Progestins induce down-regulation of insulin-like growth factor-I (IGF-I) receptors in human breast cancer cells: potential autocrine role of IGF-II.

Insulin-like growth factor-I (IGF-I) receptors are present in breast cancer cells and may play a role in breast cancer cell growth. We have studied the effect of progestins on IGF-I receptors in T47D human breast cancer cells. T47D cells constitutively express high levels of progesterone receptors and are a model for studying the regulation of cellular functions by progestins. Treatment of T47D cells with either progesterone or the synthetic progestin promegestone (R5020) decreased IGF-I receptor content by approximately 50%, as measured by Scatchard analysis and receptor biosynthesis studies. In contrast to progestins, estradiol, dexamethasone, and dihydrotestosterone did not influence IGF-I receptor content. No effect of R5020 was seen after 12 h of incubation, a near-maximal effect was seen after 24 h, and greatest effects were seen after 72 h. R5020 decreased IGF-I receptor mRNA abundance, indicating that progestins acted at the level of gene expression. However, progestins also increased the secretion of IGF-II, a ligand for the IGF-I receptor. In contrast to IGF-II, T47D cells did not express IGF-I. The addition of exogenous IGF-II to T47D cells down-regulated both IGF-I receptor binding and IGF-I receptor mRNA abundance. This study indicates, therefore, that progestins regulate IGF-I receptors in breast cancer cells and suggests that this regulation occurs via an autocrine pathway involving enhanced IGF-II secretion.     

The glycosylated IgII Extracellular domain of EMMPRIN is implicated in the induction of MMP-2

Insulin-like growth factor (IGF)-I and IGF-II play major roles in the regulation of skeletal muscle growth and differentiation, and both are locally expressed in muscle cells. Recent studies have demonstrated that IGF-II up-regulates its own gene expression during myogenesis and this auto-regulatory loop is critical for muscle differentiation. How local IGF-I is regulated in this process is unclear. Here, we report that while IGF-II up-regulated its own gene expression, it suppressed IGF-I gene expression during myogenesis. These opposite effects of IGF-II on IGF-I and IGF-II genes expression were time dependent and dose dependent. It has been shown that IGFs activate the PI3K-Akt-mTOR, p38 MAPK, and Erk1/2 MAPK pathways. In myoblasts, we examined their role(s) in mediating the opposite effects of IGF-II. Our results showed that both the PI3K-Akt-mTOR and p38 MAPK pathways played critical roles in increasing IGF-II mRNA expression. In contrast, mTOR was required for down-regulating the IGF-I gene expression by IGF-II. In addition, Akt, Erk1/2 MAPK, and p38 MAPK pathways were also involved in the regulation of basal levels of IGF-I and IGF-II genes during myogenesis. These findings reveal a previously unrecognized negative feedback mechanism and extend our knowledge of IGF-I and IGF-II gene expression and regulation during myogenesis.     

Overexpression of insulin-like growth factor-II induces accelerated myoblast differentiation

Previous studies have shown that exogenous insulin-like growth factors (IGFs) can stimulate the terminal differentiation of skeletal myoblasts in culture and have established a correlation between the rate and the extent of IGF-II secretion by muscle cell lines and the rate of biochemical and morphological differentiation. To investigate the hypothesis that autocrine secretion of IGF-II plays a critical role in stimulating spontaneous myogenic differentiation in vitro, we have established C2 muscle cell lines that stably express a mouse IGF-II cDNA under control of the strong, constitutively active Moloney sarcoma virus promoter, enabling us to study directly the effects of IGF-II overproduction. Similar to observations with other muscle cell lines, IGF-II overexpressing myoblasts proliferated normally in growth medium containing 20% fetal serum, but they underwent enhanced differentiation compared with controls when incubated in low-serum differentiation medium. Accelerated differentiation of IGF-II overexpressing C2 cells was preceded by the rapid induction of myogenin mRNA and protein expression (within 1 h, compared with 24–48 h in controls) and was accompanied by an enhanced proportion of the retinoblastoma protein in an underphosphrylated and potentially active form, by a marked increase in activity of the muscle-specific enzyme, creatine phosphokinase, by extensive myotube formation by 48 h, and by elevated secretion of IGF binding protein-5 when compared with controls. These results confirm a role for IGF-II as an autocrine/paracrine differentiation factor for skeletal myoblasts, and they define a model cell system that will be useful in determining the biochemical mechanisms of IGF action in cellular differentiation. © 1996 Wiley-Liss, Inc.     

