Palmatine suppresses glutamine-mediated interaction between pancreatic cancer and stellate cells through simultaneous inhibition of survivin and COL1A1.

Reciprocal interaction between pancreatic stellate cells (PSCs) and cancer cells (PCCs) in the tumor microenvironment (TME) promotes tumor cell survival and progression to lethal, therapeutically resistant pancreatic cancer. The goal of this study was to test the ability of Palmatine (PMT) to disrupt this reciprocal interaction in vitro and examine the underlying mechanism of interaction. We show that PSCs secrete glutamine into the extracellular environment under nutrient deprivation. PMT suppresses glutamine-mediated changes in GLI signaling in PCCs resulting in the inhibition of growth and migration while inducing apoptosis by inhibition of survivin. PMT-mediated inhibition of (glioma-associated oncogene 1) GLI activity in stellate cells leads to suppression (collagen type 1 alpha 1) COL1A1 activation. Remarkably, PMT potentiated gemcitabine's growth inhibitory activity in PSCs, PCCs and inherently gemcitabine-resistant pancreatic cancer cells. This is the first study that shows the ability of PMT to inhibit growth of PSCs and PCCs either alone or in combination with gemcitabine. These studies warrant additional investigations using preclinical models to develop PMT as an agent for clinical management of pancreatic cancer.

Comparative systems toxicology analysis of cigarette smoke and aerosol from a candidate modified risk tobacco product in organotypic human gingival epithelial cultures: A 3-day repeated exposure study.

Smoking is one of the major lifestyle-related risk factors for periodontal diseases. Modified risk tobacco products (MRTP) offer a promising alternative in the harm reduction strategy for adult smokers unable to quit. Using a systems toxicology approach, we investigated and compared the exposure effects of a reference cigarette (3R4F) and a heat-not-burn technology-based candidate MRTP, the Tobacco Heating System (THS) 2.2. Human gingival epithelial organotypic cultures were repeatedly exposed (3 days) for 28 min at two matching concentrations of cigarette smoke (CS) or THS2.2 aerosol. Results showed only minor histopathological alterations and minimal cytotoxicity upon THS2.2 aerosol exposure compared to CS (1% for THS2.2 aerosol vs. 30% for CS, at the high concentration). Among the 14 proinflammatory mediators analyzed, only 5 exhibited significant alterations with THS2.2 exposure compared with 11 upon CS exposure. Transcriptomic and metabolomic analysis indicated a general reduction of the impact in THS2.2 aerosol-exposed samples with respect to CS (∼79% lower biological impact for the high THS2.2 aerosol concentration compared to CS, and 13 metabolites significantly perturbed for THS2.2 vs. 181 for CS). This study indicates that exposure to THS2.2 aerosol had a lower impact on the pathophysiology of human gingival organotypic cultures than CS.

A strategically designed small molecule attacks alpha-ketoglutarate dehydrogenase in tumor cells through a redox process.

BACKGROUND: Targeting cancer cell metabolism is recognized as a promising arena for development of cancer chemotherapeutics. Moreover, redox metabolism is also systematically altered in tumor cells. Indeed, there is growing reason to believe that tumor-specific alteration of redox control of metabolism will be central to understanding and attacking malignancy. We report here that lipoate analog CPI-613 attacks a gate-keeping, lipoate-using metabolic enzyme, alpha-ketoglutarate dehydrogenase (KGDH), by a redox mechanism selectively in tumors cells. RESULTS: CPI-613 inhibited KGDH function strongly and rapidly, selectively in tumor cells. Moreover, CPI-613 induced a correspondingly rapid, powerful redox signal in tumor cell mitochondria. This signal was associated with redox modification of KGDH (including extensive enzyme glutathionylation and redox blockage of enzyme lipoate sulfhydryls), correlating with KGDH inactivation. The source of this tumor-specific mitochondrial redox modulatory signal was not electron transport complexes (I or III), but was largely or entirely the E3 (dihydrolipoamide dehydrogenase) component of dehydrogenases, including KGDH. Finally, we demonstrated that KGDH activity was redox regulated (in tumor cells), as expected if a tumor-specific redox process (auto)regulates KGDH. CONCLUSIONS: Our data demonstrate that lipoate analog CPI-613 attacks redox control of KGDH activity in tumor cells, perhaps by modulation of an existing lipoate-sensitive allosteric process normally governing tumor cell KGDH activity. Together with its previously reported, mechanistically distinct (non-redox) effects on the other major, lipoate-using mitochondrial metabolic enzyme, pyruvate dehydrogenase, CPI-613's KGDH effects indicate that this agent simultaneously attacks multiple central, essential components of tumor cell metabolic regulation.

ortho-Quinone tanshinones directly inhibit telomerase through an oxidative mechanism mediated by hydrogen peroxide.

