Interaction of transforming growth factor-beta receptor I with farnesyl-protein transferase-alpha in yeast and mammalian cells

Therapeutic effect of novel drug candidate, PRG-N-01, on NF2 syndrome-related tumor

BACKGROUND

NF2-related schwannomatosis (NF2-SWN) is associated with multiple benign tumors in the nervous system. NF2-SWN, caused by mutations in the NF2 gene, has developed into intracranial and spinal schwannomas. Because of the high surgical risk and frequent recurrence of multiple tumors, targeted therapy is necessary. However, there are no approved drugs.

METHODS

We examined the action mechanism of PRG-N-01, a candidate molecule for NF2-SWN, through the direct binding assay and mass spectrometry. For in vitro anti-proliferative experiments, primary cells derived from NF2 mouse model and patient tumors, were treated with PRG-N-01. The in vivo therapeutic and preventive efficacy was validated via intraperitoneal and oral administration in NF2 mouse model (Postn-Cre; Nf2f/f). Gene expression profile in the DRG of mouse model was explored by RNA sequencing. The pharmacological properties of PRG-N-01 were analyzed through the preclinical study.

RESULTS

PRG-N-01 binds to the N-terminal extremity of TGFβR1 (TβR1) kinase domain, where TβR1 and RKIP interact, inhibiting the binding and preventing degradation of RKIP. In vivo administration in the mouse model suppressed schwannoma progression in the DRG. Early oral administration of the PRG-N-01 also demonstrated preventive effects on NF2-SWN. PRG-N-01 treatment suppressed tumor growth genes while upregulating genes related to for normal cell metabolism and schwann cell differentiation in DRG. PRG-N-01 showed druggable properties through the preclinical study including ADME, pharmacodynamics, pharmacokinetics and toxicology.

CONCLUSIONS

Together, our study provides the rationale and critical data for a prospective clinical trial of PRG-N-01 in NF2-SWN patients indicating PRG-N-01 as a promising candidate for the treatment.

Regulation of protein prenylation

Prenyltransferases (PTases) are known to play a role in embryonic development, normal tissue homeostasis and cancer by posttranslationally modifying proteins involved in these processes. They are being discussed as potential drug targets in an increasing number of diseases, ranging from Alzheimer's disease to malaria. Protein prenylation and the development of specific PTase inhibitors (PTIs) have been subject to intense research in recent decades. Recently, the FDA approved lonafarnib, a specific farnesyltransferase inhibitor that acts directly on protein prenylation; and bempedoic acid, an ATP citrate lyase inhibitor that might alter intracellular isoprenoid composition, the relative concentrations of which can exert a decisive influence on protein prenylation. Both drugs represent the first approved agent in their respective substance class. Furthermore, an overwhelming number of processes and proteins that regulate protein prenylation have been identified over the years, many of which have been proposed as molecular targets for pharmacotherapy in their own right. However, certain aspects of protein prenylation, such as the regulation of PTase gene expression or the modulation of PTase activity by phosphorylation, have attracted less attention, despite their reported influence on tumor cell proliferation. Here, we want to summarize the advances regarding our understanding of the regulation of protein prenylation and the potential implications for drug development. Additionally, we want to suggest new lines of investigation that encompass the search for regulatory elements for PTases, especially at the genetic and epigenetic levels.

The Discovery and Early Days of TGF-β: A Historical Perspective

Transforming growth factors (TGFs) were discovered as activities that were secreted by cancer cells, and later by normal cells, and had the ability to phenotypically and reversibly transform immortalized fibroblasts. TGF-β distinguished itself from TGF-α because it did not bind to the same epidermal growth factor (EGF) receptor as TGF-α and, therefore, acted through different cell-surface receptors and signaling mediators. This review summarizes the discovery of TGF-β, the early developments in its molecular and biological characterization with its many biological activities in different cell and tissue contexts and its roles in disease, the realization that there is a family of secreted TGF-β-related proteins with many differentiation functions in development and activities in normal cell and tissue physiology, and the subsequent identification and characterization of the receptors and effectors that mediate TGF-β family signaling responses.

TGF-β signalling is mediated by two autonomously functioning TβRI:TβRII pairs

Transforming growth factor (TGF)-βs are dimeric polypeptides that have vital roles in regulating cell growth and differentiation. They signal by assembling a receptor heterotetramer composed of two TβRI:TβRII heterodimers. To investigate whether the two heterodimers bind and signal autonomously, one of the TGF-β protomers was substituted to block receptor binding. The substituted dimer, TGF-β3 WD, bound the TβRII extracellular domain and recruited the TβRI with affinities indistinguishable from TGF-β3, but with one-half the stoichiometry. TGF-β3 WD was further shown to retain one-quarter to one-half the signalling activity of TGF-β3 in three established assays for TGF-β function. Single-molecule fluorescence imaging with GFP-tagged receptors demonstrated a measurable increase in the proportion of TβRI and TβRII dimers upon treatment with TGF-β3, but not with TGF-β3 WD. These results provide evidence that the two TβRI:TβRII heterodimers bind and signal in an autonomous manner. They further underscore how the TGF-βs diverged from the bone morphogenetic proteins, the ancestral ligands of the TGF-β superfamily that signal through a RI:RII:RII heterotrimer.

High glucose induced endothelial cell growth inhibition is associated with an increase in TGFbeta1 secretion and inhibition of Ras prenylation via suppression of the mevalonate pathway

OBJECTIVE

Ras proteins are known to affect cellular growth and function. The influence of the prenylation status of Ras on the observed changes in endothelial cell growth under high glucose conditions has not previously been examined.

