NGR-TNF, a novel vascular-targeting agent, does not induce cytokine recruitment of proangiogenic bone marrow-derived cells.

BACKGROUND: Administration of certain chemotherapy drugs at the maximum tolerated dose, vascular-disrupting agents (VDAs) and irradiation can induce mobilisation and tumour homing of proangiogenic bone marrow-derived cells (BMDCs). Increases in cytokines and chemokines contribute to such mobilisation that eventually promotes tumour (re)growth. NGR-TNF is a vascular-targeting agent in advanced clinical development, coupling the CNGRCG angiogenic vessel-homing peptide with tumour necrosis factor-alpha (TNF). We investigated whether NGR-TNF mobilises host BMDCs and growth factors. METHODS: Blood was obtained from Lewis lung carcinoma and 4T1 tumour-bearing mice at different time points following NGR-TNF, VDA or anti-VEGFR2/flk-1 antibody treatment. Levels of circulating growth factors were assessed by ELISAs. BMDCs were characterised by FACS. Circulating endothelial progenitor cells were defined as CD45(-)/CD13(+)/flk-1(+)/CD117(+)/7AAD(-), Tie2-expressing monocytes as CD45(+)/CD11b(+)/Tie2(+) and myeloid-derived suppressor cells as CD45(+)/CD11b(+)/Gr1(+) cells. RESULTS: NGR-TNF decreases tumour blood vessel density-inducing apoptosis of tumour and tumour endothelial cells. Unlike VDAs, or high-dose NGR-TNF, lower doses of NGR-TNF, comparable to those used in clinical trials, neither mobilise nor recruit to the tumour site proangiogenic BMDCs or induce host growth factors. CONCLUSION: Low-dose NGR-TNF exerts antitumour activity without inducing proangiogenic host responses, conceivably important for preventing/overcoming resistance and designing combination therapeutic strategies.

Regulation of Id2 gene expression by the type 1 IGF receptor and the insulin receptor substrate-1.

The Id family of helix-loop-helix proteins is known to be involved in the proliferation and differentiation of several types of cells. The type 1 IGF receptor (IGF-IR) induces either proliferation or differentiation in 32D cells, a murine hemopoietic cell line, depending on the availability of the appropriate substrates for the receptor. We have previously reported that the IGF-IR regulates the expression of the Id2 gene in 32D cells. We now show that the IGF-IR controls the increase in Id2 gene expression through at least three pathways. These three pathways originate from the tyrosine residue at 950, a domain in the C-terminus, and the activation of the insulin receptor substrate-1 (IRS-1) by the receptor. IRS-1 is the preponderant signal, and its effect on Id2 gene expression requires a functional phosphotyrosine binding domain. With wild-type IRS-1, Id2 gene expression is increased, even in those cells that express IGF-I receptors defective in Id2 signaling. Rapamycin, an inhibitor of p70(S6K), a downstream effector of IRS-1 signaling, partially inhibits (but does not completely abrogate) the increase in Id2 gene expression. A mutant IRS-1 with a deletion of the Pleckstrin domain is as effective as wild-type IRS-1 in up-regulating Id2 gene expression. In addition, it seems to increase the stability of p70(S6K). Our results indicate that the IGF-IR regulates Id2 gene expression through different pathways. At least in 32D cells, increased Id2 gene expression seems to correlate more with inhibition of differentiation than with proliferation.

The role of the insulin receptor substrate-1 in the differentiation of rat hippocampal neuronal cells.