Insulin-like growth factors (IGF) in muscle development. Expression of IGF-I, the IGF-I receptor, and an IGF binding protein during myoblast differentiation

The insulin-like growth factors (IGFs) I and II exert pleiotropic effects on diverse cell types through interaction with specific high affinity cell surface receptors and with locally produced binding proteins. In skeletal muscle and in myoblast cell lines, the functions of IGF-I and -II are complex. Both growth factors appear capable of stimulating cellular proliferation and differentiation, as well as exerting insulin-like effects on intermediary metabolism. We have demonstrated recently that the expression of IGF-II and its receptor is induced during the terminal differentiation of the myoblast cell line, C2, and have suggested that IGF-II may be an autocrine growth factor in these cells (Tollefsen, S.E., Sadow, J.L., and Rotwein, P. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 1543-1547). We now have examined this cell line for expression of other components involved in IGF signaling. The synthesis of IGF-I is low during myoblast proliferation; IGF-I mRNA can be detected only through use of a sensitive solution hybridization assay. Typical IGF-I receptors can be measured in myoblasts, whereas IGF binding proteins cannot be detected in proliferating cells or in conditioned culture medium. During myogenic differentiation, IGF-I mRNA levels increase transiently by 6-10-fold within 48-72 h. The expression of IGF-I mRNA is accompanied by a 2.5-fold accumulation of IGF-I in the culture medium. IGF-I receptors also increase transiently, doubling by 48 h after the onset of differentiation. By contrast, secretion of a Mr 29,000 IGF binding protein is induced 30-fold to 100 ng/ml within 16 h and continues to increase throughout differentiation. These studies demonstrate that several components critical to IGF action are produced in a fusing skeletal muscle cell line in a differentiation-dependent manner and suggest that both IGF-I and IGF-II may be autocrine factors for muscle.     

"Spontaneous" differentiation of skeletal myoblasts is dependent upon autocrine secretion of insulin-like growth factor-II.

Differentiation of muscle cells to form postmitotic myotubes is usually viewed as being negatively controlled by medium components, sometimes designated "mitogens." However, we have found that a family of mitogenic agents, the insulin-like growth factors (IGFs), are potent stimulators of differentiation in myoblasts which act by inducing expression of the myogenin gene. We show here that this action of the IGFs occurs even when these growth factors are not added to the cell medium; upon transfer to low-serum "differentiation medium," myoblasts begin active expression of the IGF-II gene, at both the mRNA and protein levels. Furthermore, autocrine secretion of IGF-II is essential for the process of terminal differentiation of the cells. These conclusions are based upon four lines of evidence. (1) The rate of spontaneous differentiation in several sublines of myogenic cells correlates with their level of expression of IGF-II. (2) C2 and Sol 8 cells, which secrete high levels of IGF-II, are relatively insensitive to exogenous IGFs, in contrast to L6 lines, which exhibit lower levels of IGF-II gene expression. (3) An antisense oligodeoxyribonucleotide complementary to the first five codons of IGF-II inhibits myogenic differentiation in the absence but not in the presence of exogenous IGF-II. (4) Spontaneous differentiation in response to autocrine IGF-II involves the same mechanism that occurs in cells stimulated by the IGFs, i.e. elevation of expression of the myogenin gene.     