METHODS

Human umbilical vein endothelial cells were exposed to normal or high glucose conditions for 72 h. They were then examined for proliferative and hypertrophic effects, transforming growth factor beta(1) (TGFbeta(1)) release, and phosphorylated p38 expression. The importance of prenylation was explored by the addition of mevalonate, isoprenoids or farnesyltransferase inhibitors to control the high glucose media and by measuring changes induced by high glucose and exogenous TGFbeta(1) in Ras prenylation and farnesyltransferase activity. Kidneys from diabetic rats treated with atorvastatin were also compared to specimens from untreated animals and the expression of the Ras effector p-Akt examined.

RESULTS

High glucose conditions caused a reduction in cell number. This was reversed in the presence of mevalonate or farnesylpyrophosphate (FPP), suggesting that the cell growth abnormalities observed are due to high glucose induced inhibition of the mevalonate pathway and subsequent prenylation of proteins. Endothelial cells exposed to high glucose increased their secretion of TGFbeta(1) and the phosphorylation of p38 both of which were reversed by concurrent exposure to FPP. A reduction in farnesyltransferase activity was observed after exposure to both high glucose and TGFbeta(1). Exposure to a farnesyltransferase inhibitor in control conditions mimicked the growth response observed with high glucose exposure and prenylated Ras was reduced by exposure to both high glucose and TGFbeta(1). Finally, interruption of the mevalonate pathway with a statin reduced the expression of p-Akt in diabetic rat kidneys.

CONCLUSION

This study demonstrates that high glucose induced significant alterations in endothelial cell growth by inhibition of the mevalonate pathway, which subsequently mediates the increase in TGFbeta(1) and inhibition of Ras prenylation.

Farnesyltransferase inhibitors reverse taxane resistance

The combination of farnesyltransferase inhibitors (FTIs) and taxanes has been shown to result in potent antiproliferative and antimitotic synergy. Recent phase I and II clinical trials have shown that this combination shows clinical activity in taxane-refractory or taxane-resistant cancer patients. To understand the mechanism behind these clinical observations, we used a cancer cell model of paclitaxel resistance and showed that the FTI/taxane combination retains potent antiproliferative, antimitotic, and proapoptotic activity against the paclitaxel-resistant cells, at doses where each drug alone has little or no activity. To probe the mechanistic basis of these observations, paclitaxel activity was monitored in living cells using the fluorescently conjugated paclitaxel, Flutax-2. We observed that all FTIs tested increase the amount of microtubule-bound Flutax-2 and the number of microtubules labeled with Flutax-2 in both paclitaxel-resistant and paclitaxel-sensitive cells. Importantly, we observed a consequential increase in microtubule stability and tubulin acetylation with the combination of the two drugs, even in paclitaxel-resistant cells, confirming that the enhanced taxane binding in the presence of FTI affects microtubule function. Furthermore, this mechanism is dependent on the function of the tubulin deacetylase, HDAC6, because in cells overexpressing a catalytically inactive HDAC6, FTIs are incapable of enhancing Flutax-2-microtubule binding. Similar results were obtained by using an FTI devoid of farnesyltransferase inhibitory activity, indicating that functional inhibition of farnesyltransferase is also required. Overall, these studies provide a new insight into the functional relationship between HDAC6, farnesyltransferase, and microtubules, and support clinical data showing that the FTI/taxane combination is effective in taxane-refractory patients.

TGF-beta receptor-binding proteins: complex interactions

Members of the Smad protein family are fundamental downstream mediators of TGF-beta signals. However, the basic, linear Smad signaling pathway is unlikely to be the sole contributor to the plethora of cell type-specific TGF-beta responses. Investigators have identified a number of molecules that interact with the TGF-beta receptors (TbetaRs) and may explain, at least in part, the tight regulation of TGF-beta effects. Understanding these TbetaR-interacting molecules is thus a matter of great potential significance for elucidating TGF-beta-family signal transduction. The present article reviews our current understanding of the roles and mechanisms of action of this relatively understudied group of molecules.

TGF beta-induced focal complex formation in epithelial cells is mediated by activated ERK and JNK MAP kinases and is independent of Smad4

Advanced malignancies often exhibit increased concentrations of transforming growth factor-beta (TGF beta), which has been suggested to promote invasion and metastasis. While inhibition of epithelial cell proliferation in response to TGF beta is mainly mediated by the well-characterised Smad pathway, the molecular mechanism leading to TGF beta-induced invasiveness and metastasis are largely unknown. To elucidate these mechanisms, we compared TGF beta1 signalling in MCF-7 and the Smad4-negative MDA-MB-468 breast cancer cells. Both cell lines react to TGF beta1 treatment with decreased subcortical actin and increased numbers of focal contacts. TGF beta1-induced cell migration was strongly dependent on the activation of extracellular signal-regulated kinase (ERK) and Jun N-terminal kinase (JNK). These mitogen-activated protein kinases were phosphorylated in response to TGF beta and subsequently translocated into focal contacts. Inhibition of the TGF beta type I receptor ALK5 slightly reduced phosphorylation of ERK in MCF-7 cells, but neither inhibited phosphorylation of ERK in MDA-MB-468 cells nor TGF beta1-induced migration of both cell lines. In contrast, ALK5 inhibition effectively blocked Smad2 phosphorylation. In addition to ERK and JNK, the monomeric GTPase RhoA was activated by TGF beta1 and necessary for TGF beta-induced migration. Taken together, our study identifies a role of ERK and JNK activation and association of activated MAPKs with focal complexes in TGF beta1-induced cell migration in epithelial cells. These TGF beta-dependent processes were mediated independently of Smad4.

Functions and regulation of transforming growth factor-beta (TGF-β) in the prostate

The prostate is a highly androgen-dependent tissue that in humans exhibits marked susceptibility to carcinogenesis. The malignant epithelium generated from this tissue ultimately loses dependence on androgens despite retention or amplification of the androgen receptor. Accumulating evidence support that transforming growth factor-beta (TGF-beta) plays key roles in the control of androgen dependence and acquisition of resistance to such hormonal control. Although TGF-beta functions as a key tumour suppressor of the prostate, it can also promote malignant progression and metastasis of the advanced disease, through undefined mechanisms. In addition to giving an overview of the TGF-beta field as related to its function in prostate cancer, this Review focuses on novel findings that support the tumour suppressor function of TGF-beta is lost or altered by changes in the activity of the androgen receptor, insulin-like growth factor-I, Akt, and mTOR during malignant progression. Understanding the mechanisms of cross-talk between TGF-beta and such growth modulators has important implications for the rational therapeutics of prostate cancer.

