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Query: UNIPROT:P04637 (
p53
)
77,613
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
MDM2 associates with ribosomal protein S7, and this interaction is required to inhibit MDM2's E3 ligase activity, leading to stabilization of MDM2 and
p53
. Notably, the MDM2 homolog
MDMX
facilitates the inhibition of MDM2 E3 ligase activity by S7. Further, ablation of S7 inhibits MDM2 and
p53
accumulation induced by different stress signals in some cell types. Thus, ribosomal/nucleolar stress is likely a key integrating event in DNA damage signaling to
p53
. Interestingly, S7 is itself a substrate for MDM2 E3 ligase activity both in vitro and in vivo. An S7-ubiquitin fusion protein (S7-Ub) selectively inhibits MDM2 degradation of
p53
and is unaffected by
MDMX
. S7-Ub promotes apoptosis to a greater extent than S7 alone. This indicates that MDM2 ubiquitination of S7 is involved in sustaining the
p53
response. Thus, S7 functions as both effector and affector of MDM2 to ensure a proper cellular response to different stress signals.
...
PMID:Ribosomal protein S7 is both a regulator and a substrate of MDM2. 1968 95
p53
is a major tumor suppressor protein, that binds to, and is negatively regulated by MDM2. In tumors overexpressing MDM2,
p53
function can be rescued through the disruption of the MDM2-
p53
interactions by small molecules and peptides. It is known that MDM2 also binds p73 but not p63, the two homologues of
p53
. We dissect the structural and energetic reasons underlying this discrimination and have identified a peptide that is intrinsically less helical than
p53
and yet has a higher affinity for MDM2. The increased disorder has been introduced by localizing a cationic residue in between two anionic residues, imparting a degree of frustration to the system. In addition, the introduction of a bulkier hydrophobic group towards the centre of the peptide enables the peptide to adapt a bound conformation that on the one hand is most strained, and yet enables the peptide to straddle the largest surface of MDM2, amongst all the peptides. Computations also reveal that this peptide is a dual inhibitor, binding also to
MDMX
. The computed affinity of the new peptide has been validated against MDM2 using fluorescence-based thermal shift assays.
...
PMID:Design of a novel MDM2 binding peptide based on the p53 family. 1987 20
The
p53
tumour suppressor is a tightly controlled transcription factor that coordinates a broad programme of gene expression in response to various cellular stresses leading to the outcomes of growth arrest, senescence, or apoptosis. MDM2 is an E3 ubiquitin ligase that plays a key role in maintaining
p53
at critical physiological levels by targeting it for proteasome-mediated degradation. Expression of the MDM2 gene is
p53
-dependent and thus
p53
and MDM2 operate within a negative feedback loop in which
p53
controls the levels of its own regulator. Induction and activation of
p53
involves mainly the uncoupling of
p53
from its negative regulators, principally MDM2 and
MDMX
, an MDM2-related and -interacting protein that inhibits
p53
transactivation function. MDM2 is tightly regulated through various mechanisms including gene expression, protein turnover (mediated by auto-ubiquitylation), protein-protein interaction with key regulators, and post-translational modification, mainly, but not exclusively, by multisite phosphorylation. The purpose of the present article is to review our current knowledge of the signalling mechanisms that focus on MDM2, and indeed
MDMX
, through both phosphorylation mechanisms and peptide-docking events and to consider the wider implications of these regulatory events in the context of coordinated regulation of the
p53
response. This analysis also provides an opportunity to consider the signalling pathways regulating MDM2 as potential targets for non-genotoxic therapies aimed at restoring
p53
function in tumour cells.
...
