Farnesyltransferase and geranylgeranyltransferase I inhibitors upregulate RhoB expression by HDAC1 dissociation, HAT association and histone acetylation of the RhoB promoter.

Recently, we have shown that RhoB suppresses EGFR-, ErbB2-, Ras- and Akt-mediated malignant transformation and metastasis. In this paper, we demonstrate that the novel antitumor agents farnesyltransferase inhibitors (FTIs) and geranylgeranyltransferase I inhibitors (GGTIs) upregulate RhoB expression in a wide spectrum of human cancer cells including those from pancreatic, breast, lung, colon, bladder and brain cancers. RhoB induction by FTI-277 and GGTI-298 occurs at the transcriptional level and is blocked by actinomycin D. Reverse transcription-PCR experiments documented that the increase in RhoB protein levels is due to an increase in RhoB transcription. Furthermore, treatment with FTIs and GGTIs of cancer cells results in HDAC1 dissociation, HAT association and histone acetylation of the RhoB promoter. Thus, promoter acetylation is a novel mechanism by which RhoB expression levels are regulated following treatment with the anticancer agents FTIs and GGTIs.

The farnesyl transferase inhibitor, FTI-277, inhibits growth and induces apoptosis in drug-resistant myeloma tumor cells.

Mutations of the ras gene are among the most commonly identified transforming events in human cancers, including multiple myeloma. Farnesyltransferase inhibitors (FTI) were developed to prevent Ras processing and induce cancer cell death. Several FTIs are in phase II and one is in phase III clinical trials. Preclinically, most of the focus has been on solid tumors, and the effects of FTIs in multiple myeloma have not been investigated. In this study we examined the cytotoxic activity and inhibition of Ras processing in three myeloma cell lines with differing Ras mutation status. H929 cells with activated N-Ras were more sensitive to FTI-277 treatment than 8226 and U266 cells with activated K-Ras or wild-type Ras, respectively. A combination of FTI-277 and a geranylgeranyltransferase I inhibitor (GGTI)-2166 inhibited K-Ras processing and enhanced cell death in 8226 cells. U266 cells and Bcl-x(L) transfectants were equally sensitive to FTI-277 treatment. Similarly, 8226 cells selected for resistance to various chemotherapeutic agents, which resulted in either P-glycoprotein overexpression, altered topoisomerase II activity, or elevated glutathione levels, were equally sensitive to FTI-277. These preclinical studies suggest that prenylation inhibitors may represent new therapeutic agents for the treatment of refractory or drug-resistant multiple myeloma.

The farnesyltransferase inhibitor, FTI-2153, inhibits bipolar spindle formation during mitosis independently of transformation and Ras and p53 mutation status.

Recently, we have shown that the farnesyltransferase inhibitor FTI-2153 induces accumulation of two human lung cancer cell lines in mitosis by inhibiting bipolar spindle formation during prometaphase. Here we investigate whether this mitotic arrest depends on transformation, Ras and/or p53 mutation status. Using DAPI staining (DNA) and immunocytochemistry (microtubules), we demonstrate that in normal primary foreskin fibroblasts (HFF), as well as in several cancer cell lines of different origins including human ovarian (OVCAR3), lung (A-549 and Calu-1) and fibrosarcoma (HT1080), FTI-2153 inhibits bipolar spindle formation and induces a rosette morphology with a monopolar spindle surrounded by chromosomes. In both malignant cancer cell lines and normal primary fibroblasts, the percentage of prometaphase cells with bipolar spindles decreases from 67-92% in control cells to 2-28% in FTI-2153 treated cells. This inhibition of bipolar spindle formation correlates with an accumulation of cells in prometaphase. The ability of FTI-2153 to inhibit bipolar spindle formation is not dependent on p53 mutation status since both wild-type (HFF, HT1080 and A-549) and mutant (Calu-1 and OVCAR3) p53 cells were equally affected. Similarly, both wild-type (HFF and OVCAR3) and mutant (HT1080, Calu-1 and A-549) Ras cells accumulate monopolar spindles following treatment with FTI-2153. However, two cell lines, NIH3T3 (WT Ras and WT p53) and the human bladder cancer cell line, T-24 (mutant H-Ras and mutant p53) are highly resistant to FTI-2153 inhibition of bipolar spindle formation. Finally, the ability of FTI-2153 to inhibit tumor cell proliferation does not correlate with inhibition of bipolar spindle formation. Taken together these results demonstrate that the ability of FTI-2153 to inhibit bipolar spindle formation and accumulate cells in mitosis is not dependent on transformation, Ras or p53 mutation status. Furthermore, in some cell lines, FTIs inhibit growth by mechanisms other than interfering with the prophase/metaphase traverse.

Phosphotyrosyl peptides block Stat3-mediated DNA binding activity, gene regulation, and cell transformation.