The tanshinone natural products possess a variety of pharmacological properties including anti-bacterial, anti-inflammatory, anti-oxidant, and anti-neoplastic activity. The molecular basis of these effects, however, remains largely unknown. In the present study, we explored the direct effect of tanshinones on the enzyme telomerase. Telomerase is up-regulated in the majority of cancer cells and is essential for their survival, making it a potential anti-cancer drug target. We found that the ortho-quinone tanshinone II-A inhibits telomerase in a time- and DTT-dependent fashion, and the hydrogen peroxide scavenger catalase protected telomerase from inactivation. These findings demonstrate that ortho-quinone containing tanshinones can inhibit telomerase owing to their ability to generate reactive oxygen species. The results also provide evidence that telomerase is directly and negatively regulated by reactive oxygen species.

Emerging roles of the 26S proteasome in nuclear hormone receptor-regulated transcription.

The mechanisms by which nuclear hormone receptors (NHRs) regulate transcription are highly dynamic and require interplay between a myriad of regulatory protein complexes including the 26S proteasome. Protein degradation is the most well-established role of the proteasome; however, an increasing body of evidence suggests that the 26S proteasome may regulate transcription in proteolytic and nonproteolytic mechanisms. Here we review how these mechanisms may apply to NHR-mediated transcriptional regulation. This article is part of a Special Issue entitled The 26S Proteasome: When degradation is just not enough!

Ubiquitin-dependent and ubiquitin-independent control of subunit stoichiometry in the SWI/SNF complex.

The mammalian SWI/SNF chromatin remodeling complex is a key player in multiple chromatin transactions. Core subunits of this complex, including the ATPase, Brg-1, and various Brg-1-associated factors (BAFs), work in concert to maintain a functional remodeling complex. This intra-complex regulation is supervised by protein-protein interactions, as stoichiometric levels of BAF proteins are maintained by proteasomal degradation. We show that the mechanism of BAF155-mediated stabilization of BAF57 involves blocking its ubiquitination by preventing interaction with TRIP12, an E3 ubiquitin ligase. Consequently, as opposed to complexed BAF57, whose principal lysines are unavailable for ubiquitination, uncomplexed BAF57 can be freely ubiquitinated and degraded by the proteasome. Additionally, a BAF57 mutant, which contains no lysine residues, was found to retain its ability to be stabilized by interaction with BAF155, suggesting that in addition to the ubiquitin-dependent mechanism of BAF57 degradation, there exists a ubiquitin-independent mechanism that may involve the direct interaction of BAF57 with the proteasome. We propose that this regulatory mechanism exists to ensure functional fidelity of the complex and prevent the accumulation of uncomplexed proteins, which may disrupt the normal activity of the complex.

BRACO19 analog dimers with improved inhibition of telomerase and hPot 1.

Human chromosomes terminate with telomeres, which contain double-stranded G-rich, repetitive DNA followed by a single-stranded overhang of the G-rich sequence. Single-stranded oligonucleotides containing G-rich telomeric repeats have been observed in vitro to fold into a variety of G-quadruplex topologies depending on the solution conditions. G-quadruplex structures are notable in part because G-quadruplex ligands inhibit both the enzyme telomerase and other telomere-binding proteins. Because telomerase is required for growth by the majority of cancers, G-quadruplex-stabilizing ligands have become an attractive platform for anticancer drug discovery. Here, we present the preparation and biochemical activities of a novel series of 3,6-disubstituted acridine dimers modeled after the known G-quadruplex ligand BRACO19. These BRACO19 Analog Dimer (BAD) ligands were shown to bind to human telomeric DNA and promote the formation of intramolecular G-quadruplexes in the absence of monovalent cations. As expected, the BAD ligands bound to telomeric DNA with a 1:1 stoichiometry, whereas the parent compound BRACO19, a monomer, bound with a 2:1 stoichiometry. The BAD ligands exhibited potent inhibition of human telomerase with IC(50) values similar to or lower than those of BRACO19. Furthermore, the BAD ligands displayed greater potency in the inhibition of hPot1 and increased selectivity for G-quadruplex DNA when compared to BRACO19. Collectively, these experiments support the hypothesis that there is an increased potency and selectivity to be gained in the design of G-quadruplex-stabilizing agents that incorporate multiple interactions.

