Activation of membrane androgen receptors in colon cancer inhibits the prosurvival signals Akt/bad in vitro and in vivo and blocks migration via vinculin/actin signaling.

Recently, we reported that membrane androgen receptors (mARs) are expressed in colon tumors triggering strong apoptotic responses. In the present study, we analyzed mAR-induced downstream effectors controlling cell survival and migration of Caco2 colon cancer cells. We show that long-term activation of mAR downregulated the activity of PI-3K and Akt and induced de-phosphorylation/activation of the proapoptotic Bad (p-Bad). Moreover, treatment of APC(Min/+) mice, which spontaneously develop intestinal tumors, with mAR-activating testosterone conjugates reduced the tumor incidence by 80% and significantly decreased the expression of p-Akt and p-Bad levels in tumor tissue. Furthermore, mAR activation strongly inhibited Caco2 cell migration. In accordance with these findings, vinculin, a protein controlling cell adhesion and actin reorganization, was effectively phosphorylated upon mAR activation. Phosphorylation inhibitors genistein and PP2 inhibited actin reorganization and restored motility. Moreover, silencing vinculin by appropriate siRNA's, or blocking actin reorganization by cytochalasin B, restored the migration potential. From these results we conclude that mAR activation inhibits the prosurvival signals Akt/Bad in vitro and in vivo and blocks migration of colon cancer cells via regulation of vinculin signaling and actin reorganization, supporting the powerful tumoristatic effect of those receptors.

Functional membrane androgen receptors in colon tumors trigger pro-apoptotic responses in vitro and reduce drastically tumor incidence in vivo.

BACKGROUND: Membrane androgen receptors (mAR) have been implicated in the regulation of cell growth, motility and apoptosis in prostate and breast cancer. Here we analyzed mAR expression and function in colon cancer. RESULTS: Using fluorescent mAR ligands we showed specific membrane staining in colon cell lines and mouse xenograft tumor tissues, while membrane staining was undetectable in healthy mouse colon tissues and non-transformed intestinal cells. Saturation/displacement assays revealed time- and concentration-dependent specific binding for testosterone with a KD of 2.9 nM. Stimulation of colon mAR by testosterone albumin conjugates induced rapid cytoskeleton reorganization and apoptotic responses, even in the presence of anti-androgens. The actin cytoskeleton drug cytochalasin B effectively inhibited the pro-apoptotic responses and caspase-3 activation. Interestingly, in vivo studies revealed that mAR activation resulted in a 65% reduction of tumor incidence in chemically induced Balb/c mice colon tumors. CONCLUSION: Our results demonstrate for the first time that functional mARs are predominantly expressed in colon tumors and that their activation results in induction of anti-tumor responses in vitro and extensive reduction of tumor incidence in vivo.

Membrane androgen receptor activation in prostate and breast tumor cells: molecular signaling and clinical impact.

In recent years, membrane androgen receptors (mARs) have been identified in prostate and breast tumor cells, and their activation by specific mAR ligands was linked to the regulation of crucial cell responses, such as cell growth, motility, and apoptosis. Analysis of the molecular signals triggered by mAR in the presence of anti-androgens has clearly differentiated mAR-dependent biological actions from those induced by the activation of the classical intracellular androgen receptors (iARs). In this review, we summarize the specific cellular events attributed to mAR activation and the experimental results on distinct non-genomic signaling cascades operating in various tumor cells independently of the iAR. Furthermore, we discuss the crucial role of actin cytoskeleton organization and signaling in mediating mAR responses. Finally, we assess the clinical impact of the reported mAR-induced apoptotic regression of prostate cancer cells both in vitro and in vivo and discuss the potential role of mAR as a novel therapeutic target.

Rho/ROCK/actin signaling regulates membrane androgen receptor induced apoptosis in prostate cancer cells.