Signal transducers and activators of transcription (STATs) comprise a family of cytoplasmic signaling proteins that participates in normal cellular responses to cytokines and growth factors. Frequently, however, constitutive activation of certain STAT family members, particularly Stat3, has accompanied a wide variety of human malignancies. To identify small molecule inhibitors of Stat3, we investigated the ability of the Stat3 SH2 domain-binding peptide, PY*LKTK (where Y* represents phosphotyrosine), to disrupt Stat3 activity in vitro. The presence of PY*LKTK, but not PYLKTK or PFLKTK, in nuclear extracts results in significant reduction in the levels of DNA binding activities of Stat3, to a lesser extent of Stat1, and with no effect on that of Stat5. Analyses of alanine scanning mutagenesis and deletion derivatives of PY*LKTK reveal that the Leu residue at the Y+1 position and a substituent at the Y-1 position (but not necessarily Pro) are essential for the disruption of active Stat3, thereby mapping the minimum active sequence to the tripeptide, XY*L. Studies involving bead-coupled PY*LKTK peptide demonstrate that this phosphopeptide directly complexes with Stat3 monomers in vitro, suggesting that PY*LKTK disrupts Stat3:Stat3 dimers. As evidence for the functional importance of peptide-directed inhibition of Stat3, PY*LKTK-mts (mts, membrane translocating sequence) selectively inhibits constitutive and ligand-induced Stat3 activation in vivo. Furthermore, PY*LKTK-mts suppresses transformation by the Src oncoprotein, which has been shown previously to require constitutive Stat3 activation. Altogether, we have identified a minimal peptide that inhibits Stat3 signaling and provides the conceptual basis for use of this peptide as a lead for novel peptidomimetic drug design.

Thermodynamic aspects of dicarboxylate recognition by simple artificial receptors.

Recognition of dicarboxylates by bis-functional hydrogen-bonding receptors displays divergent thermodynamics in different solvent systems. NMR titration and isothermal titration calorimetry indicated that neutral bis-urea and bis-thiourea receptors form exothermic complexes with dicarboxylates in DMSO, with a near zero entropic contribution to binding. The increased binding strength of bis-guanidinium receptors precluded quantitative measurement of binding constants in DMSO, but titration calorimetry offered a qualitative picture of the association. Formation of these 1:1 complexes was also exothermic, but additional endothermic events occurred at both lower and higher host-guest ratios. These events indicated multiple binding equilibria but did not always occur at a discrete 2:1 or 1:2 host-guest molar ratio, suggesting higher aggregates. With increasing amounts of methanol as solvent, bis-guanidinium receptors form more endothermic complexes with dicarboxylates, with a favorable entropy of association. This switch from association driven by enthalpy to one driven by entropy may reflect a change from complexation involving the formation of hydrogen bonds to that promoted by solvent liberation from binding sites.

Signaling events required for transforming growth factor-beta stimulation of connective tissue growth factor expression by cultured human lung fibroblasts.

It is possible that many of the fibrogenic effects of transforming growth factor-beta (TGF-beta) are mediated by connective tissue growth factor (CTGF). In the present work, we show that TGF-beta1 produces a 5- to 6-fold increase in CTGF expression by cultured human lung fibroblasts that is due mainly to increased transcription. The half-life of CTGF mRNA is 1.96 h, consistent with its role as a cytokine. In addition to requiring Smad activity, based upon the effects of specific inhibitors, the TGF-beta intracellular signaling pathway requires the activity of a phosphatidylcholine-specific phospholipase C, a protein kinase C, and one or more tyrosine kinases. It is also likely that the pathway requires a member of the Ras superfamily of small GTPases, but not trimeric G proteins. Pharmacologic inhibition of TGF-beta stimulation of CTGF expression may be an effective therapeutic approach to a variety of undesirable fibrotic reactions.

Functionalized oligoanthranilamides: modular and conformationally controlled scaffolds.

This paper describes the use of functionalized oligoanthranilamides as conformationally controlled scaffolds for molecular recognition. Oligomers of anthranilamides are stabilized by the formation of intramolecular six-membered hydrogen bonds in a linear strand conformation. Onto alternate anthranilic acid units, we have attached di- or tripeptide recognition units with the potential to form intramolecular hydrogen bonds to an intercalated peptide strand. Using 1H NMR dilution experiments in CDCl(3), we have observed chemical shift changes that are consistent with the formation of an extended hydrogen bonded sheet dimer. We also demonstrate that the bis-alanine functionalized strands are able to form discrete hydrogen bonded complexes with dipeptide substrates and to bind hexanoyl alanylalanine selectively over its benzyl ester. In the presence of excess hydrogen bond donors and acceptors, the oligoanthranilamide strand retained its linear conformation, pointing to the potential of this modular design as a useful and stable scaffold for molecular recognition studies.

v-Src transformation is mediated through farnesylated proteins.