Smad-dependent and Smad-independent pathways in TGF-beta family signalling

Transforming growth factor-beta (TGF-beta) proteins regulate cell function, and have key roles in development and carcinogenesis. The intracellular effectors of TGF-beta signalling, the Smad proteins, are activated by receptors and translocate into the nucleus, where they regulate transcription. Although this pathway is inherently simple, combinatorial interactions in the heteromeric receptor and Smad complexes, receptor-interacting and Smad-interacting proteins, and cooperation with sequence-specific transcription factors allow substantial versatility and diversification of TGF-beta family responses. Other signalling pathways further regulate Smad activation and function. In addition, TGF-beta receptors activate Smad-independent pathways that not only regulate Smad signalling, but also allow Smad-independent TGF-beta responses.

TGF-beta and the Smad signal transduction pathway

Transforming growth factor beta (TGF-beta) superfamily members are important regulators of many diverse developmental and homeostatic processes and disruption of their activity has been implicated in a variety of human diseases ranging from cancer to chondrodysplasias and pulmonary hypertension. TGF-beta family members signal through transmembrane Ser-Thr kinase receptors that directly regulate the intracellular Smad pathway. Smads are a unique family of signal transduction molecules that can transmit signals directly from the cell surface receptors to the nucleus, where they regulate transcription by interacting with DNA binding partners as well as transcriptional coactivators and corepressors. In addition, more recent evidence indicates that Smads can also function both as substrates and adaptors for ubiquitin protein ligases, which mediate the targeted destruction of intracellular proteins. Smads have thus emerged as multifunctional transmitters of TGF-beta family signals that play critical roles in the development and homeostasis of metazoans.

A novel transforming growth factor-beta receptor-interacting protein that is also a light chain of the motor protein dynein

The phosphorylated, activated cytoplasmic domains of the transforming growth factor-beta (TGFbeta) receptors were used as probes to screen an expression library that was prepared from a highly TGFbeta-responsive intestinal epithelial cell line. One of the TGFbeta receptor-interacting proteins isolated was identified to be the mammalian homologue of the LC7 family (mLC7) of dynein light chains (DLCs). This 11-kDa cytoplasmic protein interacts with the TGFbeta receptor complex intracellularly and is phosphorylated on serine residues after ligand-receptor engagement. Forced expression of mLC7-1 induces specific TGFbeta responses, including an activation of Jun N-terminal kinase (JNK), a phosphorylation of c-Jun, and an inhibition of cell growth. Furthermore, TGFbeta induces the recruitment of mLC7-1 to the intermediate chain of dynein. A kinase-deficient form of TGFbeta RII prevents both mLC7-1 phosphorylation and interaction with the dynein intermediate chain (DIC). This is the first demonstration of a link between cytoplasmic dynein and a natural growth inhibitory cytokine. Furthermore, our results suggest that TGFbeta pathway components may use a motor protein light chain as a receptor for the recruitment and transport of specific cargo along microtublules.

Transforming growth factor-beta signal transduction in epithelial cells

Transforming growth factor (TGF)-beta is a natural and potent growth inhibitor of a variety of cell types, including epithelial, endothelial, and hematopoietic cells. The ability of TGF-beta to potently inhibit the growth of many solid tumors of epithelial origin, including breast and colon carcinomas, is of particular interest. However, many solid tumor cells become refractory to the growth inhibitory effects of TGF-beta due to defects in TGF-beta signaling pathways. In addition, TGF-beta may stimulate the invasiveness of tumor cells via the paracrine effects of TGF-beta. Accordingly, in order to develop more effective anticancer therapeutics, it is necessary to determine the TGF-beta signal transduction pathways underlying the growth inhibitory effects and other cellular effects of TGF-beta in normal epithelial cells. Thus far, two primary signaling cascades downstream of the TGF-beta receptors have been elucidated, the Sma and mothers against decapentaplegic homologues and the Ras/mitogen-activated protein kinase pathways. The major objective of this review is to summarize TGF-beta signaling in epithelial cells, focusing on recent advances involving the Sma and mothers against decapentaplegic homologues and Ras/mitogen-activated protein kinase pathways. This review is particularly timely in that it provides a comprehensive summary of both signal transduction mechanisms and the cell cycle effects of TGF-beta.

Identification of differentially expressed nucleolar TGF-beta1 target (DENTT) in human lung cancer cells that is a new member of the TSPY/SET/NAP-1 superfamily

The transforming growth factor-beta1 (TGF-beta1) responsive epithelial non-small-cell lung cancer (NSCLC) cell line NCI-H727 was used to identify potential target genes involved in TGF-beta1-mediated responses. Comparative cDNA expression patterns between cells treated with TGF-beta1 and those treated with vehicle were generated by differential mRNA display. One 496-bp fragment, differentially increased threefold by TGF-beta1 and hybridizing to a 2.7-kb mRNA species in NCI-H727 cells by Northern analysis, revealed no significant match to any known gene sequence. The mRNA transcript of this novel gene that we named differentially expressed nucleolar TGF-beta1 target (DENTT) is expressed in several normal human tissues, with the highest level of expression in brain. Human brain cDNA library screening and 5' rapid amplification of cDNA ends yielded full-length DENTT cDNA containing an 1899-bp open reading frame encoding a predicted 633-amino-acid protein with four potential nuclear localization signals (NLSs) and two coiled-coil regions. DENTT contains a conserved 191-residue domain that shows significant identity to, and defines, the TSPY/TSPY-like/SET/NAP-1 superfamily. Enhanced green fluorescent protein (EGFP)-tagged full-length DENTT transfected into COS-7 cells showed nucleolar and cytoplasmic localization. Transfection of EGFP-tagged DENTT NLS deletion constructs lacking the bipartite NLS-1 were excluded from the nucleolus. While NLS-1 is necessary for nucleolar localization of DENTT, it is not sufficient for sole nucleolar localization. Our data show that DENTT mRNA induction by TGF-beta1 correlates with induction of TGF-beta1 mRNA, induction of extracellular matrix gene expression, and inhibition of colony formation in soft agarose in TGF-beta1 responsive NSCLC cells when exposed to TGF-beta1. TGF-beta1 does not induce DENTT mRNA expression in TGF-beta1 nonresponsive NSCLC cells. Our data suggest that this novel TGF-beta1 target gene has distinct domains for direction to different subnuclear locations.