Activation of insulin-like growth factor II expression during skeletal muscle regeneration in the rat: correlation with myotube formation.

Insulin-like growth factors (IGFs) are important stimulators of proliferation and differentiation of cultured myoblasts. It has previously been shown that IGF-I is induced during muscle regeneration in rodents, however, little is known about the expression of IGF-II. Therefore, two in vivo models were used to analyze IGF-II mRNA expression during skeletal muscle regeneration in the rat: injection of the snake venom notexin and induction of ischemia. During the regeneration process the levels of both IGF-I and IGF-II mRNA were transiently induced, as analyzed by solution hybridization. Both IGF-I-like immunoreactivity and IGF-II-like immunoreactivity were found to be present during muscle regeneration. In a time course study, induction of IGF-II was preceded by IGF-I, both at the mRNA and protein levels. Using alpha- and beta-actin as markers for different stages of skeletal muscle differentiation, together with the immunohistochemistry data, it is concluded that the expression of IGF-I and IGF-II occurs at different differentiation stages, and that IGF-II appears concomitant to the formation of myotubes. These results suggest that each IGF has a distinct role during the differentiation of muscle cells.     

Insulin-like growth factors (IGF-I and IGF-II) inhibit C2 skeletal myoblast differentiation and enhance TNF alpha-induced apoptosis

IGF-I and IGF-II are thought to be unique in their ability to promote muscle cell differentiation. Murine C2 myoblasts differentiate when placed into low serum media (LSM), accompanied by increased IGF-II and IGF binding protein-5 (IGFBP-5) production. Addition of 20 ng/ml TNF alpha on transfer into LSM blocked differentiation, IGF-II and IGFBP-5 secretion and induced apoptosis. We, therefore, wished to assess whether IGFs could protect against the effects of TNF alpha. Neither inhibition of differentiation or induction of apoptosis was rescued by co-incubation with IGF-I or IGF-II. A lower dose of TNF alpha (1 ng/ml) while not inducing apoptosis still inhibited myoblast differentiation by 56% +/- 12, (P < 0.001), indicating that induction of apoptosis is not the sole mechanism by which TNF alpha inhibits myoblast differentiation. Addition of IGF-I or IGF-II alone reduced differentiation by 49% +/- 15 and 33% +/- 20, respectively, (P < 0.001), although neither induced apoptosis. For muscle cells to differentiate, they must arrest in G0. We established that addition of IGF-I, IGF-II or TNF alpha to the myoblasts promoted proliferation. The myoblasts could not exit the cell cycle as efficiently as controls and differentiation was thus reduced. Unexpectedly, co-incubation of IGF-I or IGF-II with 1 ng/ml TNF alpha enhanced the inhibition of differentiation and induced apoptosis. In the absence of apoptosis we show an association between IGF-induced inhibition of differentiation and increased IGFBP-5 secretion. These results indicate that the effects of the IGFs on muscle may depend on the cytokine environment. In the absence of TNF alpha, the IGFs delay differentiation and promote myoblast proliferation whereas in the presence of TNF alpha the IGFs induce apoptosis.     

Induction and peak gene expression of insulin-like growth factor II follow that of myogenin during differentiation of BC3H-1 muscle cells.

Acting through hormonal and/or autocrine/paracrine mechanisms, the insulin-like growth factors (IGFs) stimulate the differentiation of muscle cells. Previous studies have suggested that one mechanism by which IGFs stimulate muscle cell differentiation is by increasing the expression of myogenin, a DNA binding protein that regulates the expression of muscle-specific genes. While exogenous IGF peptides increase myogenin mRNA, the role of endogenously produced IGF peptides in myogenin expression has not been established. In addition, the potential role of IGFs in regulating the expression of Id, a protein in myoblasts that can inhibit the action of myogenin-like peptides, is also unknown. In the present study, we have examined the kinetics of accumulation of myogenin and IGF-II mRNAs during differentiation of BC3H-1 mouse muscle cells and have explored the potential role of IGFs in regulating Id expression. During differentiation induced by serum withdrawal, induction of myogenin expression preceded that of IGF-II, the principal IGF peptide expressed by these cells. In addition, Id expression decreased within two hours in serum-free medium and was not affected by IGF treatment. Thus, these studies suggest that endogenously-produced IGF-II may stimulate muscle cell differentiation after both the decrease in Id and the induction of myogenin gene expression have occurred.     

