Design, synthesis, and biological evaluation of substrate-competitive inhibitors of C-terminal Binding Protein (CtBP).

C-terminal Binding Protein (CtBP) is a transcriptional co-regulator that downregulates the expression of many tumor-suppressor genes. Utilizing a crystal structure of CtBP with its substrate 4-methylthio-2-oxobutyric acid (MTOB) and NAD(+) as a guide, we have designed, synthesized, and tested a series of small molecule inhibitors of CtBP. From our first round of compounds, we identified 2-(hydroxyimino)-3-phenylpropanoic acid as a potent CtBP inhibitor (IC50=0.24µM). A structure-activity relationship study of this compound further identified the 4-chloro- (IC50=0.18µM) and 3-chloro- (IC50=0.17µM) analogues as additional potent CtBP inhibitors. Evaluation of the hydroxyimine analogues in a short-term cell growth/viability assay showed that the 4-chloro- and 3-chloro-analogues are 2-fold and 4-fold more potent, respectively, than the MTOB control. A functional cellular assay using a CtBP-specific transcriptional readout revealed that the 4-chloro- and 3-chloro-hydroxyimine analogues were able to block CtBP transcriptional repression activity. This data suggests that substrate-competitive inhibition of CtBP dehydrogenase activity is a potential mechanism to reactivate tumor-suppressor gene expression as a therapeutic strategy for cancer.

Constitutive Activation of DNA Damage Checkpoint Signaling Contributes to Mutant p53 Accumulation via Modulation of p53 Ubiquitination.

UNLABELLED: Many mutant p53 proteins exhibit an abnormally long half-life and overall increased abundance compared with wild-type p53 in tumors, contributing to mutant p53's gain-of-function oncogenic properties. Here, a novel mechanism is revealed for the maintenance of mutant p53 abundance in cancer that is dependent on DNA damage checkpoint activation. High-level mutant p53 expression in lung cancer cells was associated with preferential p53 monoubiquitination versus polyubiquitination, suggesting a role for the ubiquitin/proteasome system in regulation of mutant p53 abundance in cancer cells. Interestingly, mutant p53 ubiquitination status was regulated by ataxia-telangectasia mutated (ATM) activation and downstream phosphorylation of mutant p53 (serine 15), both in resting and in genotoxin-treated lung cancer cells. Specifically, either inhibition of ATM with caffeine or mutation of p53 (serine 15 to alanine) restored MDM2-dependent polyubiquitination of otherwise monoubiquitinated mutant p53. Caffeine treatment rescued MDM2-dependent proteasome degradation of mutant p53 in cells exhibiting active DNA damage signaling, and ATM knockdown phenocopied the caffeine effect. Importantly, in cells analyzed individually by flow cytometry, p53 levels were highest in cells exhibiting the greatest levels of DNA damage response, and interference with DNA damage signaling preferentially decreased the relative percentage of cells in a population with the highest levels of mutant p53. These data demonstrate that active DNA damage signaling contributes to high levels of mutant p53 via modulation of ubiquitin/proteasome activity toward p53. IMPLICATION: The ability of DNA damage checkpoint signaling to mediate accumulation of mutant p53 suggests that targeting this signaling pathway may provide therapeutic gain. Mol Cancer Res; 14(5); 423-36. ©2016 AACR.

Inhibition of C-terminal binding protein attenuates transcription factor 4 signaling to selectively target colon cancer stem cells.

Selective targeting of cancer stem cells (CSCs), implicated in tumor relapse, holds great promise in the treatment of colorectal cancer. Overexpression of C-terminal binding protein (CtBP), an NADH dependent transcriptional regulator, is often observed in colon cancer. Of note, TCF-4 signaling is also up-regulated in colonic CSCs. We hypothesized that CtBP, whose dehydrogenase activity is amenable to pharmacological inhibition by 4-methylthio-2-oxobutyric acid (MTOB), positively regulates TCF-4 signaling, leading to CSC growth and self-renewal. CSCs demonstrated significant upregulation of CtBP1 and CtBP2 levels (mRNA and protein) and activity partly due to increased NADH/NAD ratio, as well as increased TCF/LEF transcriptional activity, compared to respective controls. Depletion of CtBP2 inhibited, while its overexpression enhanced, CSC growth (1° spheroids) and self-renewal (2°/3° spheroids). Similarly, MTOB caused a robust inhibition of spheroid growth and self-renewal in a dose dependent manner. MTOB displayed significantly greater selectivity for growth inhibition in the spheroids, at least in part through induction of apoptosis, compared to monolayer controls. Moreover, MTOB inhibited basal as well as induced (by GSK-3ß inhibitor) TCF/LEF activity while suppressing mRNA and protein levels of several ß-catenin target genes (CD44, Snail, C-MYC and LGR5). Lastly, CtBP physically interacted with TCF-4, and this interaction was significantly inhibited in the presence of MTOB. The above findings point to a novel role of CtBPs in the promotion of CSC growth and self-renewal through direct regulation of TCF/LEF transcription. Moreover, small molecular inhibition of its function can selectively target CSCs, presenting a novel approach for treatment of colorectal cancer focused on targeting of CSCs.

p53 Ubiquitination and proteasomal degradation.

