Anna Mandinova

Selective killing of cancer cells by a small molecule targeting the stress response to ROS

Malignant transformation, driven by gain-of-function mutations in oncogenes and loss-of-function mutations in tumour suppressor genes, results in cell deregulation that is frequently associated with enhanced cellular stress (for example, oxidative, replicative, metabolic and proteotoxic stress, and DNA damage). Adaptation to this stress phenotype is required for cancer cells to survive, and consequently cancer cells may become dependent upon non-oncogenes that do not ordinarily perform such a vital function in normal cells. Thus, targeting these non-oncogene dependencies in the context of a transformed genotype may result in a synthetic lethal interaction and the selective death of cancer cells. Here we used a cell-based small-molecule screening and quantitative proteomics approach that resulted in the unbiased identification of a small molecule that selectively kills cancer cells but not normal cells. Piperlongumine increases the level of reactive oxygen species (ROS) and apoptotic cell death in both cancer cells and normal cells engineered to have a cancer genotype, irrespective of p53 status, but it has little effect on either rapidly or slowly dividing primary normal cells. Significant antitumour effects are observed in piperlongumine-treated mouse xenograft tumour models, with no apparent toxicity in normal mice. Moreover, piperlongumine potently inhibits the growth of spontaneously formed malignant breast tumours and their associated metastases in mice. Our results demonstrate the ability of a small molecule to induce apoptosis selectively in cells that have a cancer genotype, by targeting a non-oncogene co-dependency acquired through the expression of the cancer genotype in response to transformation-induced oxidative stress.

A small molecule that binds Hedgehog and blocks its signaling in human cells

Small-molecule inhibition of extracellular proteins that activate membrane receptors has proved to be extremely challenging. Diversity-oriented synthesis and small-molecule microarrays enabled the discovery of robotnikinin, a small molecule that binds the extracellular Sonic Hedgehog (Shh) protein and blocks Shh-signaling in cell lines, human primary keratinocytes and a synthetic model of human skin. Shh pathway activity is rescued by small-molecule agonists of Smoothened, which functions immediately downstream of the Shh receptor Patched.

EGFR signalling as a negative regulator of Notch1 gene transcription and function in proliferating keratinocytes and cancer

The Notch1 gene has an important role in mammalian cell-fate decision and tumorigenesis. Upstream control mechanisms for transcription of this gene are still poorly understood. In a chemical genetics screen for small molecule activators of Notch signalling, we identified epidermal growth factor receptor (EGFR) as a key negative regulator of Notch1 gene expression in primary human keratinocytes, intact epidermis and skin squamous cell carcinomas (SCCs). The underlying mechanism for negative control of the Notch1 gene in human cells, as well as in a mouse model of EGFR-dependent skin carcinogenesis, involves transcriptional suppression of p53 by the EGFR effector c-Jun. Suppression of Notch signalling in cancer cells counteracts the differentiation-inducing effects of EGFR inhibitors while, at the same time, synergizing with these compounds in induction of apoptosis. Thus, our data reveal a key role of EGFR signalling in the negative regulation of Notch1 gene transcription, of potential relevance for combinatory approaches for cancer therapy.

Copper Induces the Assembly of a Multiprotein Aggregate Implicated in the Release of Fibroblast Growth Factor 1 in Response to Stress

Fibroblast growth factor (FGF) 1 is known to be released in response to stress conditions as a component of a multiprotein aggregate containing the p40 extravescicular domain of p65 synaptotagmin (Syt) 1 and S100A13. Since FGF1 is a Cu2+-binding protein and Cu2+ is known to induce its dimerization, we evaluated the capacity of recombinant FGF1, p40 Syt1, and S100A13 to interact in a cell-free system and the role of Cu2+ in this interaction. We report that FGF1, p40 Syt1, and S100A13 are able to bind Cu2+ with similar affinity and to interact in the presence of Cu2+ to form a multiprotein aggregate which is resistant to low concentrations of SDS and sensitive to reducing conditions and ultracentrifugation. The formation of this aggregate in the presence of Cu2+ is dependent on the presence of S100A13 and is mediated by cysteine-independent interactions between S100A13 and either FGF1 or p40 Syt1. Interestingly, S100A13 is also able to interact in the presence of Cu2+ with Cys-free FGF1 and this observation may account for the ability of S100A13 to export Cys-free FGF1 in response to stress. Lastly, tetrathiomolybdate, a Cu2+ chelator, significantly represses in a dose-dependent manner the heat shock-induced release of FGF1 and S100A13. These data suggest that S100A13 may be involved in the assembly of the multiprotein aggregate required for the release of FGF1 and that Cu2+ oxidation may be an essential post-translational intracellular modifier of this process.