H19-7/IGF-IR cells are rat hippocampal cells expressing a human IGF-I receptor, which differentiate to a neuronal phenotype when stimulated by IGF-I at 39 degrees C. H19-7/IGF-IR cells have low levels of expression of insulin receptor substrate-l (IRS-1), a major substrate of the IGF-IR. IGF-I induces serine-phosphorylation and down-regulation of the endogenous IRS-1 upon differentiation of H19-7/IGF-IR cells. The profound influence of IRS-1 on differentiation of H19-7/IGF-IR cells was confirmed by transfecting these cells with a plasmid expressing mouse IRS-1. Over-expression of wild type IRS-1 in H19-7/IGF-IR cells abolishes IGF-I-induced differentiation at 39 degrees C. A mutant of IRS-1 lacking the PTB domain loses the ability to inhibit the differentiation program. H19-7/IGF-IR/IRS-1 cells at 39 degrees C show a stronger and prolonged activation of Akt, when compared to H19-7/IGF-IR cells. The role of Akt in the inhibition of the differentiation program was confirmed by using the inhibitor of Class I PI3 kinases LY29400, which restores IGF-I-induced differentiation of H19-7/IGF-IR/IRS-1 cells. H19-7/IGF-IR/IRS-1 cells show a strong reduction in MAP kinases signaling, which is related to the superactivation of Akt. This was confirmed by expressing in H19-7/IGF-IR cells a constitutively active Akt, which inhibited MAP kinases activation in these cells. These experiments confirm the importance of MAPK in the mechanism of IGF-I-mediated differentiation of H19-7/IGF-IR cells

Anti-apoptotic signaling of the insulin-like growth factor-I receptor through mitochondrial translocation of c-Raf and Nedd4.

The type 1 insulin-like growth factor receptor (IGF-IR) sends a strong anti-apoptotic signal by at least three different pathways. By using mutants of the IGF-IR, we showed that one of the pathways depends on residues of the IGF-IR (serines 1280--1283) that interact with 14.3.3 proteins. The result is the activation of Raf-1 and the mitochondrial translocation of both Raf-1 and Nedd4, a target of caspases. A mutant IGF-IR in which the serines at positions 1280--1283 have been mutated to alanine does not protect from apoptosis and fails to translocate Nedd4 or Raf-1 to the mitochondria. This failure is accompanied by a loss of cytochrome c from the mitochondria. The 14.3.3/Raf-1/Nedd4 pathway is operative in the presence or absence of the insulin receptor substrate-1.

IGF-I receptor signalling in transformation and differentiation.

The type 1 insulin-like growth factor receptor (IGF-IR) sends several signals, some of which are contradictory. When the concentrations of insulin receptor substrate 1 (IRS-1), a major substrate of the IGF-IR, are high, the signal is mitogenic, anti-apoptotic, and can even cause malignant transformation. However, in the absence of IRS-1, the IGF-IR sends a differentiation signal, which leads to granulocytic differentiation in haemopoietic cells. The mitogenic signal of the IGF-IR/IRS-1 combination depends largely, but not exclusively, on the activation of the phosphatidylinositol-3 kinase (PI3K).

Regulation of Id2 gene expression by the insulin-like growth factor I receptor requires signaling by phosphatidylinositol 3-kinase.

The Id proteins play an important role in proliferation, differentiation, and tumor development. We report here that Id gene expression can be regulated by the insulin-like growth factor I receptor (IGF-IR), a receptor that also participates in the regulation of cellular proliferation and differentiation. Specifically, we found that the IGF-IR activated by its ligand was a strong inducer of Id2 gene expression in 32D murine hemopoietic cells. This activation was not simply the result of cellular proliferation, as Id2 gene expression was higher in 32D cells stimulated by IGF-I than in cells exponentially growing in interleukin-3. The up-regulation of Id2 gene expression was largely dependent on the presence of insulin receptor substrate-1, a major substrate of the IGF-IR and a potent activator of the phosphatidylinositol 3-kinase (PI3K) pathway. The role of PI3K activity in the up-regulation of Id2 gene expression by the IGF-IR was confirmed by different methods and in different cell types. In 32D cells, the up-regulation of Id2 gene expression by the PI3K pathway correlated with interleukin-3 independence and inhibition of differentiation.

Cooperative transformation of 32D cells by the combined expression of IRS-1 and V-Ha-Ras.