Insulin-like growth factor-I stimulates terminal myogenic differentiation by induction of myogenin gene expression.

Stimulation of myogenic differentiation by the insulin-like growth factors (IGFs) has been established for many years, but our attempts to elucidate the mechanism of that stimulation have been successful only in eliminating some likely possibilities. The recent discovery of a family of muscle determination genes has opened a new approach to this question, allowing specific focus on those genes that might play central roles in controlling myogenesis. We now report that IGF-I stimulates terminal myogenic differentiation in L6A1 cells by inducing a large increase in expression of the myogenin gene. This conclusion is supported by the following observations. 1) Myogenin mRNA is elevated by IGF-I, with a concentration dependency that parallels the stimulation of differentiation, including a decrease in stimulation at higher concentrations. 2) The time course of elevation of myogenin mRNA is consistent with its acting as an intermediate in the signalling pathway between occupancy of the IGF-I receptor and induction of expression of muscle-specific genes. 3) Inhibitors of myogenesis also inhibit elevation of myogenin mRNA in response to IGF-I. 4) An antisense oligonucleotide to the N-terminus of myogenin prevents the stimulation of differentiation by IGF-I and IGF-II, but has no effect on other actions of IGF-I on myoblasts. MyoD has been reported not to be expressed in L6 cells, and the expression of myf-5 and herculin/myf-6/MRF4 is reportedly low or undetectable. Thus, the stimulation of differentiation by IGF-I can be attributed largely, if not entirely, to increased expression of the myogenin gene. However, the relatively long time period between addition of the IGFs and elevation of myogenin mRNA as well as the inhibition of this process by several inhibitors indicate that increased myogenin mRNA levels are not a simple direct result of occupation of the IGF-I receptor.     

Expression of mRNA encoding insulin-like growth factors I and II and the type 1 IGF receptor in the bovine corpus luteum at defined stages of the oestrous cycle

Previous studies have implicated insulin-like growth factors I and II (IGF-I and -II), in the regulation of ovarian function. The present study investigated the localization of mRNA encoding IGF-I and -II and the type 1 IGF receptor using in situ hybridization to determine further the roles of the IGFs within the bovine corpus luteum at precise stages of the oestrous cycle. Luteal expression of mRNA encoding IGF-I and -II and the type 1 IGF receptor was detected throughout the oestrous cycle. The expression of IGF-I mRNAvaried significantly during the oestrous cycle. IGF-I mRNA concentrations were significantly higher on day 15 than on day 10, and IGF-I mRNA in the regressing corpus luteum at 48 h after administration of exogenous prostaglandin was significantly greater than in the early or mid-luteal phase (days 5 and 10). In contrast, there was no significant effect of day of the oestrous cycle on expression of mRNA for IGF-II and the type 1 IGF receptor in the corpus luteum. Expression of IGF-II mRNA was localized to a subset of steroidogenic luteal cells and was also associated with cells of the luteal vasculature. mRNA encoding the type 1 IGF receptor was widely expressed in a pattern indicative of expression in large and small luteal cells. These data demonstrate that the bovine corpus luteum is a site of IGF production and reception throughout the luteal phase. Furthermore, this study highlights the potential of IGF-II in addition to IGF-I in the autocrine and paracrine regulation of luteal function.     