Oncogenic Ki-ras confers a more aggressive colon cancer phenotype through modification of transforming growth factor-beta receptor III

Transforming growth factor-beta1 (TGF-beta1) can act as a tumor suppressor or a tumor promoter depending on the characteristics of the malignant cell. Each of three Ki-ras(G12V) transfectants of HD6-4 colon cancer cells had been shown to be more aggressive in vivo than controls in earlier studies (Yan, Z., Chen, M., Perucho, M., and Friedman, E. (1997) J. Biol. Chem. 272, 30928-30936). We now show that stable expression of oncogenic Ki-ras(G12V) converts the HD6-4 colon cancer cell line from insensitive to TGF-beta1 to growth-promoted by TGF-beta1. Each of three Ki-ras(G12V) transfectants responded to TGF-beta1 by an increase in proliferation and by decreasing the abundance of the Cdk inhibitor p21 and the tumor suppressor PTEN, whereas each of three wild-type Ki-ras transfectants remained unresponsive to TGF-beta1. The wild-type Ki-ras transfectants lack functional TGF-beta receptors, whereas all three Ki-ras(G12V) transfectants expressed functional TGF-beta receptors that bound (125)I-TGF-beta1. The previous studies showed that in cells with wild-type Ki-ras, TGF-beta receptors were not mutated, and receptor proteins were transported to the cell surface, but post-translational modification of TGF-beta receptor III (TbetaRIII) was incomplete. We now show that the betaglycan form of TbetaRIII is highly modified following translation when transiently expressed in Ki-ras(G12V) cells, whereas no such post-translational modification of TbetaRIII occurs in control cells. Antisense oligonucleotides directed to Ki-Ras decreased both TbetaRIII post-translational modification in Ki-ras(G12V) cells and TGF-beta1 down-regulation of p21, demonstrating the direct effect of mutant Ras. Therefore, one mechanism by which mutant Ki-Ras confers a more aggressive tumor phenotype is by enhancing TbetaRIII post-translational modification.

Inhibition of farnesyltransferase increases TGFbeta type II receptor expression and enhances the responsiveness of human cancer cells to TGFbeta

Several small GTPases of the Ras superfamily have been shown to antagonize TGFbeta signaling in human tumor cell lines. Some of these GTPases are post-translationally modified by farnesylation, a lipid modification catalyzed by farnesyltransferase and required for the proteins to attach to membranes and to function. In this study, we investigated the effect of the farnesyltransferase inhibitor FTI-277 on TGFbeta-regulated cell growth and transcription. Treatment of the human pancreatic tumor cell line, Panc-1, with FTI-277 enhanced the ability of TGFbeta to inhibit both anchorage-dependent and -independent tumor cell growth. FTI-277 also enhanced the ability of TGFbeta to induce transcription, as measured by p3TP-lux reporter activity and collagen synthesis. The enhancement of TGFbeta responses by FTI-277 correlated with the stimulation of transcription and protein expression of type II TGFbeta receptor (TbetaRII). Consequently, FTI-277-treated cells exhibited a higher level of TGFbeta binding to its receptor. Thus, inhibition of protein farnesylation stimulates TbetaRII expression, which leads to increased TGFbeta receptor binding and signaling as well as inhibition of tumor cell growth and transformation.

Bcl-2 blocks apoptotic signal of transforming growth factor-beta in human hepatoma cells

Transforming growth factor-beta (TGF-beta) has been shown to induce apoptosis on normal hepatocytes and hepatoma cells both in vitro and in vivo. However, how the TGF-beta induces apoptosis is still not clear. We examined the expression of anti-apoptosis proteins and sensitivity to TGF-beta in three well differentiated human hepatoma cell lines. Two TGF-beta sensitive cell lines Hep3B and HuH7 totally lacked Bcl-2. In contrast, the TGF-beta resistant HepG2 cells expressed a substantial amount of Bcl-2. All three cell lines expressed equal amounts of Bcl-X(L), Bcl-X(S) and Bax. Overexpression of Bcl-2 in Hep3B and HuH7 cells protected them from TGF-beta-induced apoptosis. TGF-beta treatment increased intracellular peroxide production and suppressed the expression of glutathione-S-transferase in the Hep3B cells, and these effects were partially suppressed by the overexpression of Bcl-2. These results suggest that Bcl-2 may protect cell from TGF-beta-F-induced apoptosis by interfering TGF-beta generated signals leading to induce reactive oxygen species production.