Chromatin-modifying enzymes as therapeutic targets--Part 2.

BACKGROUND: Part 1 of this review described the importance of histone acetylases, deacetylases, methylases and demethylases in transcriptional control and their potential as therapeutic targets. However, precise gene regulation requires the involvement of more than just the addition or removal of acetyl and methyl groups on histones. Histone phosphorylation, ubiquitylation, SUMOylation and poly-ADP-ribosylation, as well as ATP-dependent nucleosome remodeling complexes, play equally pivotal roles in the maintenance of transcriptional fidelity. Accordingly, the enzymes responsible for these modifications are also misregulated in various disease states. OBJECTIVE: To review the complex roles of chromatin-modifying enzymes in gene regulation and to highlight their potential as therapeutic targets. METHODS: This review is based on recent published literature and online resources. RESULTS/CONCLUSION: In this second and final part of the review, we discuss the importance of these other histone and nucleosome modifying enzymes in gene transcription as well as their therapeutic potential.

Chromatin-modifying enzymes as therapeutic targets--Part 1.

BACKGROUND: Disease pathogenesis may result from genetic alterations and/or a more diverse group of epigenetic changes. While events such as DNA methylation are well established, there is significant interest in nucleosome remodeling, RNA interference and histone modifications, as mechanisms that underlie epigenetic effects. While genetic mutations are permanent, epigenetic changes can be transitory. The potential to reverse epigenetic changes has led to the development of therapeutic strategies targeting chromatin-modifying enzymes. OBJECTIVE: To review the roles of chromatin-modifying enzymes in gene regulation and to highlight their potentials as therapeutic targets. METHODS: This review is based on recently published literature and online resources. RESULTS/CONCLUSION: This paper focuses on enzymes responsible for histone acetylation, deacetylation, methylation and demethylation, and their potential as targets for epigenetic therapies. A subsequent paper will do the same for enzymes responsible for histone phosphorylation, ubiquitylation, SUMOylation and poly-ADP-ribosylation as well as ATP-dependent nucleosome remodeling.

Electron microscopic visualization of telomerase from Euplotes aediculatus bound to a model telomere DNA.

Binding of the telomerase ribonucleoprotein from the ciliate Euplotes aediculatus to telomeric DNA in vitro has been examined by electron microscopy (EM). Visualization of the structures that formed revealed a globular protein complex that localized to the DNA end containing the E. aediculatus telomere consensus 3'-single-strand T(4)G(4)T(4)G(4)T(4)G(2) overhang. Gel filtration confirmed that purified E. aediculatus telomerase is an active dimer in solution, and comparison of the size of the DNA-associated complex with apoferritin suggests that E. aediculatus telomerase binds to a single telomeric 3'-end as a dimer. Up to 43% of the telomerase-DNA complexes appeared by EM to involve tetramers or larger multimers of telomerase in association with two or more DNA ends. These data provide the first direct evidence that telomerase is a functional dimer and suggest that two telomerase ribonucleoprotein particles cooperate to elongate each Euplotes telomere in vivo.

The biochemical role of the heat shock protein 90 chaperone complex in establishing human telomerase activity.

Telomerase is a ribonucleoprotein complex that synthesizes the G-rich DNA found at the 3'-ends of linear chromosomes. Human telomerase consists minimally of a catalytic protein (hTERT) and a template-containing RNA (hTR), although other proteins are involved in regulating telomerase activity in vivo. Several chaperone proteins, including hsp90 and p23, have demonstrable roles in establishing telomerase activity both in vitro and in vivo, and previous reports indicate that hsp90 and p23 are required for the reconstitution of telomerase activity from recombinant hTERT and hTR. Here we report that hTERT and hTR associate in the absence of a functional hsp90-p23 heterocomplex. We also report that hsp90 inhibitors geldanamycin and novobiocin inhibit recombinant telomerase even after telomerase is assembled. Inhibition by geldanamycin could be overcome by allowing telomerase to first bind its primer, suggesting a role for hsp90 in loading telomerase onto the telomere. Inhibition by novobiocin could not similarly be overcome but instead resulted in destabilization of the hTERT polypeptide. We propose that the hsp90-p23 complex fine tunes and stabilizes a functional telomerase structure, allowing primer loading and extension.

