Ronit Haklai

Selective Inhibition of Ras-dependent Cell Growth by Farnesylthiosalisylic Acid

S-trans,trans-Farnesylthiosalicylic acid (FTS) is a novel farnesylated rigid carboxylic acid derivative. In cell-free systems, it acts as a potent competitive inhibitor (K = 2.6 μM) of the enzyme prenylated protein methyltransferase (PPMTase), which methylates the carboxyl-terminal S-prenylcysteine in a large number of prenylated proteins including Ras. In such systems, FTS inhibits Ras methylation but not Ras farnesylation. Inhibition of the PPMTase by FTS in homogenates or membranes of a variety of tissues and cell lines is inferred from a block in the methylation of exogenously added substrates such as N-acetyl-S-trans,trans-farnesyl-L-cysteine and of endogenous substrates including small GTP-binding proteins. FTS can also inhibit methylation of these proteins in intact cells (e.g. in Rat-1 fibroblasts, Ras-transformed Rat-1, and B16 melanoma cells). Unlike in cell-free systems, however, relatively high concentrations of FTS (50-100 μM) are required for partial blocking (10-40%) of protein methylation in the intact cells. Thus, FTS is a weak inhibitor of methylation in intact cells. Because methylation is the last step in the processing of Ras and related proteins, FTS is not likely to affect steps that precede it, e.g. protein prenylation. This may explain why the growth and gross morphology of a variety of cultured cell types (including Chinese hamster ovary, NIH3T3, Rat1, B16 melanoma, and PC12) is not affected by up to 25 μM FTS and is consistent with the observed lack of FTS-induced cytotoxicity. Nevertheless, FTS reduces the levels of Ras in cell membranes and can inhibit Ras-dependent cell growth in vitro, independently of methylation. It inhibits the growth of human Ha-ras-transformed cells (EJ cells) and reverses their transformed morphology in a dose-dependent manner (0.1-10 μM). The drug does not interfere with the growth of cells transformed by v-Raf or T-antigen but inhibits the growth of ErbB2-transformed cells and blocks the mitogenic effects of epidermal and basic fibroblast growth factors, thus implying its selectivity toward Ras growth signaling, possibly via modulation of Ras-Raf communication. Taken together, the results raise the possibility that FTS may specifically interfere with the interaction of Ras with a farnesylcysteine recognition domain in the cell membrane. This drug, and perhaps other farnesylated rigid carboxylic acid analogs, may be used for in vitro characterization of the PPMTase and for the identification of a putative Ras farnesylcysteine recognition domain in cell membranes.

Disruption of cooperation between Ras and MycN in human neuroblastoma cells promotes growth arrest

Purpose: Our aim was to examine whether active Ras and MycN cooperation contributes to the malignant phenotype of human neuroblastoma with amplified MycN gene, an aggressive incurable tumor. Experimental Design: Human neuroblastoma LAN-1 cells, in which the MycN gene is amplified, were used to examine the impact of the Ras inhibitor farnesylthiosalicylic acid on cell growth, on the levels Ras and MycN proteins, and on profiles of gene expression. Results: We show that LAN-1 cells express relatively large amounts of MycN and active Ras-GTP. Inhibition of active Ras by farnesylthiosalicylic acid led to attenuation of the Raf-MEK-ERK and phosphoinositide 3-kinase-Akt-glycogen synthase-3 (GSK-3) pathways, to reduction in cyclin D1, phospho-retinoblastoma, and E2F, and to increase in the cyclin-dependent kinase inhibitor p27 and in retinoblastoma-binding protein-1, an inhibitor of E2F transcriptional activity. Ras inhibition by farnesylthiosalicylic acid or by a dominant-negative Ras also led to complete disappearance of MycN protein from the nuclei of LAN-1 cells. This was a result of blocking of Akt inactivation of GSK-3, leading to GSK-3-dependent phosphorylation with consequent proteosomal degradation of MycN. Loss of active Ras and of MycN in LAN-1 cells was manifested in profiles of gene expression that could be expected from the loss of MycN transcriptional activity and of Ras signaling. These changes explain the farnesylthiosalicylic acid–induced inhibition of LAN-1 cell growth. Conclusions: Active Ras is needed to block MycN degradation, promoting cooperative Ras- and MycN-dependent cell cycle progression in LAN-1 cells. Ras inhibitors are therefore likely candidates for the treatment of advanced neuroblastoma characterized by high expression of MycN.