32D cells expressing v-Ha-Ras fail to show a transformed phenotype. Since Ras requires an active IGF-1R for transformation of fibroblasts, we asked whether expression of IRS-1 or Shc (two of the major substrates of the IGF-1R) could co-operate with oncogenic Ras in transforming 32D cells. We find that IRS-1, but not Shc, in combination with v-Ha-Ras generates a fully transformed phenotype in 32D cells. 32D cells expressing both IRS-1 and v-Ha-Ras (32D/IRS1/Ras) survive and proliferate in the absence of IL-3, do not undergo granulocytic differentiation in the presence of G-CSF and form tumors in nu/nu and syngeneic mice. In contrast, 32D cells expressing singly IRS-1 or v-Ha-Ras exhibit only a block in differentiation capacity. Over-expression of Shc proteins, by itself, promotes differentiation of 32D cells. Concomitant expression of IRS-1 and v-Ha-Ras synergistically phosphorylates ERK-1 and ERK-2 whereas a MEK inhibitor rapidly induces death of 32D/IRS1/Ras transformed cells. Furthermore, transformed 32D/IRS1/Ras cells display high levels of PI3-K activation and undergo rapid apoptosis when exposed to PI3-K inhibitors. The data indicate that: (1) a fully transformed phenotype in 32D cells is generated when a block in differentiation (v-Ha-Ras) is coupled with another differentiation block (IRS-1); (2) PI3-K and MAPK activity are required for the survival of transformed cells; (3) the signals generated by IRS-1 and oncogenic Ras converge on ERK and PI3-K resulting in high levels of activation.

Insulin receptor substrate-1, p70S6K, and cell size in transformation and differentiation of hemopoietic cells.

After an initial burst of cell proliferation, the type 1 insulin-like growth factor receptor (IGF-IR) induces granulocytic differentiation of 32D IGF-IR cells, an interleukin-3-dependent murine hemopoietic cell line devoid of insulin receptor substrate-1 (IRS-1). The combined expression of the IGF-IR and IRS-1 (32D IGF-IR/IRS-1 cells) inhibits IGF-I-mediated differentiation, and causes malignant transformation of 32D cells. Because of the role of IRS-1 in changing the fate of 32D IGF-IR cells from differentiation (and subsequent cell death) to malignant transformation, we have looked for differences in IGF-IR signaling between 32D IGF-IR and 32D IGF-IR/IRS-1 cells. In this report, we have focused on p70(S6K), which is activated by the IRS-1 pathway. We find that the ectopic expression of IRS-1 and the inhibition of differentiation correlated with a sustained activation of p70(S6K) and an increase in cell size. Phosphorylation in vivo of threonine 389 and, to a lesser extent, of threonine 421/serine 424 of p70(S6K) seemed to be a requirement for inhibition of differentiation. A role of IRS-1 and p70(S6K) in the alternative between transformation or differentiation of 32D IGF-IR cells was confirmed by findings that inhibition of p70(S6K) activation or IRS-1 signaling, by rapamycin or okadaic acid, induced differentiation of 32D IGF-IR/IRS-1 cells. We have also found that the expression of myeloperoxidase mRNA (a marker of differentiation, which sharply increases in 32D IGF-IR cells), does not increase in 32D IGF-IR/IRS-1 cells, suggesting that the expression of IRS-1 in 32D IGF-IR cells causes the extinction of the differentiation program initiated by the IGF-IR, while leaving intact its proliferation program.

Insulin-like growth factor I receptor signaling in differentiation of neuronal H19-7 cells.

The type I insulin-like growth factor receptor (IGF-IR) is known to send two seemingly contradictory signals inducing either cell proliferation or cell differentiation, depending on cell type and/or conditions. H19-7 cells are rat hippocampal neuronal cells immortalized by a temperature-sensitive SV40 large T antigen that grow at 34 degrees C in epidermal growth factor or serum but differentiate at 39 degrees C when induced by basic fibroblast growth factor. At 39 degrees C, expression of the human IGF-IR in H19-7 cells induces an insulin-like growth factor (IGF) I-dependent differentiation. We have investigated the domains of the IGF-IR required for differentiation of H19-7 cells. The tyrosine 950 residue and serines 1280-1283 in the COOH terminus of the receptor are required for IGF-I-induced differentiation at 39 degrees C, although they are dispensable for IGF-I-mediated growth at 34 degrees C. Both domains have to be mutated to inactivate the differentiating function. The inability of these mutant receptors to induce differentiation correlates with mitogen-activated protein kinase activation. In contrast, inhibitors of phosphatidylinositol 3'-kinase have no effect on IGF-I-mediated differentiation of H19-7 cells, although they do inhibit the mitogenic response.