IGFBP-3 mediates TGF beta 1 proliferative response in colon cancer cells

Many human tumor cells are resistant to growth inhibition by TGF beta 1. Resistance may be caused by mutations in TGFbeta receptors or in other components of the TGF beta signal transduction systems, or by knockout of the retinoblastoma (Rb) gene, which in fibroblasts converts cellular response to TGF beta 1 from growth inhibition to growth stimulation. Our earlier studies showed such a switch in response to TGF beta 1 occurred in 45% of colon cancers but without deletion of Rb. We now show that insulin-like growth factor binding protein 3 (IGFBP-3) mediates the TGF beta 1-induced proliferation of 3 metastatic or highly aggressive colon carcinoma cell lines. TGF beta 1 increases IGFBP-3 abundance while phosphorothiolated antisense oligonucleotides to IGFBP-3 block the growth-promoting effect of TGF beta 1 in each of 3 lines.IGFBP-3 induces carcinoma cell growth in a dose-dependent and time-dependent manner in vitro. IGFBP-3 may confer a selective growth advantage on tumor cells in vivo because levels of mature IGFBP-3 were elevated at least 2-fold in 7 of 10 resected colon cancers compared with adjacent normal tissue.

Steps in integrin beta1-chain glycosylation mediated by TGFbeta1 signaling through Ras

Ras is activated by transforming growth factor beta (TGFbeta) in several cell types, but the biological consequences of this activation are largely unknown. We now show that ras mediates two stages in integrin beta1-chain maturation: 1) glycosylation of the 86-kD core peptide, which is a TGFbeta1-independent process, and 2) TGFbeta1-mediated conversion of the 115-kD beta1 integrin precursor into the mature 130-kD form. HD3 colon epithelial cells maintain elevated levels of integrin alpha2beta1 heterodimers, strong binding to collagen I, and autocrine regulation by TGFbeta1, which converts beta1 integrin into the mature cell surface form. Each of three HD3 cell clones that stably express dominant negative ras (N17ras) exhibited abnormal glycosylation of the integrin beta1-chain, decreased cell surface expression of the mature integrin beta1, and impaired binding to collagen and laminin. Autocrine levels of TGFbeta were not altered by expression of N17ras. The aberrant glycosylation of the integrin beta1-chain was reversed by antisense oligonucleotides specific to the DNA sequence encoding the rasS17N mutation. Glycosylation of the 86-kD core peptide was delayed in the N17ras transfectants, but was not altered by either the addition of TGFbeta1 or inhibition of autocrine TGFbeta1. In contrast, conversion of the partially glycosylated beta1 integrin precursor into the mature 130-kD isoform was accelerated by exogenous TGFbeta1 and blocked by neutralizing antibody to autocrine TGFbeta1 in control cell lines. Neither effect was seen in the N17ras transfectants, indicating that TGFbeta1 modulates integrin beta1-chain maturation by activating ras proteins. Cell fractionation studies demonstrated that this conversion takes place within the Golgi.

Effect of farnesyltransferase overexpression on cell growth and transformation

A series of studies using farnesyltransferase (FTase) inhibitors that the inhibition of FTase function suppresses the growth of ras-transformed cells in vitro and in vivo. However, whether FTase is directly involved in the regulation of cell proliferation remains to be demonstrated. To investigate whether overexpression of FTase results in altered cell growth and transformation, we thus used NIH3T3 cells transfected with cDNA constructs of both alpha and beta subunits of human FTase. FTase-overexpressing cells resulted in a 3- to 13-fold increase in the expression of the alpha and beta subunit protein of FTase and a 1.5- to 3-fold increase in the level of the enzyme activity compared with untransfected NIH3T3 cells or vector-transfected cells. Further investigations using metabolic labeling indicated that farnesylation of Ras was enhanced in FTase-overexpressing cells. Insulin-like growth factor-I, platelet-derived growth factor (PDGF), and basic fibroblast growth factor (bFGF) more potently enhanced DNA synthesis and anchorage-dependent growth in FTase-overexpressing cells than in control cells, in a dose-dependent manner. In particular, PDGF and bFGF also induced dose-dependently enhanced colony formation in soft agar in FTase-overexpressing cells. Furthermore, in FTase-transfectants, bFGF stimulated high activation of mitogen-activated protein kinase. Interestingly, FTase-transfectants developed progressive tumors in nude mice. Light and electron microscopy showed that the tumors were characteristic of fibrosarcoma, which were distinct from v-ras-induced tumors. Overexpression of FTase in NIH3T3 cells thus amplifies growth-factor-mediated cell growth and transformation, and FTase-overexpressing cells form tumors in nude mice.

p21(WAF1/CIP1) is upregulated by the geranylgeranyltransferase I inhibitor GGTI-298 through a transforming growth factor beta- and Sp1-responsive element: involvement of the small GTPase rhoA

We have recently reported that the geranylgeranyltransferase I inhibitor GGTI-298 arrests human tumor cells at the G1 phase of the cell cycle and increases the protein and RNA levels of the cyclin-dependent kinase inhibitor p21(WAF1/CIP1). Here, we show that GGTI-298 acts at the transcriptional level to induce p21(WAF1/CIP1) in a human pancreatic carcinoma cell line, Panc-1. This upregulation of p21(WAF1/CIP1) promoter was selective, since GGTI-298 inhibited serum responsive element- and E2F-mediated transcription. A functional analysis of the p21(WAF1/CIP1) promoter showed that a GC-rich region located between positions -83 and -74, which contains a transforming growth factor beta-responsive element and one Sp1-binding site, is sufficient for the upregulation of p21(WAF1/CIP1) promoter by GGTI-298. Electrophoretic mobility shift assays showed a small increase in the amount of DNA-bound Sp1-Sp3 complexes. Furthermore, the analysis of Sp1 transcriptional activity in GGTI-298-treated cells by using GAL4-Sp1 chimera or Sp1-chloramphenicol acetyltransferase reporter revealed a significant increase in Sp1-mediated transcription. Moreover, GGTI-298 treatment also resulted in increased Sp1 and Sp3 phosphorylation. These results suggest that GGTI-298-mediated upregulation of p21(WAF1/CIP1) involves both an increase in the amount of DNA-bound Sp1-Sp3 and enhancement of Sp1 transcriptional activity. To identify the geranylgeranylated protein(s) involved in p21(WAF1/CIP1) transcriptional activation, we analyzed the effects of the small GTPases Rac1 and RhoA on p21(WAF1/CIP1) promoter activity. The dominant negative mutant of RhoA, but not Rac1, was able to activate p21(WAF1/CIP1). In contrast, constitutively active RhoA repressed p21(WAF1/CIP1). Accordingly, the ADP-ribosyl transferase C3, which specifically inhibits Rho proteins, enhanced the activity of p21(WAF1/CIP1). Taken together, these results suggest that one mechanism by which GGTI-298 upregulates p21(WAF1/CIP1) transcription is by preventing the small GTPase RhoA from repressing p21(WAF1/CIP1) induction.