p53 levels and activity are controlled in large part through regulated ubiquitination and subsequent destruction by the 26S proteasome. Monoubiquitination of p53 is mediated primarily by the RING-finger E3 ubiquitin ligase MDM2 and impacts p53 activity through modulation of p53 localization and transcription activities. Recently, several E4 ubiquitin ligases (E4s) have been identified which serve to extend these monoubiquitin chains. The ubiquitin ligase activity of these factors toward p53, and their contribution to p53 degradation, can be studied using a variety of in vitro and in vivo methods and reagents which will be described in this chapter. These methods include in vivo ubiquitination of p53 using HA-ubiquitin or his-ubiquitin; the in vitro E3 ubiquitin ligase assay, in which ubiquitin reaction components (URC) are incubated with a purified E3 or E4 ligase; a one-step E4 assay, in which URC are incubated with a substrate, E3, and E4; and a two-step E4 assay in which p53 is monoubiquitinated in an E3 reaction, and subsequently purified and incubated with an E4. Finally, we will describe an in vitro degradation assay in which ubiquitinated p53 is incubated with purified 26S proteasomes. Together, these assays can be used to provide insight into the biochemical nature of p53 ubiquitination and degradation.

It Takes 15 to Tango: Making Sense of the Many Ubiquitin Ligases of p53.

The transcription factor p53 regulates numerous cellular processes to guard against tumorigenesis. Cell-cycle inhibition, apoptosis, and autophagy are all regulated by p53 in a cell- and context-specific manner, underscoring the need for p53 activity to be kept low in most circumstances. p53 is kept in check primarily through its regulated ubiquitination and degradation by a number of different factors, whose contributions may reflect complex context-specific needs to restrain p53 activity. Chief among these E3 ubiquitin ligases in p53 homeostasis is the ubiquitously expressed proto-oncogene MDM2, whose loss renders vertebrates unable to limit p53 activity, resulting in early embryonic lethality. MDM2 has been validated as a critical, universal E3 ubiquitin ligase for p53 in numerous tissues and organisms to date, but additional E3 ligases have also been identified for p53 whose contribution to p53 activity is unclear. In this review, we summarize the recent advances in our knowledge regarding how p53 activity is apparently controlled by a multitude of ubiquitin ligases beyond MDM2.

The histone acetyltransferase PCAF regulates p21 transcription through stress-induced acetylation of histone H3.

The activity of p53 as a tumor suppressor primarily depends on its ability to transactivate specific target genes in response to genotoxic and other potentially mutagenic stresses. Several histone acetyl transferases (HATs), including p300, CBP, PCAF and GCN5 have been implicated in the activation of p53-dependent transcription of the cyclin-dependent kinase (cdk) inhibitor p21 as well as other target genes. Here we show that PCAF, but not CBP or p300, is a critical regulator of p53-dependent p21 expression in response to multiple p53-activating stresses. PCAF was required for the transcriptional activation of p21 in response to exogenous p53 in p53-null cells, nutlin-3, DNA damaging agents and p14(ARF) expression, suggesting a broad requirement for PCAF in p53 signaling to p21 after stress. Importantly, cells lacking PCAF failed to undergo cell cycle arrest in response to nutlin-3 treatment or p14(ARF) expression, consistent with a physiologically important role for PCAF in this p53 function. Surprisingly, the role for PCAF in induction of p21 was independent of p53 lysine 320 acetylation, a previously suggested target of PCAF-mediated acetylation. Though p21 promoter occupancy by p53 was not altered by PCAF knockdown, activation of p21 transcription required an intact PCAF HAT domain, and induction of chromatin marks acetyl-H3K9 and acetyl-H3K14 at the p21 promoter by p53 was dependent upon physiologic levels of PCAF. Together, our experiments indicate that PCAF is required for stress-responsive histone 3 acetylation at the p21 promoter, p53-directed transcription of p21 and the resultant growth arrest.

CBP and p300 are cytoplasmic E4 polyubiquitin ligases for p53.

p300 and CREB-binding protein (CBP) act as multifunctional regulators of p53 via acetylase and polyubiquitin ligase (E4) activities. Prior work in vitro has shown that the N-terminal 595 aa of p300 encode both generic ubiquitin ligase (E3) and p53-directed E4 functions. Analysis of p300 or CBP-deficient cells revealed that both coactivators were required for endogenous p53 polyubiquitination and the normally rapid turnover of p53 in unstressed cells. Unexpectedly, p300/CBP ubiquitin ligase activities were absent in nuclear extracts and exclusively cytoplasmic. Consistent with the cytoplasmic localization of its E3/E4 activity, CBP deficiency specifically stabilized cytoplasmic, but not nuclear p53. The N-terminal 616 aa of CBP, which includes the conserved Zn(2+)-binding C/H1-TAZ1 domain, was the minimal domain sufficient to destabilize p53 in vivo, and it included within an intrinsic E3 autoubiquitination activity and, in a two-step E4 assay, exhibited robust E4 activity for p53. Cytoplasmic compartmentalization of p300/CBP's ubiquitination function reconciles seemingly opposed functions and explains how a futile cycle is avoided-cytoplasmic p300/CBP E4 activities ubiquitinate and destabilize p53, while physically separate nuclear p300/CBP activities, such as p53 acetylation, activate p53.