Biological activities and signaling pathways of the granulin/epithelin precursor.

Growth-regulated cells, such as 3T3 mouse embryo fibroblasts (MEFs), require more than one growth factor for growth, usually the insulin-like growth factor I (IGF-I) in combination with either platelet-derived growth factor or epidermal growth factor. Singly, these growth factors cannot sustain the growth of 3T3 cells. However, if the IGF-I receptor (IGF-IR) is even modestly overexpressed, then IGF-I, by itself, stimulates the growth of MEFs in monolayer and makes them capable of forming colonies in soft agar. The granulin/epithelin precursor (GEP) has been identified as the only growth factor, thus far, that can stimulate by itself the growth of R- cells, a 3T3-like cell line in which the genes for the IGF-IR have been deleted. We have expressed GEP in R- cells and show that these cells can now grow in serum-free medium. GEP, however, cannot replace other functions of the IGF-IR, such as protection from apoptosis (anoikis) or transforming activity (colony formation in soft agar). GEP activates, in R- cells, the two signaling pathways that are known to be sufficient for IGF-I-mediated mitogenesis in cells overexpressing the IGF-IR, the mitogen-activated protein kinase and the phosphatidylinositol 3-kinase pathways. This may explain why GEP, by itself, can replace the IGF-IR for growth in monolayer cultures. It also confirms that, for transformation, other pathways must be activated besides the two pathways that are sufficient for mitogenesis.

mGrb10 interacts with Nedd4.

We have utilized the yeast two-hybrid system to identify proteins interacting with mouse Grb10, an adapter protein known to interact with both the insulin and the insulin-like growth factor-I receptors. We have isolated a mouse cDNA clone containing the C2 domain of mouse Nedd4, a ubiquitin protein ligase (E3) that also contains a hect (homologous to the E6-AP carboxyl-terminus) domain and three WW domains. The interaction with Grb10 in the two-hybrid system was confirmed using the full-length Nedd4, and it was abolished by deleting the last 148 amino acids of Grb10, a region that includes the SH2 domain and the newly identified BPS domain. The interaction between Grb10 and Nedd4 was also reproduced in vivo in mouse embryo fibroblasts, where endogenous Nedd4 co-immunoprecipitated constitutively with both the endogenous and an overexpressed Grb10. This interaction was Ca(2+)-independent. Grb10 interacting with Nedd4 was not ubiquitinated in vivo, raising the possibility that this interaction may be used to target other proteins, like tyrosine kinase receptors, for ubiquitination.

Insulin and IGF-I receptors signaling in protection from apoptosis.

R-cells are mouse embryo fibroblasts with a targeted disruption of the insulin-like growth factor I receptor (IGF-IR) genes. Because R-cells do not express the IGF-IR, they are ideal for studying the biological effects of the insulin receptor (IR), independently from any contribution by the IGF-IR. By stably transfecting R-cells with constructs expressing the IR, we show here the IR can protect cells from apoptosis induced by anoikis or by okadaic acid. The IR, however, is not as efficient as the IGF-IR in protecting mouse embryo fibroblasts from apoptosis, even when IRS-1, one of its major substrates, is over-expressed. In addition, the protection by the IGF-IR is resistant to inhibitors of phosphatidylinositol 3-kinase (PI 3-ki), while the anti-apoptotic effect of the IR is sensitive. These experiments suggest that the IGF-IR uses an alternative anti-apoptotic pathway, not shared with the IR, which is PI3-ki-independent.

Growth and differentiation signals by the insulin-like growth factor 1 receptor in hemopoietic cells are mediated through different pathways.

The type 1 insulin-like growth factor receptor (IGF-IR) plays an important role in the growth of cells both in vivo and in vitro. The IGF-IR is also capable of inducing differentiation in a number of cell types, raising the question of how the same receptor can send two seemingly contradictory signals, one for growth and one for differentiation. Using 32D cells, which are murine hemopoietic cells, we show that the activated IGF-IR can induce differentiation along the granulocytic pathway in a manner similar to the granulocyte colony-stimulating factor. We find that one of the major substrates of the IGF-IR, the insulin receptor substrate-1 inhibits IGF-I-mediated differentiation of 32D cells. In the absence of insulin receptor substrate-1, functional impairment of another major substrate of the IGF-IR, the Shc proteins, is associated with a decrease in the extent of differentiation. Although the end points of the respective pathways remain to be defined, these results show for the first time that IGF-I-mediated growth or differentiation of hemopoietic cells may depend on a balance between two of its substrates.