Galectin‐3/MAC‐2, Ras and PI3K activate complement receptor‐3 and scavenger receptor‐AI/II mediated myelin phagocytosis in microglia

The removal of degenerated myelin is essential for repair in Wallerian degeneration that follows traumatic injury to axons and in autoimmune demyelinating diseases (e.g., multiple sclerosis). Microglia can remove degenerated myelin through phosphatidylinositol‐3‐kinase (PI3K)‐dependent phagocytosis mediated by complement receptor‐3 (CR3/MAC‐1) and scavenger receptor‐AI/II (SRAI/II). Paradoxically, these receptors are expressed in microglia after injury but myelin is not phagocytosed. Additionally, Galectin‐3/MAC‐2 is expressed in microglia that phagocytose but not in microglia that do not phagocytose, suggesting that Galectin‐3/MAC‐2 is instrumental in activating phagocytosis. S‐trans, trans‐farnesylthiosalicylic (FTS), which inhibits Galectin‐3/MAC‐2 dependent activation of PI3K through Ras, inhibited phagocytosis. K‐Ras‐GTP levels and PI3K activity increased during normal phagocytosis and decreased during FTS‐inhibited phagocytosis. Galectin‐3/MAC‐2, which binds and stabilizes active Ras, coimmunoprecipitated with Ras and levels of the coimmunoprecipitate increased during normal phagocytosis. A role for Galectin‐3/MAC‐2 dependent activation of PI3K through Ras, mostly K‐Ras, is thus suggested. An explanation may thus be offered for deficient phagocytosis by microglia that express CR3/MAC‐1 and SRAI/II without Galectin‐3/MAC‐2 and efficient phagocytosis when CR3/MAC‐1 and SRAI/II are co‐expressed with Galectin‐3/MAC‐2.

Suppression of lung cancer tumor growth in a nude mouse model by the Ras inhibitor salirasib (farnesylthiosalicylic acid)

Aberrant Ras pathway functions contribute to the malignant phenotype of lung cancers. Inhibitors of Ras might therefore be considered as potential drugs for lung cancer therapy. Here, we show that the Ras inhibitor farnesylthiosalicylic acid (salirasib) inhibits proliferation of human lung cancer cells harboring a mutated K-ras gene (A549, H23, or HTB54) or overexpressing a growth factor receptor (H1299 or HTB58) and enhances the cytotoxic effect of the chemotherapeutic drug gemcitabine. Salirasib inhibited active K-Ras in A549 cells, reversed their transformed morphology, and inhibited their anchorage-independent growth in vitro. Tumor growth in A549 and HTB58 cell nude mouse models was inhibited by i.p. administration of salirasib. P.o. formulated salirasib also inhibited A549 cell tumor growth. Our results suggest that p.o. salirasib may be considered as a potential treatment for lung cancer therapy. [Mol Cancer Ther 2007;6(6):1765–1773]

Downregulation of survivin and aurora A by histone deacetylase and RAS inhibitors: a new drug combination for cancer therapy

Histone deacetylase (HDAC) inhibitors, such as valproic acid (VPA), constitute a novel class of anticancer agents that cause an increase in acetylated histones and thus restore the expression of dormant tumor‐suppressor and other genes related to cell differentiation, cell‐cycle arrest or apoptosis of tumor cells. The Ras inhibitor farnesylthiosalicylic acid (FTS, salirasib) attenuates cancer cell proliferation in vitro and in vivo and, under certain circumstances, induces cell death. FTS by itself does not induce differentiation or complete growth arrest. The abovementioned activity of VPA as a differentiation agent suggested that it might be worth investigating its possible therapeutic potential in synergistic combination with FTS. Here, we examined whether the combined application of VPA and FTS could synergistically inhibit the proliferation of cancer cells that express oncogenic K‐Ras (A549 nonsmall‐cell lung carcinoma cells), DLD1 (colon carcinoma cells) or chronically active wild‐type K‐Ras and constitutively active B‐Raf (ARO, thyroid carcinoma cells). The results showed that combined treatment with VPA and FTS synergistically reduces proliferation in all of these cancer cell lines by downregulating Ras and blocking the expression of Survivin and Aurora A. These alterations, which were most pronounced following the combined treatment, led to a mitotic crisis, as reflected by mislocalization of the chromosomal passenger complex. Our findings thus demonstrate that combination therapy with VPA and FTS might offer a promising therapeutic approach to the treatment of epithelial tumors.