In this study we describe a novel Rho small GTPase dependent pathway that elicits apoptotic responses controlled by actin reorganization in hormone-sensitive LNCaP- and hormone insensitive DU145-prostate cancer cells stimulated with membrane androgen receptor selective agonists. Using an albumin-conjugated steroid, testosterone-BSA, we now show significant induction of actin polymerization and apoptosis that can be reversed by actin disrupting agents in both cell lines. Testosterone-BSA triggered RhoA/B and Cdc42 activation in DU145 cells followed by stimulation of downstream effectors ROCK, LIMK2 and ADF/destrin. Furthermore, dominant-negative RhoA, RhoB or Cdc42 mutants or pharmacological inhibitors of ROCK inhibited both actin organization and apoptosis in DU145 cells. Activation of RhoA/B and ROCK was also implicated in membrane androgen receptor-dependent actin polymerization and apoptosis in LNCaP cells. Our findings suggest that Rho small GTPases are major membrane androgen receptor effectors controlling actin reorganization and apoptosis in prostate cancer cells.

Membrane androgen receptor activation triggers down-regulation of PI-3K/Akt/NF-kappaB activity and induces apoptotic responses via Bad, FasL and caspase-3 in DU145 prostate cancer cells.

BACKGROUND: Recently we have reported membrane androgen receptors-induced apoptotic regression of prostate cancer cells regulated by Rho/ROCK/actin signaling. In the present study we explored the specificity of these receptors and we analyzed downstream effectors controlling survival and apoptosis in hormone refractory DU145-prostate cancer cells stimulated with membrane androgen receptor-selective agonists. RESULTS: Using membrane impermeable conjugates of serum albumin covalently linked to testosterone, we show here down-regulation of the activity of pro-survival gene products, namely PI-3K/Akt and NF-kappaB, in DU145 cells. Testosterone-albumin conjugates further induced FasL expression. A FasL blocking peptide abrogated membrane androgen receptors-dependent apoptosis. In addition, testosterone-albumin conjugates increased caspase-3 and Bad protein activity. The actin cytoskeleton drug cytochalasin B and the ROCK inhibitor Y-27632 inhibited FasL induction and caspase-3 activation, indicating that the newly identified Rho/Rock/actin signaling may regulate the downstream pro-apoptotic effectors in DU145 cells. Finally, other steroids or steroid-albumin conjugates did not interfere with these receptors indicating testosterone specificity. CONCLUSION: Collectively, our results provide novel mechanistic insights pointing to specific pro-apoptotic molecules controlling membrane androgen receptors-induced apoptotic regression of prostate cancer cells and corroborate previously published observations on the potential use of membrane androgen receptor-agonists as novel anti-tumor agents in prostate cancer.

Functional characterization and anti-cancer action of the clinical phase II cardiac Na+/K+ ATPase inhibitor istaroxime: in vitro and in vivo properties and cross talk with the membrane androgen receptor.

Sodium potassium pump (Na+/K+ ATPase) is a validated pharmacological target for the treatment of various cardiac conditions. Recent published data with Na+/K+ ATPase inhibitors suggest a potent anti-cancer action of these agents in multiple indications. In the present study, we focus on istaroxime, a Na+/K+ ATPase inhibitor that has shown favorable safety and efficacy properties in cardiac phase II clinical trials. Our experiments in 22 cancer cell lines and in prostate tumors in vivo proved the strong anti-cancer action of this compound. Istaroxime induced apoptosis, affected the key proliferative and apoptotic mediators c-Myc and caspase-3 and modified actin cystoskeleton dynamics and RhoA activity in prostate cancer cells. Interestingly, istaroxime was capable of binding to mAR, a membrane receptor mediating rapid, non-genomic actions of steroids in prostate and other cells. These results support a multi-level action of Na+/K+ ATPase inhibitors in cancer cells and collectively validate istaroxime as a strong re-purposing candidate for further cancer drug development.

A single subunit of a heterotrimeric CCAAT-binding complex carries a nuclear localization signal: piggy back transport of the pre-assembled complex to the nucleus.

An unresolved question concerns the nuclear localization of the heterotrimeric CCAAT-binding complex, which is evolutionarily conserved in eukaryotic organisms including fungi, plants and mammals. All three subunits are necessary for DNA binding. In the filamentous fungus Aspergillus nidulans the corresponding complex was designated AnCF (A.nidulans CCAAT-binding factor). AnCF consists of the HapB, HapC and HapE subunits. Here, by using various green fluorescent protein constructs, a nuclear localization signal sequence (NLS) of the HapB protein was identified, outside of the evolutionarily conserved domain. HapB-EGFP was transported into the nucleus in both DeltahapC and DeltahapE strains, indicating that its NLS interacts with the import machinery independently of the other Hap subunits. In contrast, HapC-EGFP did not enter the nucleus in the absence of HapE or HapB. A similar finding was made for HapE-EGFP, which did not localize to the nucleus in the absence of HapC or HapB. Addition of the HapB-NLS to either HapC or HapE led to nuclear localization of the respective protein fusions, indicating that both HapC and HapE lack a functional NLS. Furthermore, these data strongly suggest that HapC and HapE have first to form a heterodimer and can be transported only as a heterodimer via the HapB protein into the nucleus. Therefore, the HapB subunit is the primary cargo for the import machinery, while HapC and HapE are transported to the nucleus only as a heterodimer and in complex with HapB via a piggy back mechanism. This enables the cell to provide equimolar concentrations of all subunits to the nucleus.