The type II transforming growth factor (TGF)-beta receptor-interacting protein TRIP-1 acts as a modulator of the TGF-beta response

The transforming growth factor-beta (TGF-beta) receptor interacting protein TRIP-1 was originally identified as a WD40 repeat-containing protein that has the ability to associate with the TGF-beta type II receptor and is phosphorylated by it (1). However, its function was not known. We now show that TRIP-1 expression represses the ability of TGF-beta to induce transcription from the plasminogen activator inhibitor-1 promoter, a common reporter of the TGF-beta-induced gene expression response, but does not affect the ability of TGF-beta to inhibit cyclin A transcription. TRIP-1 can also inhibit the plasminogen activator inhibitor-1 expression induced by Smads as well as activated TGF-beta type I receptors. Its inhibitory effect is exerted by a combination of receptor-dependent and receptor-independent mechanisms. Deletion mutational analysis revealed that two distinct regions, which do not contain recognizable WD40 repeats, are required for the ability of TRIP-1 to inhibit the gene expression response. Expression of other segments of TRIP-1 increased the TGF-beta-induced gene expression response and therefore may exert a dominant negative phenotype. We conclude that TRIP-1 acts as a modulator of the TGF-beta response.

TGF-beta: a balancing act

Regulation of developmental processes as well as host defense and repair mechanisms requires the maintenance of a delicate balance of positive and negative regulatory signals. TGF-beta, a molecule known for its many diverse activities, can promote or inhibit cell growth and function. Disruption of the balance between these opposing activities can contribute to aberrant development, malignancy, or pathogenic immune and inflammatory responses. TGF-beta transgenic mouse studies highlight the essential function(s) of TGF-beta and its receptors and provide insight to potential therapeutic approaches to manipulate TGF-beta expression.

TGF-beta-signaling with small molecule FKBP12 antagonists that bind myristoylated FKBP12-TGF-beta type I receptor fusion proteins

BACKGROUND

Growth arrest in many cell types is triggered by transforming growth factor beta (TGF-beta), which signals through two TGF-beta receptors (type I, TGF-beta RI, and type II, TGF-beta). In the signaling pathway, TGF-beta binds to the extracellular domain of TGF-betaRII, which can then transphosphorylate TGF-betaRI in its glycine/serine (GS)-rich box. Activated TGF-betaRI phosphorylates two downstream effectors, Smad2 and Smad3, leading to their translocation into the nucleus. Cell growth is arrested and plasminogen activator inhibitor 1 (PAI-1) is upregulated. We investigated the role of the immunophilin FKBP12, which can bind to the GS box of TGF-betaRI, in TGF-beta signaling.

RESULTS

Overexpression of myristoylated TGF-betaRI and TGF-betaRII cytoplasmic tails caused constitutive nuclear translocation of a green-fluorescent-protein-Smad2 construct in COS-1 cells, and constitutive activation of a PAI-1 reporter plasmid in mink lung cells. Fusing FKBP12 to TGF-betaRI resulted in repression of autosignaling that could be alleviated by FK506M or rapamycin (two small molecules that can bind to FKBP12). Mutation of the FKBP12-binding site in the FKBP1-TGF-betaRI fusion protein restored constitutive signaling. An acidic mutation in the FKBP12-TGF-betaRI protein allowed FKBP12 antagonists to activate signaling in the absence of TGF-betaRII. Further mutations in the TGF-betaRI FKBP12-binding site resulted in TGF-beta signaling that was independent of both TGF-betaRII and FKBP12 antagonists.

CONCLUSIONS

Fusing FKBP12 to TGF-betaRI results in a novel receptor that is activated by small molecule FKBP12 antagonists. These results suggest that FKBP12 binding to TGF-betaRI is inhibitory and that FKBP12 plays a role in inhibiting TGF-beta superfamily signals.

Interaction of Drosophila inhibitors of apoptosis with thick veins, a type I serine/threonine kinase receptor for decapentaplegic

Decapentaplegic (Dpp) is a Drosophila member of bone morphogenetic proteins, which belong to the transforming growth factor-beta superfamily. Members of this family regulate a variety of biological processes such as cell proliferation, morphogenesis, immune response, and apoptosis. Dpp plays a critical role in many aspects of Drosophila development. Members of the transforming growth factor-beta superfamily bind to two different types of serine/threonine kinase receptors, termed type I and type II. Type I receptors act as downstream components of type II receptors in the receptor complexes. Therefore, intracellular proteins that interact with the type I receptors are likely to play important roles in signaling. Several proteins have been identified through protein-protein interaction screenings. We identified Drosophila inhibitor of apoptosis (DIAP) 1 as an interacting protein of a Dpp type I receptor, Thick veins (Tkv). DIAP1 associates with Tkv in vivo. The binding region in DIAP1 is mapped to its C-terminal RING finger region. DIAP2, another Drosophila member of the inhibitor of apoptosis protein family, also interacts with Tkv in vivo. These data suggest that DIAP1 and DIAP2 may be involved, possibly as negative regulators, in the Dpp signaling pathway, which leads to cell apoptosis.