Copper chelation represses the vascular response to injury

The induction of an acute inflammatory response followed by the release of polypeptide cytokines and growth factors from peripheral blood monocytes has been implicated in mediating the response to vascular injury. Because the Cu2+-binding proteins IL-1α and fibroblast growth factor 1 are exported into the extracellular compartment in a stress-dependent manner by using intracellular Cu2+ to facilitate the formation of S100A13 heterotetrameric complexes and these signal peptideless polypeptides have been implicated as regulators of vascular injury in vivo, we examined the ability of Cu2+ chelation to repress neointimal thickening in response to injury. We observed that the oral administration of the Cu2+ chelator tetrathiomolybdate was able to reduce neointimal thickening after balloon injury in the rat. Interestingly, although immunohistochemical analysis of control neointimal sections exhibited prominent staining for MAC1, IL-1α, S100A13, and the acidic phospholipid phosphatidylserine, similar sections obtained from tetrathiomolybdate-treated animals did not. Further, adenoviral gene transfer of the IL-1 receptor antagonist during vascular injury also significantly reduced the area of neointimal thickening. Our data suggest that intracellular copper may be involved in mediating the response to injury in vivo by its ability to regulate the stress-induced release of IL-1α by using the nonclassical export mechanism employed by human peripheral blood mononuclear cells in vitro.

The intracellular translocation of the components of the fibroblast growth factor 1 release complex precedes their assembly prior to export.

The release of signal peptideless proteins occurs through nonclassical export pathways and the release of fibroblast growth factor (FGF)1 in response to cellular stress is well documented. Although biochemical evidence suggests that the formation of a multiprotein complex containing S100A13 and Synaptotagmin (Syt)1 is important for the release of FGF1, it is unclear where this intracellular complex is assembled. As a result, we employed real-time analysis using confocal fluorescence microscopy to study the spatio-temporal aspects of this nonclassical export pathway and demonstrate that heat shock stimulates the redistribution of FGF1 from a diffuse cytosolic pattern to a locale near the inner surface of the plasma membrane where it colocalized with S100A13 and Syt1. In addition, coexpression of dominant-negative mutant forms of S100A13 and Syt1, which both repress the release of FGF1, failed to inhibit the stress-induced peripheral redistribution of intracellular FGF1. However, amlexanox, a compound that is known to attenuate actin stress fiber formation and FGF1 release, was able to repress this process. These data suggest that the assembly of the intracellular complex involved in the release of FGF1 occurs near the inner surface of the plasma membrane and is dependent on the F-actin cytoskeleton.

S100A13 mediates the copper-dependent stress- induced release of IL-1α from both human U937 and murine NIH 3T3 cells

Copper is involved in the promotion of angiogenic and inflammatory events in vivo and, although recent clinical data has demonstrated the potential of Cu2+ chelators for the treatment of cancer in man, the mechanism for this activity remains unknown. We have previously demonstrated that the signal peptide-less angiogenic polypeptide, FGF1, uses intracellular Cu2+ to facilitate the formation of a multiprotein aggregate that enables the release of FGF1 in response to stress and that the expression of the precursor form but not the mature form of IL-1α represses the stress-induced export of FGF1 from NIH 3T3 cells. We report here that IL-1α is a Cu2+-binding protein and human U937 cells, like NIH 3T3 cells, release IL-1α in response to temperature stress in a Cu2+-dependent manner. We also report that the stress-induced export of IL-1α involves the intracellular association with the Cu2+-binding protein, S100A13. In addition, the expression of a S100A13 mutant lacking a sequence novel to this gene product functions as a dominant-negative repressor of IL-1α release, whereas the expression of wild-type S100A13 functions to eliminate the requirement for stress-induced transcription. Lastly, we present biophysical evidence that IL-1α may be endowed with molten globule character, which may facilitate its release through the plasma membrane. Because Cu2+ chelation also represses the release of FGF1, the ability of Cu2+ chelators to potentially serve as effective clinical anti-cancer agents may be related to their ability to limit the export of these proinflammatory and angiogenic signal peptide-less polypeptides into the extracellular compartment.