Src is an oncoprotein which has been implicated in a number of human malignancies in which it has been shown to be overexpressed and highly activated. The precise mechanism of Src transformation, however, is still poorly understood. We hypothesized that Ras and other farnesylated proteins may mediate Src transformation. To test this hypothesis, v-Src-transfected rat fibroblasts (3Y1) were treated every 72 h with a 15 microM concentration of a farnesyl-transferase inhibitor (FTI). At 2 weeks, a focus formation assay was performed to assess transformation potential. Untreated and FTI-treated v-Src-transfected 3Y1 cells formed a mean of 39 (+/-2.6) and 29.8 (+/-2.9) foci per well, respectively. This 24% decrease was judged to be statistically significant (P = 0.02). Moreover, foci (>90%) in the FTI-treated wells were also consistently smaller than foci in the untreated wells. Western blots with antibody directed toward H-Ras confirmed complete inhibition of Ras farnesylation in the treated cell lines. The specificity of this inhibition was verified by Western blot using antibody specific for Rap1A. The transforming potential of v-Src is inhibited, but not eliminated by FTI treatment. This suggests that v-Src transformation is mediated in part by farnesylated proteins, one of which may be Ras.

Peptidomimetic inhibitors of protein farnesyltransferase show potent antimalarial activity.

Malaria continues to represent a very serious health problem in the tropics. The current methods of clinical treatment are showing deficiencies due to the increased incidence of resistance in the parasite. In the present paper we report the design, synthesis, and evaluation of potential antimalarial agents against a novel target, protein farnesyltransferase. We show that the most potent compounds are active against Plasmodium falciparum in vitro at submicromolar concentrations.

CEP1612, a dipeptidyl proteasome inhibitor, induces p21WAF1 and p27KIP1 expression and apoptosis and inhibits the growth of the human lung adenocarcinoma A-549 in nude mice.

The ubiquitin proteasome system is responsible for the proteolysis of important cell cycle and apoptosis-regulatory proteins. In this paper we report that the dipeptidyl proteasome inhibitor, phthalimide-(CH2)8CH-(cyclopentyl) CO-Arg(NO2)-Leu-H (CEP1612), induces apoptosis and inhibits tumor growth of the human lung cancer cell line A-549 in an in vivo model. In cultured A-549 cells, CEP1612 treatment results in accumulation of two proteasome natural substrates, the cyclin-dependent kinase inhibitors p21WAF1 and p27KIP1, indicating its ability to inhibit proteasome activity in intact cells. Furthermore, CEP1612 induces apoptosis as evident by caspase-3 activation and poly(ADP-ribose) polymerase cleavage. Treatment of A-549 tumor-bearing nude mice with CEP1612 (10 mg/kg/day, i.p. for 31 days) resulted in massive induction of apoptosis and significant (68%; P < 0.05) tumor growth inhibition, as shown by terminal deoxynucleotidyltransferase-mediated UTP end labeling. Furthermore, immunostaining of tumor specimens demonstrated in vivo accumulation of p21WAF1 and p27KIP1 after CEP1612 treatment. The results suggest that CEP1612 is a promising candidate for further development as an anticancer drug and demonstrate the feasibility of using proteasome inhibitors as novel antitumor agents.

The farnesyltransferase inhibitor, FTI-2153, blocks bipolar spindle formation and chromosome alignment and causes prometaphase accumulation during mitosis of human lung cancer cells.

Even though farnesyltransferase inhibitors (FTIs), a novel class of therapeutic agents presently in clinical trials, have preclinically outstanding anticancer activity and impressive lack of toxicity, their mechanism of action is not well understood. To enhance our understanding of how FTIs inhibit the growth of tumors, we have investigated their effects on cell cycle progression of two human lung cancer cell lines, A-549 and Calu-1. In this report, we show in synchronized A-549 and Calu-1 cells that FTI-2153 treatment resulted in a large accumulation of cells in the mitosis phase of the cell division cycle, with some cells in the G(0)/G(1) phase. Furthermore, microtubule immunostaining and 4,6-diamidino-2-phenylindole DNA staining demonstrated that the FTI-2153-induced accumulation in mitosis is due to the inability of these cells to progress from prophase to metaphase. FTI-2153 inhibited the ability of A-549 and Calu-1 cells to form bipolar spindles and caused formation of monoasteral spindles. Furthermore, FTI-2153 induced a ring-shaped chromosome morphology and inhibited chromosome alignment. Time-lapse videomicroscopy confirmed this result by showing that FTI-2153-treated cells are unable to align their chromosomes at the metaphase plate. FTI-2153 did not affect the localization to the kinetochores of two farnesylated centromeric proteins, CENP-E and CENP-F. Thus, a mechanism by which FTIs inhibit progression through mitosis and tumor growth is by blocking bipolar spindle formation and chromosome alignment.