Anti-apoptotic signaling of the IGF-I receptor in fibroblasts following loss of matrix adhesion.

The type 1 insulin-like growth factor receptor (IGF-IR) is known to protect cells from a variety of apoptotic injuries. In several instances, the anti-apoptotic effect of the wild type IGF-IR is more evident under conditions of anchorage-independence than in cells in monolayer cultures. We have investigated IGF-IR signaling in cells in anoikis, a form of apoptosis that occurs when cells are denied attachment to the extra-cellular matrix. IGF-I protects mouse embryo fibroblasts (MEF) from anoikis caused by withdrawal of growth factors. Survival is dependent on the concentration of IGF-I and a sufficient number of functional IGF-I receptors. In this model, IGF-I protection correlates best with ras activation and cell-to-cell aggregation, while PI3-kinase, Akt and MAP kinases seem to play a lesser, alternative role.

Dissociation between resistance to apoptosis and the transformed phenotype in IGF-I receptor signaling.

Programmed Cell Death (PCD) is known to play an important role in both the development and the growth rate of human tumors. It has in fact been suggested that suppression of the apoptotic pathway is a requirement for the establishment of the transformed phenotype. In order to elucidate the relationship between resistance to apoptosis and transformation, we have asked in this investigation whether or not the two processes can be directly correlated. For this purpose, we have used mouse embryo fibroblasts (MEF) expressing either the wild-type or several mutants of the type 1 insulin-like growth factor receptor (IGF-IR). The wild-type IGF-IR has both transforming and anti-apoptotic activities, and we have asked whether these two activities can be or not separated in mutant receptors. Using this well-defined system, our results show that certain mutants of the IGF-IR that have strong anti-apoptotic and mitogenic activities, are incapable of transforming MEF (colony formation in soft agar). We have, instead, a good correlation between mitogenic and anti-apoptotic activities, suggesting the possibility that the two processes may share similar signaling pathways from the IGF-IR. On the other hand, our results indicate that transformation requires an additional signal, above and beyond the mitogenic and survival signals. Our conclusion is that, at least in this system, the establishment of the malignant phenotype and resistance to apoptosis can be dissociated, implying the possibility of separate targeting.

Insulin-like growth factor-I-mediated survival from anoikis: role of cell aggregation and focal adhesion kinase.

Anoikis is a form of cell death that occurs when cells are denied attachment to the extra-cellular matrix. Using p6 cells, that are 3T3 cells overexpressing the type 1 insulin-like growth factor receptor (IGF-IR), we show that these cells undergo apoptosis when seeded on polyHEMA plates in serum-free medium (SFM). IGF-I protects p6 cells from anoikis, without inducing mitogenesis or DNA synthesis. In the surviving p6 cells in suspension cultures, the focal adhesion kinase (FAK) is tyrosyl phosphorylated by IGF-I, although this phosphorylation occurs only after several hours. The importance of FAK in protection from anoikis is confirmed by v-src-transformed R-cells, in which FAK is constitutively phosphorylated, that survive even in SFM. Surviving cells, whether p6 or v-src transformed, tend to form large cell aggregates, whose appearance precedes the phosphorylation of FAK. These and other findings suggest that FAK phosphorylation in the case of IGF-I is a mediated effect rather than a direct one. When p6 cells are plated on polyHEMA dishes, IGF-I induces cell aggregation and this aggregation correlates with survival and the eventual phosphorylation of FAK.

Molecular markers of IGF-I-mediated mitogenesis.