A novel protein distinguishes between quiescent and activated forms of the type I transforming growth factor beta receptor

Transforming growth factor beta (TGFbeta) signal transduction is mediated by two receptor Ser/Thr kinases acting in series, type II TGFbeta receptor (TbetaR-II) phosphorylating type I TGFbeta receptor (TbetaR-I). Because the failure of interaction cloning, thus far, to identify bona fide TbetaR-I substrates might reasonably have been due to the use of inactive TbetaR-I as bait, we sought to identify molecules that interact specifically with active TbetaR-I, employing the triple mutation L193A,P194A,T204D in a yeast two-hybrid system. The Leu-Pro substitutions prevent interaction with FK506-binding protein 12 (FKBP12), whose putative function in TGFbeta signaling we have previously disproved; the charge substitution at Thr204 constitutively activates TbetaR-I. Unlike previous screens using wild-type TbetaR-I, where FKBP12 predominated, none of the resulting colonies encoded FKBP12. A novel protein was identified, TbetaR-I-associated protein-1 (TRAP-1), that interacts in yeast specifically with mutationally activated TbetaR-I, but not wild-type TbetaR-I, TbetaR-II, or irrelevant proteins. In mammalian cells, TRAP-1 was co-precipitated only by mutationally activated TbetaR-I and ligand-activated TbetaR-I, but not wild-type TbetaR-I in the absence of TGFbeta. The partial TRAP-1 protein that specifically binds these mutationally and ligand-activated forms of TbetaR-I can inhibit signaling by the native receptor after stimulation with TGFbeta or by the constitutively activated receptor mutation, as measured by a TGFbeta-dependent reporter gene. Thus, TRAP-1 can distinguish activated forms of the receptor from wild-type receptor in the absence of TGFbeta and may potentially have a functional role in TGFbeta signaling.

Regulation of cellular and system function by activin

Activin is an important molecule that regulates hormonogenesis, cellular homeostasis (divide or die pathways), and differentiation programs (developmentally and in adult cells). The cellular mechanisms that integrate an activin signal into a physiological response include a binary receptor complex and tandem serine threonine kinases, intracellular signal mediators, and nuclear transcription factors. Activin antagonists (inhibins) and bioneutralizing binding proteins (follistatins) act as gating molecules to ensure accurate delivery of activin signals to cellular machinery. Correct execution of an activin cue intracellularly permits actions as fundamental as embryonic mesoderm development, neuronal survival, hematopoietic function, and reproductive cyclicity. Absent or incorrect activin signaling results in phenotypes as catastrophic as embryonic lethality, tumor formation, and infertility. The general ways in which a cell senses and responds to an activin signal will be reviewed in the first part of this paper. The role of this ligand in reproductive function will also be examined as a specific example of activin activity.

TGF-beta signal transduction

The transforming growth factor beta (TGF-beta) family of growth factors control the development and homeostasis of most tissues in metazoan organisms. Work over the past few years has led to the elucidation of a TGF-beta signal transduction network. This network involves receptor serine/threonine kinases at the cell surface and their substrates, the SMAD proteins, which move into the nucleus, where they activate target gene transcription in association with DNA-binding partners. Distinct repertoires of receptors, SMAD proteins, and DNA-binding partners seemingly underlie, in a cell-specific manner, the multifunctional nature of TGF-beta and related factors. Mutations in these pathways are the cause of various forms of human cancer and developmental disorders.

TGF-beta signalling from cell membrane to nucleus through SMAD proteins

The recent identification of the SMAD family of signal transducer proteins has unravelled the mechanisms by which transforming growth factor-beta (TGF-beta) signals from the cell membrane to the nucleus. Pathway-restricted SMADs are phosphorylated by specific cell-surface receptors that have serine/threonine kinase activity, then they oligomerize with the common mediator Smad4 and translocate to the nucleus where they direct transcription to effect the cell's response to TGF-beta. Inhibitory SMADs have been identified that block the activation of these pathway-restricted SMADs.

Insulin stimulates the phosphorylation and activity of farnesyltransferase via the Ras-mitogen-activated protein kinase pathway

Farnesylation of p21Ras by farnesyltransferase (FTase) is obligatory for anchoring p21Ras to the plasma membrane, where it can be activated by growth factors. Insulin significantly stimulates the phosphorylation of the alpha-subunit of FTase (4-fold) and the enzymatic activity of FTase in 3T3-L1 fibroblasts and adipocytes. FTase activity was assessed by the amount of [3H] mevalonate (a precursor of farnesyl) incorporated into p21Ras in vivo and by quantitating the amount of farnesylated p21Ras before and after insulin administration. Insulin-stimulated phosphorylation of the alpha-subunit of FTase in 3T3-L1 fibroblasts and adipocytes was blocked by the mitogen-activated protein/extracellular-signal regulated kinase-kinase inhibitor, PD98059, but not by wortmannin or bisindolylmaleimide. Additionally, PD98059 blocked insulin-stimulated [3H]mevalonic incorporation and farnesylation of unprocessed p21Ras in both cell lines. Furthermore, expression of the dominant negative mutant of p21Ras precluded insulin-stimulated phosphorylation of the FTase alpha-subunit and activation of its enzymatic activity. In contrast, 3T3-L1 fibroblasts, expressing the constitutively active Raf-1, exhibited enhanced phosphorylation of the FTase alpha-subunit. It seems that insulin's effect on the phosphorylation and activation of FTase in both fibroblasts and adipocytes is mediated via the Ras pathway, resulting in a positive feedback augmentation of the cellular pool of farnesylated p21Ras.

p21ras farnesyltransferase alpha- and beta-subunits are phosphorylated in PC-12 cells: TGF-beta signaling pathway independent phosphorylation

Farnesyltransferase (FTase) catalyzes the transfer of a farnesyl isoprenoid to the conserved carboxyl-terminal cysteine residue of proteins terminating with the CAAX sequence. Rat brain FTase is a heterodimer consisting of a 49 kDa alpha-subunit and a 46 kDa beta-subunit. In this report, we show, for the first time, that the beta-subunit of FTase is phosphorylated in vivo and the FTase heterodimer contains phosphorylated alpha/beta-subunits in rat adrenal medulla pheocytochroma PC-12 cells. The presence of the phosphorylated FTase subunits as heterodimer in PC-12 cells which are known to be deficient in TGF-beta signaling pathways argues against the involvement of this pathway in their phosphorylation and heterodimerization.

