,在以上各组织中均有表达;delta(δ)受体表达的组织最少,只在海马表达;kappa(κ)受体表达介于两者之间,分别在皮质、小脑、脑干、脊髓中表达.在树鼩组织中,CNR1和CNR2表达于整个大脑重要脑区中,且CNR1表达量高于同一区域内CNR2表达的鼍:脾脏中CNR2的表达较高,而CNR1不表达.三类阿片受体只有检测到μ受体在脑部与脾脏表达,且在各个脑区的表达量明显高于脾脏的表达量;δ体和κ受体在被检各个组织中均无表达.总体而言,两种大麻素受体在猕猴和树鼩体内表达情况与人类和鼠的情况类似,而三类阿片受体在猕猴体内表达情况与人类吏为接近.猕猴和树鼩可能可用于人类毒品成瘾的研究;猕猴在某些神经受体的表达更接近人类,其在研究毒品成瘾的机理和对免疫系统的影响方面仍有不可替代的地位.     

Developmental expression patterns of the signaling adapters FRS-2 and FRS-3 during early embryogenesis

Two fibroblast growth factor (FGF) receptor substrates (FRS2 and FRS3) are involved in downstream signaling from activated FGF receptors and neurotrophin-activated Trk receptors. Despite the importance of signaling from these factors in embryogenesis, FRS2 and FRS3 expression patterns during development are unknown. In this study we characterize the expression of FRS2 and FRS3 from E7 to parturition and in adult murine tissues. Both are first detected in whole E8.5 CD1 mouse embryos. FRS2 is detected as early as E7 in the developing syncytiotrophoblast, later in the neural tube (NT) and in many adult and fetal tissues. FRS3 is more restricted in location than FRS2 (fetal NT, heart, stomach, liver and some adult tissues), and is expressed predominantly in the ventricular layer of the developing NT and brains of murine embryos.     

Expression of CNPY2 in Mouse Tissues: Quantification and Localization

Canopy FGF signaling regulator 2 (CNPY2) is a FGF21-modulated protein containing a saposin B-type domain. In vitro studies have shown CNPY2 is able to enhance neurite outgrowth in neurons and stabilize the expression of low density lipoprotein receptor in macrophages and hepatocytes. However, no in vivo data are available on the normal expression of CNPY2 and information is lacking on which cell types express this protein in tissues. To address this, the present study examined CNPY2 expression at the mRNA and protein levels. Quantitative PCR and ELISA examination of mouse tissues showed that CNPY2 varies between organs, with the highest expression in the heart, lung and liver. Immunohistochemistry detected CNPY2 in a variety of cell types including skeletal, cardiac and smooth muscle myocytes, endothelial cells and epithelial cells. CNPY2 was also detectable in mouse blood and human and mouse uteri. These data demonstrate CNPY2 is widely distributed in tissues and suggest the protein has biological functions that have yet to be identified. Using these new observations we discuss possible functions of the protein.     

Characterization of a novel protein (FGFRL1) from human cartilage related to FGF receptors

Utilizing a subtractive cDNA cloning approach we have identified a novel protein from human cartilage. This protein represents an integral membrane protein with 504 amino acids and a molecular mass of 55 kDa. It is composed of a signal peptide, three extracellular Ig-like modules, a transmembrane segment, and a short intracellular domain. The extracellular domain is closely related to the extracellular domain of FGF receptors. The intracellular domain, however, does not show any similarity to the protein tyrosine kinase domain of FGF receptors. The novel gene (FGFRL1) is located on human chromosome 4 band p16 in close proximity to the gene for FGFR3. Its mRNA is preferentially expressed in cartilaginous tissues. Owing to the structural similarity, it is conceivable that the novel protein plays a role in the modulation of FGF receptor activity.     

Differential Fibroblast Growth Factor 8 (FGF8)-Mediated Autoregulation of Its Cognate Receptors,Fgfr1 and Fgfr3, in Neuronal Cell Lines

Fibroblast growth factors (FGFs) mediate a vast range of CNS developmental processes including neural induction, proliferation, migration, and cell survival. Despite the critical role of FGF signaling for normal CNS development, few reports describe the mechanisms that regulate FGF receptor gene expression in the brain. We tested whether FGF8 could autoregulate two of its cognate receptors, Fgfr1 and Fgfr3, in three murine cell lines with different lineages: fibroblast-derived cells (3T3 cells), neuronal cells derived from hippocampus (HT-22 cells), and neuroendocrine cells derived from hypothalamic gonadotropin-releasing hormone (GnRH) neurons (GT1-7 cells). GnRH is produced by neurons in the hypothalamus and is absolutely required for reproductive competence in vertebrate animals. Several lines of evidence strongly suggest that Fgf8 is critical for normal development of the GnRH system, therefore, the GT1-7 cells provided us with an additional endpoint, Gnrh gene expression and promoter activity, to assess potential downstream consequences of FGF8-induced modulation of FGF receptor levels. Results from this study suggest that the autoregulation of its cognate receptor represents a common downstream effect of FGF8. Further, we show that Fgfr1 and Fgfr3 are differentially regulated within the same cell type, implicating these two receptors in different biological roles. Moreover, Fgfr1 and Fgfr3 are differentially regulated among different cell types, suggesting such autoregulation occurs in a cell type-specific fashion. Lastly, we demonstrate that FGF8b decreases Gnrh promoter activity and gene expression, possibly reflecting a downstream consequence of altered FGF receptor populations. Together, our data bring forth the possibility that, in addition to the FGF synexpression group, autoregulation of FGFR expression by FGF8 represents a mechanism by which FGF8 could fine-tune its regulatory actions.     

An in vitro long-term culture model for normal human mammary gland: expression and regulation of steroid receptors

Steroids and their nuclear receptors play crucial roles in the development and maintenance of normal functions of the human mammary gland (HMG). They have also been implicated in breast carcinogenesis. However, the study of steroid action in normal HMG has been hampered by experimental difficulties. By using a newly established in vitro long-term culture method, we successfully cultured normal HMG tissue for more than 2 months without detriment to its morphology or steroid receptor expression. Expression of the cellular structural and extracellular matrix proteins was similar to that prior to culture, and HMG tissue retained its properties of steroid receptor expression and regulation. Addition of 17-beta estrogen to mammary tissues markedly increased the expression of progesterone receptor (PR) but only slightly affected that of the estrogen receptor (ER). Medroxyprogesterone acetate down-regulated the expression of PR within 24-48 h and also increased the expression of androgen receptor. When HMG tissue was cultured in medium containing normal or dextran-coated charcoal-stripped fetal calf serum or normal human serum, the expression and regulation of steroid hormone receptors were similar, although different in extent. When serum was omitted, the morphology of HMG was normal after 1 week, but the expression and regulation of ER and PR were altered. Thus, as HMGs retain the capacity to express steroid receptors in culture, this long-term culture system is probably a good model for studying the regulation of the mammary gland by steroids.