Disruption of protein-protein interactions: design of a synthetic receptor that blocks the binding of cytochrome c to cytochrome c peroxidase.

Synthetic receptor 1 has been found via fluorescence titration to compete effectively with cytochrome c peroxidase for binding cytochrome c (Cc), forming 1:1 Cc:1 complex with a binding constant of (3 +/- 1) x 10(8) M-1, and to disrupt Cc: Apaf-1 complex, a key adduct in apoptosis.

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.

Farnesyltransferase and geranylgeranyltransferase I inhibitors in cancer therapy: important mechanistic and bench to bedside issues.

The fact that proteins such as Ras, Rac and RhoA require farnesylation or geranylgeranylation to induce malignant transformation prompted many investigators to develop farnesyltransferase (FTase) and geranylgeranyltransferase I (GGTase I) inhibitors (FTIs and GGTIs, respectively) as novel anticancer drugs. Although FTIs have been shown to antagonise oncogenic signalling, reverse malignant transformation, inhibit human tumour growth in nude mice and induce tumour regression in transgenic mice without any signs of toxicity, their mechanism of action is not known. This review will focus on important mechanistic issues as well as bench to bedside translational issues. These will include the relevance to cancer therapy of the alternative geranylgeranylation of K-Ras when FTase is inhibited; a thorough discussion about evidence for and against the involvement of inhibition of prenylation of Ras and RhoB in the mechanism of FTIs' antitumour activity as well as effects of FTIs and GGTIs on the cell cycle machinery and the dynamics of bipolar spindle formation and chromosome alignment during mitosis. Bench to bedside issues relating to the design of hypothesis-driven clinical trials with biochemical correlates for proof-of-concept in man will also be discussed. This will include Phase I issues such as determining maximally tolerated dose (MTD) versus effective biological dose (EBD), as well as whether Phase II trials are still needed for clinical evaluations of anti-signalling agents. Other questions that will be addressed include: what levels of inhibition of FTase activity are required for tumour response in Phase II clinical evaluations? What FTase substrates are most relevant as biochemical correlates? Are signalling pathways such as H-Ras/PI3K/Akt and K-Ras/Raf/MEK/Erk significant biological readouts? Does Ras mutation status predict response? What are appropriate clinical end-points for FTI Phase II trials? For this latter important question, time to tumour progression, median survival, percentage of patients that progress, clinical benefits and improvement in quality of life will all be discussed.

Direct tumor lysis by NK cells uses a Ras-independent mitogen-activated protein kinase signal pathway.

Destruction of tumor cells is a key function of lymphocytes, but the molecular processes driving it are unclear. Analysis of signal molecules indicated that mitogen-activated protein kinase (MAPK)/extracellular regulated kinase 2 critically controlled lytic function in human NK cells. We now have evidence to indicate that target ligation triggers a Ras-independent MAPK pathway that is required for lysis of the ligated tumor cell. Target engagement caused NK cells to rapidly activate MAPK within 5 min, and PD098059 effectively blocked both MAPK activation and tumoricidal function in NK cells. Target engagement also rapidly activated Ras, detected as active Ras-GTP bound to GST-Raf-RBD, a GST fusion protein linked to the Raf protein fragment containing the Ras-GTP binding domain. However, Ras inactivation by pharmacological disruption with the farnesyl transferase inhibitor, FTI-277, had no adverse effect on the ability of NK cells to lyse tumor cells or to express MAPK activation upon target conjugation. Notably, MAPK inactivation with PD098059, but not Ras inactivation with FTI-277, could interfere with perforin and granzyme B polarization within NK cells toward the contacted target cell. Using vaccinia delivery of N17 Ras into NK cells, we demonstrated that IL-2 activated a Ras-dependent MAPK pathway, while target ligation used a Ras-independent MAPK pathway to trigger lysis in NK cells.

Design of GFB-111, a platelet-derived growth factor binding molecule with antiangiogenic and anticancer activity against human tumors in mice.

We have designed a molecule, GFB-111, that binds to platelet-derived growth factor (PDGF), prevents it from binding to its receptor tyrosine kinase, and blocks PDGF-induced receptor autophosphorylation, activation of Erk1 and Erk2 kinases, and DNA synthesis. GFB-111 is highly potent (IC50 = 250 nM) and selective for PDGF over EGF, IGF-1, aFGF, bFGF, and HRGbeta (IC50 values > 100 microM), but inhibits VEGF-induced Flk-1 tyrosine phosphorylation and Erk1/Erk2 activation with an IC50 of 10 microM. GFB-111 treatment of nude mice bearing human tumors resulted in significant inhibition of tumor growth and angiogenesis. The results demonstrate the feasibility of designing novel growth factor-binding molecules with potent anticancer and antiangiogenic activity.