Farnesyltransferase inhibitors versus Ras inhibitors

Over the past few years, the idea that farnesyl-protein transferase (FPTase) inhibitors might be effective antiproliferative/antitumor agents has been realized in studies of cultured cells and in rodent models of cancer. Most of the studies with FPTase inhibitors have focused on inhibiting the growth of ras-transformed cells in vitro or the growth of ras-dependent tumors in mice. More recently, it has been recognized that the antiproliferative effect of FPTase inhibitors may extend beyond ras-driven tumors. It now seems likely that the ability of FPTase inhibitors to reverse the malignant phenotype results, at least in part, from inhibiting the farnesylation of proteins other than Ras.

Transforming growth factor-beta: the breaking open of a black box

Transforming growth factor-beta (TGF-beta) and its related proteins regulate broad aspects of body development, including cell proliferation, differentiation, apoptosis and gene expression, in various organisms. Deregulated TGF-beta function has been causally implicated in the generation of human fibrotic disorders and in tumor progression. Nevertheless, the molecular mechanisms of TGF-beta action remained essentially unknown until recently. Here, we discuss recent progress in our understanding of the mechanism of TGF-beta signal transduction with respect to the regulation of gene expression, the control of cell phenotype and the potential usage of TGF-beta for the treatment of human diseases.

Heteromeric and homomeric interactions correlate with signaling activity and functional cooperativity of Smad3 and Smad4/DPC4

Homologs of Drosophila Mad function as downstream mediators of the receptors for transforming growth factor beta (TGF-beta)-related factors. Two homologs, the receptor-associated Smad3 and the tumor suppressor Smad4/DPC4, synergize to induce ligand-independent TGF-beta activities and are essential mediators of the natural TGF-beta response. We now show that Smad3 and Smad4 associate in homomeric and heteromeric interactions, as assessed by yeast two-hybrid and coimmunoprecipitation analyses. Heteromeric interactions are mediated through the conserved C-terminal domains of Smad3 and Smad4. In Smad3, the homomeric interaction is mediated by the same domain. In contrast, the homomeric association of Smad4 requires both the N-terminal domain and the C-terminal domain, which by itself does not homomerize. Mutations that have been associated with impaired Mad activity in Drosophila or decreased tumor suppressor activity of Smad4/DPC4 in pancreas cancer, including a short C-terminal truncation and two point mutations in the conserved C-terminal domains, impair the ability of Smad3 and Smad4 to undergo homo- and heteromeric associations. Analyses of the biological activity of Smad3 and Smad4 and their mutants show that full signaling activity correlates with their ability to undergo efficient homo- and heteromeric interactions. Mutations that interfere with these interactions result in decreased signaling activity. Finally, we evaluated the ability of Smad3 or Smad4 to induce transcriptional activation in yeast. These results correlate the ability of individual Smads to homomerize with transcriptional activation and additionally with their biological activity in mammalian cells.

The TGF-beta family mediator Smad1 is phosphorylated directly and activated functionally by the BMP receptor kinase

Bone morphogenetic proteins (BMPs) are members of the TGF-beta family that regulate cell proliferation, apoptosis, and differentiation, and participate in the development of most tissues and organs in vertebrates. Smad proteins function downstream of TGF-beta receptor serine/threonine kinases and undergo serine phosphorylation in response to receptor activation. Smad1 is regulated in this fashion by BMP receptors, and Smad2 and Smad3 by TGF-beta and activin receptors. Here, we report that BMP receptors phosphorylate and activate Smad1 directly. Phosphorylation of Smad1 in vivo involves serines in the carboxy-terminal motif SSXS. These residues are phosphorylated directly by a BMP type I receptor in vitro. Mutation of these carboxy-terminal serines prevents several Smad1 activation events, namely, Smad1 association with the related protein DPC4, accumulation in the nucleus, and gain of transcriptional activity. Similar carboxy-terminal serines in Smad2 are required for its phosphorylation and association with DPC4 in response to TGF-beta, indicating the generality of this process of Smad activation. As a direct physiological substrate of BMP receptors, Smad1 provides a link between receptor serine/threonine kinases and the nucleus.

MADR2 is a substrate of the TGFbeta receptor and its phosphorylation is required for nuclear accumulation and signaling

MAD-related (MADR) proteins are essential intracellular components of TGFbeta signaling pathways and are regulated by phosphorylation. Here, we demonstrate that MADR2 and not the related protein DPC4 transiently interacts with the TGFbeta receptor and is directly phosphorylated by the complex on C-terminal serines. Interaction of MADR2 with receptors and phosphorylation requires activation of receptor I by receptor II and is mediated by the receptor I kinase. Mutation of the phosphorylation sites generates a dominant negative MADR2 that blocks TGFbeta-dependent transcriptional responses, stably associates with receptors, and fails to accumulate in the nucleus in response to TGFbeta signaling. Thus, transient association and phosphorylation of MADR2 by the TGFbeta receptor is necessary for nuclear accumulation and initiation of signaling.

Signal transduction by members of the transforming growth factor-beta superfamily

Transforming growth factor-beta (TGF beta) superfamily members exert their diverse biological effects through their interaction with heteromeric receptor complexes of transmembrane serine/threonine kinases. Both components of the receptor complex, known as receptor I and receptor II are essential for signal transduction. The composition of these complexes can vary significantly due to the promiscuous nature of the ligands and the receptors, and this diversity of interactions can yield a variety of biological responses. Several receptor interacting proteins and potential mediators of signal transduction have now been identified. Recent advances, particularly in our understanding of the function of Mothers against dpp-related (MADR) proteins, are providing new insights into how the TGF beta superfamily signals its diverse biological activities.