PMID:The regulation of MDM2 by multisite phosphorylation--opportunities for molecular-based intervention to target tumours? 1989 41
It has long been known that traditional anticancer radio- and chemotherapies in part work through direct or indirect activation of the
p53
tumour suppressor pathway. However, many of these strategies are nonselective and genotoxic. The emerging understanding of the pathways that regulate
p53
has led to the notion that it should be possible to activate the
p53
pathway in ways that are inherently nongenotoxic. Important targets for pharmacological interference in this respect are MDM2 and
MDMX
, key negative regulators of
p53
. Genetic and pharmacologic studies suggest that blocking the physical interaction of these proteins with
p53
, or inhibiting the catalytic role of MDM2 in tagging
p53
for proteasomal degradation, both of which lead to an increase in the transcriptional activity of
p53
, may indeed be an efficient and safe way to eradicate tumour cells that retain wild-type
p53
. Here we review the rationale for such strategies, as well as the current state in the discovery and development of drugs that reactivate
p53
by inhibiting its inhibitors MDM2 and
MDMX
. The first compounds that have been shown in model systems to be able selectively to kill cancer cells in this way are now entering clinical trials and the promise of MDM2 inhibitors as a new therapeutic anticancer modality should therefore become clear in the not-too-distant future.
...
PMID:Small-molecule inhibitors of MDM2 as new anticancer therapeutics. 1989 42
MDM2 and
MDMX
function as key regulators of
p53
by binding to its N terminus, inhibiting its transcriptional activity, and promoting degradation. MDM2 and
MDMX
overexpression or hyperactivation directly contributes to the loss of
p53
function during the development of nearly 50% of human cancers. Recent studies showed that disrupting
p53
-MDM2 and
p53
-
MDMX
interactions can lead to robust activation of
p53
but also revealed a need to develop novel dual specific or
MDMX
-specific inhibitors. Using phage display we identified a 12-residue peptide (pDI) with inhibitory activity against MDM2 and
MDMX
. The co-crystal structures of the pDI and a single mutant derivative (pDI6W) liganded with the N-terminal domains of human
MDMX
and MDM2 served as the basis for the design of 11 distinct pDI-derivative peptides that were tested for inhibitory potential. The best derivative (termed pDIQ) contained four amino acid substitutions and exhibited a 5-fold increase in potency over the parent peptide against both MDM2 (IC(50) = 8 nm) and
MDMX
(IC(50) = 110 nm). Further structural studies revealed key molecular features enabling the high affinity binding of the pDIQ to these proteins. These include large conformational changes of the pDIQ to reach into a hydrophobic site unique to
MDMX
. The findings suggest new strategies toward the rational design of small molecule inhibitors efficiently targeting
MDMX
.
...
PMID:Structure-based design of high affinity peptides inhibiting the interaction of p53 with MDM2 and MDMX. 1991 Apr 68
Bing De Ling is a Chinese herbal formula that has been used to treat cancer patients for more than a decade. However, the molecular mechanisms behind its anti-tumor efficacy are still elusive. Here, we show that Bing De Ling inhibits cell proliferation in ovarian cancer epithelial cell lines, OV2008 and C13. It induces G1/S arrest in a
p53
-dependent manner in that this effect is attenuated in OV2008 cells transfected with dominant-negative
p53
plasmid. Moreover, we show that Bing De Ling up-regulates
p53
transcriptional activities as well as its downstream target genes, such as p21Cip1, MDM2, and
MDMX
. In addition, Bing De Ling inhibits
MDMX
-
p53
interaction which may result in stabilization and activation of
p53
. Collectively, our results suggest that the anti-tumor activity of Bing De Ling may be in part due to activation of
p53
.
...
PMID:Bing De Ling, a Chinese herbal formula, inhibits cancer cells growth via p53. 2003 72
The
p53 protein
, a guardian of the genome, is inactivated by mutations or deletions in approximately half of human tumors. While in the rest of human tumors,
p53
is expressed in wild-type form, yet it is inhibited by over-expression of its cellular regulators MDM2 and
MDMX
proteins. Although the
p53
-binding sites within the
MDMX
and MDM2 proteins are closely related, known MDM2 small-molecule inhibitors have been shown experimentally not to bind to its homolog,
MDMX
. As a result, the activity of these inhibitors including Nutlin3 is compromised in tumor cells over-expressing
MDMX
, preventing these compounds from fully activating the
p53 protein
. Here, we applied the relaxed complex scheme (RCS) to allow for the full receptor flexibility in screening for dual-inhibitors that can mutually antagonize the two
p53
-regulator proteins. First, we filtered the NCI diversity set, DrugBank compounds and a derivative library for MDM2-inhibitors against 28 dominant MDM2-conformations. Then, we screened the MDM2 top hits against the binding site of
p53
within the
MDMX
target. Results described herein identify a set of compounds that have been computationally predicted to ultimately activate the
p53
pathway in tumor cells retaining the wild-type protein.