Common stemness regulators of embryonic and cancer stem cells.

Pluripotency of embryonic stem cells (ESCs) and induced pluripotent stem cells is regulated by a well characterized gene transcription circuitry. The circuitry is assembled by ESC specific transcription factors, signal transducing molecules and epigenetic regulators. Growing understanding of stem-like cells, albeit of more complex phenotypes, present in tumors (cancer stem cells), provides a common conceptual and research framework for basic and applied stem cell biology. In this review, we highlight current results on biomarkers, gene signatures, signaling pathways and epigenetic regulators that are common in embryonic and cancer stem cells. We discuss their role in determining the cell phenotype and finally, their potential use to design next generation biological and pharmaceutical approaches for regenerative medicine and cancer therapies.

Steroidal cardiac Na+/K+ ATPase inhibitors exhibit strong anti-cancer potential in vitro and in prostate and lung cancer xenografts in vivo.

Sodium potassium pump (Na(+)/K(+)ATPase) is a validated pharmacological target for the treatment of congestive heart failure. Recent data with inotropic drugs such as digoxin & digitoxin (digitalis) suggest a potent anti-cancer action of these drugs and promote Na(+)/K(+)ATPase as a novel therapeutic target in cancer. However, digitalis have narrow therapeutic indices, are pro-arrhythmic and are considered non-developable drugs by the pharmaceutical industry. On the contrary, a series of recently-developed steroidal inhibitors showed better pharmacological properties and clinical activities in cardiac patients. Their anti-cancer activity however, remained unknown. In this study, we synthesized seventeen steroidal cardiac inhibitors and explored for the first time their anti-cancer activity in vitro and in vivo. Our results indicate potent anti-cancer actions of steroidal cardiac inhibitors in multiple cell lines from different tumor panels including multi-drug resistant cells. Furthermore, the most potent compound identified in our studies, the 3-[(R)-3- pyrrolidinyl]oxime derivative 3, showed outstanding potencies (as measured by GI50, TGI and LC50 values) in most cells in vitro, was selectively cytotoxic in cancer versus normal cells showing a therapeutic index of 31.7 and exhibited significant tumor growth inhibition in prostate and lung xenografts in vivo. Collectively, our results suggest that previously described cardiac Na(+)/K(+)ATPase inhibitors have potent anti-cancer actions and may thus constitute strong re-purposing candidates for further cancer drug development.

Monomeric and oligomeric flavanols are agonists of membrane androgen receptors.

The present work reports a new mode of action of the naturally occurring flavanols catechin and epicatechin and their dimers B2 and B5, in the breast cancer T47D cell line, namely, their interaction with membrane androgen receptors. We show that monomeric and dimeric flavanols are complete (B2) or partial displacers of radiolabeled testosterone bound on T47D membranes, with affinities ranging from 1.7 (B5) to 82.2 nM (B2). In addition, they trigger the phosphorylation of the same signaling molecules (FAK, PI3K) as testosterone-BSA, minutes after binding to membrane receptors, leading to actin cytoskeleton polymerization and redistribution, with formation of filopodia and lamellipodia. The PI3K inhibitor wortmannin reverts the effect of polyphenols and testosterone-BSA, providing additional evidence about activation of a similar signaling cascade. Incubation of T47D cells for more than 2 h with polyphenols or testosterone-BSA induces apoptosis, which follows the same time-dependent pattern. We conclude that flavanols (monomers or dimers) are agonists of membrane androgen receptors and could be used as testosterone-protein conjugates for the management of tumors, in which, application of testosterone-BSA induces regression, providing additional data about the mechanism of their antiproliferative action.