A high-throughput assay for a human telomerase protein-human telomerase RNA interaction.

The rapid rate at which cancer cells divide necessitates a mechanism for telomere maintenance, and in approximately 90% of all cancer types the enzyme telomerase is used to maintain the length of telomeric DNA. Telomerase is a multi-subunit enzyme that minimally contains a catalytic protein subunit, hTERT, and an RNA subunit, hTR. Proper assembly of telomerase is critical for its enzymatic activity and therefore is a requirement for the proliferation of most cancer cells. We have developed the first high-throughput screen capable of identifying small molecules that specifically perturb human telomerase assemblage. The screen uses a scintillation proximity assay to identify compounds that prevent a specific and required interaction between hTR and hTERT. Rather than attempting to disrupt all of the individual hTR-hTERT interactions, we focused the screen on the interaction of the CR4-CR5 domain of hTR with hTERT. The screen employs a biotin-labeled derivative of the CR4-CR5 domain of hTR that independently binds [(35)S]hTERT in a functionally relevant manner. The complex between hTERT and biotin-labeled RNA can be captured on streptavidin-coated scintillation proximity beads. Use of 96-well filter plates and a vacuum manifold enables rapid purification of the beads. After optimization, statistical evaluation of the screen generated a Z' factor of 0.6, demonstrating the high precision of the assay.

Nucleic acid-binding ligands identify new mechanisms to inhibit telomerase.

We screened a small library of known nucleic acid-binding ligands in order to identify novel inhibitors of recombinant human telomerase. Inhibitory compounds were classified into two groups: Group I inhibitors had a notably greater effect when added prior to telomerase assemblage and Group II inhibitors displayed comparable inhibition when added before or after telomerase assemblage. Hoechst 33258, a Group I inhibitor, was found to interact tightly (KD = 0.36 microM) with human telomerase RNA (hTR) leading us to propose that hTR is the molecular target for this and other Group I inhibitors. Our results suggest that hTR can be exploited as a small-molecule drug target and provide several new structural motifs for the further development of novel telomerase inhibitors.

Inhibition of telomerase activity by preventing proper assemblage.

Telomerase is a ribonucleoprotein complex that acts as a reverse transcriptase in the maintenance of chromosome ends. Because the vast majority of cancer cells require telomerase activity, telomerase has become a target for anticancer drug discovery. Here, we describe a new approach for targeting telomerase by blocking the association between the telomerase catalytic subunit, hTERT, and key elements of the human telomerase RNA subunit, hTR. By examining the effects of oligonucleotides that hybridize to various regions of hTR, we identified two regions of the RNA subunit that are sensitive to molecular interactions leading to telomerase inhibition. Oligonucleotides that hybridize to either the P3/P1 pairing region or to the CR4-CR5 domain of hTR, hTRas009, and hTRas010, respectively, inhibit telomerase activity when added to recombinant hTERT and hTR prior to assemblage. However, addition of hTRas009 or hTRas010 to preassembled telomerase resulted in little or no inhibition. We also examined the ability of hTRas009 and hTRas010 to inhibit binding of hTR and hTR fragments to hTERT. We found that hTRas009 inhibited approximately 50% of the maximum binding between the pseudoknot fragment of hTR (nucleotides 46-209) and hTERT, whereas hTRas010 inhibited over 90% of the maximum binding between the CR4-CR5 fragment of hTR (nucleotides 243-328) and hTERT. In addition, neither oligonucleotide was able to appreciably inhibit the binding of full-length hTR to hTERT, although both oligonucleotides used in conjunction decreased binding by approximately 50%. We propose that the P3/P1 pairing region and CR4-CR5 domain represent viable targets to inhibit telomerase by perturbing proper assemblage of the active complex.