...
PMID:Ensemble-based virtual screening reveals dual-inhibitors for the p53-MDM2/MDMX interactions. 2005 66
The
p53
pathway is disrupted in virtually every human tumor. In approximately 50% of human cancers, the
p53
gene is mutated, and in the remaining cancers, the pathway is dysregulated by genetic lesions in other genes that modulate the
p53
pathway. One common mechanism for inactivation of the
p53
pathway in tumors that express wild-type
p53
is increased expression of MDM2 or
MDMX
. MDM2 and
MDMX
bind
p53
and inhibit its function by distinct nonredundant mechanisms. Small molecule inhibitors and small peptides have been developed that bind MDM2 in the
p53
-binding pocket and displace the
p53 protein
, leading to
p53
-mediated cell cycle exit and apoptosis. To date, peptide inhibitors of
MDMX
have been developed, but no small molecule inhibitors have been reported. We have developed biochemical and cell-based assays for high throughput screening of chemical libraries to identify
MDMX
inhibitors and identified the first
MDMX
inhibitor SJ-172550. This compound binds reversibly to
MDMX
and effectively kills retinoblastoma cells in which the expression of
MDMX
is amplified. The effect of SJ-172550 is additive when combined with an MDM2 inhibitor. Results from a series of biochemical and structural modeling studies suggest that SJ-172550 binds the
p53
-binding pocket of
MDMX
, thereby displacing
p53
. This lead compound is a useful chemical scaffold for further optimization of
MDMX
inhibitors that may eventually be used to treat pediatric cancers and various adult tumors that overexpress
MDMX
or have similar genetic lesions. When combined with selective MDM2 inhibitors, SJ-172550 may also be useful for treating tumors that express wild-type
p53
.
...
PMID:Identification and characterization of the first small molecule inhibitor of MDMX. 2008 Sep 70
p53
suppresses tumor development by responding to unauthorized cell proliferation, growth factor or nutrient deprivation, and DNA damage. Distinct pathways have been identified that cause
p53
activation, including ARF-dependent response to oncogene activation, ribosomal protein-mediated response to abnormal rRNA synthesis, and ATM-dependent response to DNA damage. Elucidating the mechanisms of these signaling events are critical for understanding tumor suppression by
p53
and development of novel cancer therapeutics. More than a decade of research has established the ATM kinase as a key molecule that activates
p53
after DNA damage. Our recent study revealed that ATM phosphorylation of MDM2 is likely to be the key step in causing
p53
stabilization. Upon activation by ionizing irradiation, ATM phosphorylates MDM2 on multiple sites near its RING domain. These modifications inhibit the ability of MDM2 to poly-ubiquitinate
p53
, thus leading to its stabilization. MDM2 phosphorylation does not inactivate its E3 ligase activity per se, since MDM2 self-ubiquitination and
MDMX
ubiquitination functions are retained. The selective inhibition of
p53
poly-ubiquitination is accomplished through disrupting MDM2 oligomerization that may provide a scaffold for processive elongation of poly ubiquitin chains. These findings suggest a novel model of
p53
activation and a general mechanism of E3 ligase regulation by phosphorylation.
...
PMID:Mechanism of p53 stabilization by ATM after DNA damage. 2008 65
The N terminal transactivation domain of
p53
is regulated by ligases and coactivator proteins. The functional conformation of this region appears to be an alpha helix which is necessary for its appropriate interactions with several proteins including MDM2 and p300. Folding simulation studies have been carried out to examine the propensity and stability of this region and are used to understand the differences between the family members with the ease of helix formation following the order
p53
> p73 > p63. It is clear that hydrophobic clusters control the kinetics of helix formation, while electrostatic interactions control the thermodynamic stability of the helix. Differences in these interactions between the family members may partially account for the differential binding to, and regulation by, MDM2 (and
MDMX
). Phosphorylations of the peptides further modulate the stability of the helix and control associations with partner proteins.
...
PMID:Differences in the transactivation domains of p53 family members: a computational study. 2015 76
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