The aim of these investigations was to identify a number of molecular markers that correlate to growth stimulation by IGF-I. For this purpose, we have selected four cell lines that respond equally well to growth stimulation by serum, but differ in their proliferative response to IGF-I. Two cell lines (R503 and R600 cells) respond to IGF-I with both DNA synthesis and cell division, a third cell line (R508 cells) can enter S phase after IGF-I, but the cells do not divide, and a fourth one (R12 cells) totally fails to respond to IGF-I with growth. Using these cell lines, all of which had an intact mitogenic response program to serum, we show that: (1) an increase in GTP/GDP ratio is an early event that distinguishes cells capable of entering S phase after IGF-I from cells that do not; (2) all cells that are induced to synthesize DNA by IGF-I have increased phosphorylation of MAP kinases, regardless of their ability to divide; (3) the same cell lines display a similar increase in cyclin A and B expression at early times after stimulation; and (4) cyclin levels and cyclin B-associated cdc2 kinase activity remain elevated at later times only in cells that undergo cell division. These results establish certain parameters of IGF-I-mediated mitogenesis and clearly separate the occurrence of DNA synthesis from cell division in certain situations.

The baculovirus anti-apoptotic p35 protein promotes transformation of mouse embryo fibroblasts.

The baculovirus p35 protein is a potent inhibitor of programmed cell death induced by a variety of stimuli in insects, nematodes, and mammalian cell lines. The broad ability of p35 in preventing apoptosis has led us to investigate its effect on mouse embryo fibroblasts in vitro and in vivo. For this purpose, we have used R- cells (3T3-like fibroblasts derived from mouse embryos with a targeted disruption of the insulin-like growth factor I receptor (IGF-IR) genes) and R508 cells (derived from R- and with 15 x 10(3) IGF-IRs per cell). Both cell lines grow normally in monolayer, but they do not form colonies in soft agar, and they are non-tumorigenic in nude mice. We show here that, in addition to its anti-apoptotic effect, p35 causes transformation of R508 cells, as evidenced by the following: 1) decreased growth factor requirements, 2) ability to form foci in monolayer and colonies in soft agar, and 3) ability to form tumors in nude mice. Since R- cells stably transfected with p35 do not transform, our observations suggest that in addition to its effect as an inhibitor of apoptosis, the baculovirus p35 protein has transforming potential that requires the presence of the IGF-IR. The possibility that these two properties could be separated was confirmed by demonstrating that R508 cells expressing another anti-apoptotic protein, Bcl-2, could not form tumors in nude mice.

The role of mGrb10alpha in insulin-like growth factor I-mediated growth.

Several isoforms of Grb10 are known to interact with either the insulin receptor or the insulin-like growth factor I (IGF-I) receptor, or both. Inasmuch as the data in the literature on the function of Grb10 are not always concordant, we have investigated the role of one of these isoforms, mGrb10alpha, in cell proliferation. For this purpose, a plasmid expressing mGrb10alpha was stably transfected into p6 cells and other mouse embryo fibroblast cell lines. An overexpressed mGrb10alpha inhibits IGF-I-mediated growth, causes a delay in the S and G2 phases of the cell cycle, and partially reverses the transformed phenotype. In contrast, it has no effect on insulin stimulation of cell proliferation. These studies indicate that this isoform of Grb10 has an inhibitory effect on IGF-I signaling of cell proliferation.

Protective effect of the insulin-like growth factor I receptor on apoptosis induced by okadaic acid.

Okadaic acid (OKA), a potent inhibitor of serine phosphatases at concentrations as low as 20-25 nM, induces apoptosis of R- mouse embryo fibroblasts, which are 3T3-like cells devoid of type 1 insulin-like growth factor receptors (IGF-IRs). From R- cells, we have generated (by stable transfection) cell lines with IGF-IR numbers ranging from 0 (R- cells) to >10(6) receptors per cell. The wild-type IGF-IR protects R- cells from OKA-induced apoptosis, its protective effect being exquisitely dependent on the number of receptors. A small increment in wild-type receptor number (from 15 x 10(3) to 22 x 10(3) receptors/cell) is sufficient to change R(-)-derived cells from sensitive to resistant to apoptosis. We have also studied the effect of various mutations of the IGF-IR on its ability to protect R(-)-derived cells from OKA-induced apoptosis. Our data indicate a correlation between protection from apoptosis and the ability of the receptor to respond to insulin-like growth factor I with mitogenesis.