The p53 pathway as a target in cancer therapeutics: obstacles and promise.

The complex role of the tumor suppressor p53 in normal and malignant cells complicates efforts to target it for cancer therapy. Turning Off Cancer In 1993, the tumor suppressor protein p53 was named “Molecule of the Year” by Science magazine; Daniel E. Koshland Jr., the Editor-in-Chief of Science at that time, wrote that “the excitement generated by [p53] and its fellow tumor suppressors is reaching a crescendo with exhilarating possibilities for the prevention and cure of cancer.” Now, nearly 2 decades later, where do we stand? p53—which is frequently inactivated in human malignancies—functions primarily as a transcription factor, regulating the expression of a large set of genes that affect the balance between cell growth and cell arrest in response to a variety of stressors. Mandinova and Lee review efforts to identify activators of the p53 pathway that might serve as anticancer drugs and suggest ways to optimize screens for such compounds, a number of which are now being tested in clinical trials. They also describe recent findings showing that the responses of cancer cells to p53 appear to be more complex than previously thought; for example, p53 can induce survival pathways in cancer cells in the presence of cytotoxic damage. Such pathways might, in turn, serve as targets for new cancer drugs. A large fraction of human tumors carry p53 mutations, which allow tumor initiation and progression; furthermore, it is now clear that restoration or reactivation of wild-type p53 function prompts rapid elimination of tumors. The discovery and design of compounds that reactivate or enhance the p53 pathway has resulted in the identification of promising drug candidates that have now entered clinical trials for anticancer strategies. However, some of these agents appear to elicit undesirable toxic effects on normal cells and tissues and therefore are restricted in the dose that can be applied in tumors. In this Review, we discuss the concerns about and promise of these p53 activators and propose ways to expand and optimize screening strategies to identify such molecules.

The FoxO3a gene is a key negative target of canonical Notch signalling in the keratinocyte UVB response.

Notch signalling has an important role in skin homeostasis, promoting keratinocyte differentiation and suppressing tumorigenesis. Here we show that this pathway also has an essential anti‐apoptotic function in the keratinocyte UVB response. Notch1 expression and activity are significantly induced, in a p53‐dependent manner, by UVB exposure of primary keratinocytes as well as intact epidermis of both mouse and human origin. The apoptotic response to UVB is increased by deletion of the Notch1 gene or down‐modulation of Notch signalling by pharmacological inhibition or genetic suppression of ‘canonical’ Notch/CSL/MAML1‐dependent transcription. Conversely, Notch activation protects keratinocytes against apoptosis through a mechanism that is not linked to Notch‐induced cell cycle withdrawal or NF‐κB activation. Rather, transcription of FoxO3a, a key pro‐apoptotic gene, is under direct negative control of Notch/HERP transcription in keratinocytes, and upregulation of this gene accounts for the increased susceptibility to UVB of cells with suppressed Notch signalling. Thus, the canonical Notch/HERP pathway functions as a protective anti‐apoptotic mechanism in keratinocytes through negative control of FoxO3a expression.

Identification of ROCK1 kinase as a critical regulator of Beclin1-mediated autophagy during metabolic stress

The Ser/Thr Rho kinase 1 (ROCK1) is known to play major roles in a wide range of cellular activities, including those involved in tumor metastasis and apoptosis. Here we identify an indispensable function of ROCK1 in metabolic stress-induced autophagy. Applying a proteomics approach, we characterize Beclin1, a proximal component of the PI(3)kinase class III lipid-kinase complex that induces autophagy, as an interacting partner of ROCK1. Upon nutrient deprivation, activated ROCK1 promotes autophagy by binding and phosphorylating Beclin1 at Thr119. This results in the specific dissociation of the Beclin1-Bcl-2 complex, without affecting the Beclin1-UVRAG interaction. Conversely, inhibition of ROCK1 activity increases Beclin1-Bcl-2 association, thus reducing nutritional stress-mediated autophagy. Genetic knockout of ROCK1 function in mice also leads to impaired autophagy as evidenced by reduced autophagosome formation. These results show that ROCK1 acts as a prominent upstream regulator of Beclin1-mediated autophagy and maintains a homeostatic balance between apoptosis and autophagy.