Ras inhibition attenuates myocardial ischemia-reperfusion injury

Myocardial injury, developed after a period of ischemia/reperfusion (I/R) results in the destruction of functional heart tissue, this being replaced by scar tissue. Intracellular signaling pathways mediating cardiomyocyte death are partially understood and involve the activation of Ras. p38-MAPK, JNK and Mst-1 are downstream effectors of Ras protein. We hypothesized that S-farnesylthiosalicylic acid (FTS), a synthetic small molecule that detaches Ras from the inner cell membrane, consequently inhibiting Ras activity, reduces I/R myocardial injury in vitro and in vivo. Wistar rat hearts were isolated, mounted on the Langendorff apparatus and subjected to ischemia (30 min, 37 degrees C) and reperfusion. During the reperfusion period, the hearts were perfused with FTS (1 microM) solution or control buffer. Left anterior descending (LAD) ligation and subsequent reperfusion was performed in two groups of Wistar rats. Rats received 5mg/kg FTS or PBS according to two protocols: (A) FTS or PBS were administered daily 7 days prior, immediately before and 14 days (every other day) after LAD occlusion or (B) every other day for 14 days post-I/R. Hearts from FTS-treated rats (Langendorff) and FTS-treated rats (protocol A) showed a significant improvement in myocardial performance and smaller scar tissue compared with the PBS group. Infarct size in the FTS-treated group was 12.7+/-2% vs. 23.7+/-4% in the PBS-treated (in vitro) group and 17.3+/-2.5% vs. 36+/-7% compared with control I/R rats (in vivo) p<0.05. These effects may be associated with the down regulation of JNK as a short-term effector and with Mst-1 in the long-term remodeling process.

The association between let-7, RAS and HIF-1α in Ewing Sarcoma tumor growth.

Ewing Sarcoma (ES) is the second most common primary malignant bone tumor in children and adolescents. microRNAs (miRNAs) are involved in cancer as tumor suppressors or oncogenes. We studied the involvement of miRNAs located on chromosomes 11q and 22q that participate in the most common translocation in ES. Of these, we focused on 3 that belong to the let-7 family. We studied the expression levels of let-7a, and let-7b and detected a significant correlation between low expression of let-7b and increased risk of relapse. let-7 is known to be a negative regulator of the RAS oncogene. Indeed, we detected an inverse association between the expression of let-7 and RAS protein levels and its downstream target p-ERK, following transfection of let-7 mimics and inhibitors. Furthermore, we identified let-7 as a negative regulator of HIF-1α and EWS-FLI-1. Moreover, we were able to show that HIF-1α directly binds to the EWS-FLI-1 promoter. Salirasib treatment in-vitro resulted in the reduction of cell viability, migration ability, and in the decrease of cells in S-phase. A significant reduction in tumor burden and in the expression levels of both HIF-1α and EWS-FLI-1 proteins were observed in mice after treatment. Our results support the hypothesis that let-7 is a tumor suppressor that negatively regulates RAS, also in ES, and that HIF-1α may contribute to the aggressive metastatic behavior of ES. Moreover, the reduction in the tumor burden in a mouse model of ES following Salirasib treatment, suggests therapeutic potential for this RAS inhibitor in ES.

The Ras antagonist farnesylthiosalicylic acid ameliorates experimental myocarditis in the rat

BACKGROUND Myocarditis is an inflammatory disorder of the heart in which T lymphocytes have a central role. No effective treatment is currently at hand for management of the myocarditis. Lymphocyte function requires the active signal transducer Ras. We thus hypothesized that S-farnesylthiosalicylic acid (FTS), a synthetic small molecule that detaches Ras from the inner cell membrane and induces its rapid degradation, will attenuate experimental autoimmune myocarditis (EAM). METHODS AND RESULTS Two groups of Lewis rats were induced to develop EAM by immunization with porcine cardiac myosin. Group A received 5 mg/kg of FTS, and group B received phosphate-buffered saline (PBS) according to two protocols: FTS or PBS was given 2 days before myosin immunization in protocol 1 and FTS or PBS was given 14 days after myosin immunization in protocol 2. FTS significantly suppressed myocarditis, and this effect was accompanied by a reduction in myosin-specific cellular and humoral immune responses. In the longer regimen, FTS treatment for 6 weeks was associated with preservation of myocardial function made evident by echocardiography. In vitro, FTS significantly attenuated the proliferation of lymphocytes from untreated myocarditic rats to myosin. CONCLUSIONS FTS is effective in suppressing the progression of EAM and its consequent functional myocardial dysfunction. The effect may be mediated by suppression of the cellular and humoral responses to myosin.