Regulation of the genes for insulin-like growth factor (IGF) I and II and their receptors by steroids and gonadotropins in the ovary

Insulin-like growth factors (IGFs) I and II are two single-chain polypeptide hormones that are structurally related to each other and to proinsulin. Among the large number of growth factors involved in ovarian physiology, IGF-I and IGF-II are considered to be important progression factors for ovarian follicular development. To explore the ovarian expression of IGF-I, IGF-II and their receptor genes, a solution hybridization/RNase protection assay, was used. IGF-I mRNA was seen in the granulosa cells, and IGF-II mRNA in the theca-interstitial compartment. To study the hormonal regulation of the IGF-I and IGF-II gene, immature (21-day-old) hypohysectomized rats were treated with FSH (10 μg/day),GH (150 μg/day) and diethylstilbestrol (DES subcutaneous implant/5 days). Estrogen differentially regulated ovarian IGF-I and IGF-II gene expression. In concert with GH, estrogen up-regulated ovarian IGF-I mRNA, but significantly decreased hepatic IGF-I gene expression. Both IGF receptors (type I and type II) as well as the insulin receptor gene, were expressed in both ovarian cells. The expression of the type IIGF receptor gene (but not the type II IGF gene) was up-regulated by FSH and estrogen in vivo. In conclusion, these studies may serve to better understand the auto paracrine role of IGF, and their receptors in the pathophysiology of follicle recruitment, oocyte maturation and potentially embryo development.     

Insulin-like growth factor family and combined antisense approach in therapy of lung carcinoma

BACKGROUND: Perturbation in a level of any peptide from insulin-like growth factor (IGF) family (ligands, receptors, and binding proteins) seems to be implicated in lung cancer formation; IGF ligands and IGF-I receptor through their mitogenic and anti-apoptotic action, and the mannose 6-phosphate/insulin-like growth factor II receptor (M6-P/IGF-IIR) possibly as a tumor suppressor. MATERIALS AND METHODS: To determine the identity, role, and mutual relationship of IGFs in lung cancer growth and maintenance, we examined IGF's gene (by RT-PCR) and protein (by immunohistochemistry) expression in 69 human lung carcinoma tissues. We also examined IGF-I receptor numbers (Scatchard analysis) and IGF-II production and release (by Western blot) in IGF-II/IGF-IR mRNA positive and negative lung carcinomas. Finally, the potential role of IGF-IR and IGF-II as growth promoting factors in lung cancer was studied using antisense oligodeoxynucleotides that specifically inhibit IGF-IR and IGF-II mRNA. RESULTS: Thirty-two tumors were positive for IGF-I, 39 for IGF-II, 48 for IGF-IR, and 35 for IGFBP-4 mRNA. Seventeen tumors were concomitantly positive for all four IGFs, whereas 34 were positive for IGF-II, IGF-IR, and IGFBP-4 mRNA. An elevated amount of IGF-II peptide was secreted into the growth medium of cell cultures established from five different IGF-II/IGF-IR mRNA positive lung cancer tissues. The cells also expressed elevated numbers of IGF-IR. Nine IGF-II-negative and 19 IGF-II-positive lung cancers of different stages were selected, and M6-P/ IGF-II receptor was determined immunohistochemically. Most of the IGF-II-negative tumors were strongly positive for M6-P/IGF-IIR. IGF-II-positive tumors were mostly negative for M6-P/IGF-II receptors. Antisense oligodeoxynucleotides to IGF-II significantly inhibited, by 25-60%, the in vitro growth of all six lung cancer cell lines. However, the best results (growth inhibition of up to 80%) were achieved with concomitant antisense treatment (to IGF-IR and IGF-II). CONCLUSION: Our data suggest that lung cancer cells produce IGF-IR and IGF-II, which in turn stimulates their proliferation by autocrine mechanism. Cancer cell proliferation can be abrogated or alleviated by blocking the mRNA activity of these genes indicating that an antisense approach may represent an effective and practical cancer gene therapy strategy.