The ras antagonist s-farnesylthiosalicyclic acid induces inhibition of mapk activation

Inhibition of Ras-dependent signaling and of oncogenic Ras function by farnesyl transferase inhibitors that block Ras membrane anchorage is limited due to alternative prenylation of Ras. Here we demonstrate that inhibition of the Ras-dependent Raf-1-MAPK (mitogen activated protein kinase) cascade is achieved by S-farnesylthiosalicylic acid (FTS) which affects Ras membrane association but not Ras farnesylation. FTS interferes with the activation of Raf-1 and MAPK and inhibits DNA synthesis in Ras-transformed EJ cells at concentrations similar to those at which it inhibits EJ cell growth (5-25 microM). FTS also inhibits MAPK activity and DNA synthesis stimulated by serum, EGF or thrombin in serum-starved untransformed Rat-1 cells, demonstrating the generality of its effects on Ras-dependent signaling. The effects of FTS on MAPK activity developed relatively rapidly (within 2-6 h) consistent with its rapid effect on Ras membrane anchorage. FTS represents a new class of Ras antagonists that may be useful for the inhibition of various types of oncogenic Ras isoforms independently of their prenylation.

Abstract A76: Ras pathway and HIF-1α contribute to the aggressiveness of Ewing sarcoma

Aim: Ewing sarcoma (ES) is the second most common and aggressive primary malignant bone tumor in children and adolescents. The hallmarks of the tumor are specific translocations; the most frequent involves the EWS gene on chromosome 22 and the FLI-1 gene on chromosome 11. Our aim was to identify microRNAs (miRs) and genes involved in the aggressiveness of ES. Out of the miRs located on these chromosomes, 3 belong to the let-7 family. Methods: We evaluated the expression levels of hsa-let-7a and hsa-let-7b by RQ-PCR in 57 primary ES tumors. We measured the protein levels of p-ERK, HIF-1a and EWS-FLI-1 following transfection with let-7a, let-7b or HIF-1a . The effect of a Ras inhibitor was evaluated in vitro and in vivo. Results: In the group of patients with localized disease, a significant correlation with outcome was observed. Progression free survival (PFS) at ten years for patients with high hsa-let-7b expression was 62% versus 29% for those with low hsa-let-7b expression level (p=0.029). Multivariate Cox regression analysis identified expression of let-7b as an independent prognostic factor in ES, with a 4.4 fold increased risk of relapse (p=0.021). hsa-let-7 is known to be a negative regulator of the RAS oncogene. Positive p-ERK immuno-staining was detected in 31 out of the 45 (69%) tumors analyzed, and a significant inverse correlation was identified between hsa-let-7a and p-ERK (p=0.037). One of the target genes of RAS is Hypoxia inducible factor 1 (HIF-1). We detected a high level of HIF-1α protein in ES cell lines, under normoxic conditions, which did not change following induced hypoxia. This implies for a mechanism that mimics hypoxia and probably contributes to the high frequency of metastasis and thereby aggressiveness of this tumor. Following transfection with hsa-let-7a and hsa-let-7b mimics (overexpression) the levels of RAS, p-ERK, HIF-1α and EWS-FLI-1 proteins were significantly reduced (60%, p=0.0019, 52%, p=0.003, 45%, p=0.0028 and 38%, p=0.006, respectively). Silencing of HIF-1α resulted in a decrease of 61% of EWS-FLI-1, suggesting that HIF-1α regulates EWS-FLI-1, and we were able to show that HIF-1α directly binds EWS promoter. This was accompanied by a reduction of 32% (p=0.009) in cell proliferation rate and by a significant decrease of 36% (p=0.0013) in cell migration ability. Using a RAS inhibitor, Salirasib, we observed a significant decrease of HIF-1α and EWS-FLI-1 protein levels in both in-vitro and in-vivo settings. In addition, a significant inhibition of tumor growth was demonstrated in the treated animals. Conclusions: These results imply that Ras and HIF-1α might contribute to the high frequency of metastasis and thereby aggressiveness of ES tumors. The reduction in tumor burden in a mouse model of ES following Salirasib treatment, demonstrates the therapeutic potential of this RAS inhibitor in ES. Citation Format: Michal Hameiri-Grossman, Adi Porat-Klein, Ian J. Cohen, Shifra Ash, Yoel Kloog, Ronit Haklai, Galit Elad-Sfadia, Avraham Weizman, Isaac Yaniv, Smadar Avigad. Ras pathway and HIF-1α contribute to the aggressiveness of Ewing sarcoma. [abstract]. In: Proceedings of the AACR Special Conference on Pediatric Cancer at the Crossroads: Translating Discovery into Improved Outcomes; Nov 3-6, 2013; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2013;74(20 Suppl):Abstract nr A76.