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Query: UNIPROT:P04637 (
p53
)
77,613
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A wild-type (wt)
p53
gene characterizes thyroid tumors, except for the rare anaplastic histotype. Because
p53
inactivation is a prerequisite for tumor development, alterations of
p53
regulators represent an alternative way to impair
p53
function. Indeed, murine double minute 2 (MDM2), the main
p53
negative regulator, is overexpressed in many tumor histotypes including those of the thyroid. A new
p53
regulator, MDM4 (a.k.a.
MDMX
or HDMX) an analog of MDM2, represents a new oncogene although its impact on tumor properties remains largely unexplored. We estimated levels of MDM2, MDM4, and its variants, MDM4-S (originally HDMX-S) and MDM4-211 (originally HDMX211), in a group of 57 papillary thyroid carcinomas (PTC), characterized by wt tumor protein 53, in comparison to matched contra-lateral lobe normal tissue. Further, we evaluated the association between expression levels of these genes and the histopathological features of tumors. Quantitative real-time polymerase chain reaction revealed a highly significant downregulation of MDM4 mRNA in tumor tissue compared to control tissue (P<0.0001), a finding confirmed by western blot on a subset of 20 tissue pairs. Moreover, the tumor-to-normal ratio of MDM4 levels for each individual was significantly lower in late tumor stages, suggesting a specific downregulation of MDM4 expression with tumor progression. In comparison, MDM2 messenger RNA (mRNA) and protein levels were frequently upregulated with no correlation with MDM4 levels. Lastly, we frequently detected overexpression of MDM4-S mRNA and presence of the aberrant form, MDM4-211 in this tumor group. These findings indicate that MDM4 alterations are a frequent event in PTC. It is worthy to note that the significant downregulation of full-length MDM4 in PTC reveals a novel status of this factor in human cancer that counsels careful evaluation of its role in human tumorigenesis and of its potential as therapeutic target.
...
PMID:Analysis of human MDM4 variants in papillary thyroid carcinomas reveals new potential markers of cancer properties. 1833 86
The critical
tumor suppressor p53
is mutated or functionally inactivated in nearly all cancers. We have shown previously that the MDM2-
MDMX
complex functions as an integral unit in targeting
p53
for degradation. Here we identify the small protein 14-3-3 as a binding partner of
MDMX
, which binds at the C terminus (Ser367) in a phosphorylation-dependent manner. Importantly, we demonstrate that the serine/threonine kinase Akt mediates phosphorylation of
MDMX
at Ser367. This phosphorylation leads to stabilization of
MDMX
and consequent stabilization of MDM2. Previous studies have shown that Akt phosphorylates and stabilizes MDM2. Our data suggest that stabilization of
MDMX
by Akt may be an alternative mechanism by which Akt up-regulates MDM2 protein levels and exerts its oncogenic effects on
p53
in tumor cells.
...
PMID:Phosphorylation of MDMX mediated by Akt leads to stabilization and induces 14-3-3 binding. 1835 62
CARP1 and CARP2 proteins (CARPs) are E3 ligases that target
p53
as well as phospho-
p53
for degradation. Because MDM2 is a critical regulator of
p53
turnover, we investigated and found that CARPs associate with MDM2. We provide evidence that CARPs stabilize MDM2 by inhibiting MDM2 self-ubiquitination. CARPs together with MDM2 enhance
p53
degradation, thereby inhibiting
p53
-mediated cell death. CARP protein levels correlate with MDM2 levels including under hypoxia where both are reduced. CARP2 was found to target 14-3-3sigma for degradation, leading to MDM2 stabilization.
MDMX
, a homolog of MDM2, is not absolutely required for MDM2 stabilization by CARPs, although overexpression of CARP2 enhances MDM2/
MDMX
interaction. Taken together, our study identifies novel mechanisms by which CARP proteins regulate the
p53
signaling pathway.
...
PMID:CARPs enhance p53 turnover by degrading 14-3-3sigma and stabilizing MDM2. 1838 27
The
p53 tumor suppressor
is a powerful growth suppressive and pro-apoptotic molecule frequently inactivated in human cancer. Many tumors overproduce its negative regulator MDM2, a specific
p53
ubiquitin ligase and transcriptional inhibitor, to disable
p53
function. Therefore,
p53
activation by inhibiting MDM2 has been proposed as a novel strategy for cancer therapy in tumors expressing wild-type
p53
. Recently developed small-molecule
p53
-MDM2 binding inhibitors, the nutlins, selectively activate
p53
function and induce cell cycle arrest and apoptosis in cancer cells. By stabilizing
p53
, nutlins also elevate the cellular level of its transcriptional target MDM2. Here, we present evidence that nutlin-induced MDM2 retains its ubiquitin ligase activity and contributes to the anti-tumor activity of
p53
-MDM2 binding inhibitors by facilitating the degradation of another
p53
inhibitor,
MDMX
. MDM2 and
MDMX
levels were analyzed in a panel of 12 randomly selected solid tumor cell lines. In the presence of nutlin-3, MDM2 increased in all and
MDMX
decreased in most of the cell lines.
MDMX
was resistant to nutlin-induced degradation in 2/12 cell lines. In these cells,
MDMX
appears to be a major suppressor of the apoptotic response to
p53
activation although this effect was only partially
p53
-dependent. Doxorubicin facilitated
MDMX
degradation through DNA damage response pathways and restored their sensitivity to nutlin, suggesting that combination therapy may be an effective way to overcome nutlin resistance in cancers with
MDMX
aberrations.
...
PMID:Elevated MDM2 boosts the apoptotic activity of p53-MDM2 binding inhibitors by facilitating MDMX degradation. 1852 Jan 79
The oncoproteins MDM2 and
MDMX
negatively regulate the activity and stability of the
tumor suppressor protein p53
and are important molecular targets for anticancer therapy. Grafting four residues of
p53
critical for MDM2/
MDMX
binding to the N-terminal alpha-helix of BmBKTx1, a scorpion toxin isolated from the venom of the Asian scorpion Buthus martensi Karsch, converts the miniature protein into an effective inhibitor of
p53
interactions with MDM2 and
MDMX
. Additional mutations enable the 27-residue miniprotein inhibitor to traverse the cell membrane and selectively kill tumor cells in a
p53
dependent manner.
...
PMID:Turning a scorpion toxin into an antitumor miniprotein. 1879 22
MDM2 and
MDMX
are oncogenic homologue proteins that regulate the activity and stability of
p53
, a tumor suppressor protein involved in more than 50% of human cancers. While the large body of experiments so far accumulated has validated MDM2 as a therapeutically important target for the development of anticancer drugs, it is only recently that
MDMX
has also become an attractive target for the treatment of tumor cells expressing wild type
p53
. The availability of structural information of the N-terminal domain of MDM2 in complex with
p53
-derived peptides and inhibitors, and the very recent disclosure of the crystal structure of the N-terminal domain of
MDMX
bound to a
p53
peptide, offer an unprecedented opportunity to provide insight into the molecular basis of
p53
recognition and the identification of discriminating features affecting the binding of the tumor suppressor protein at MDM2 and
MDMX
. By using coarse graining simulations, in this study we report the exploration of the conformational transitions featured in the pathway leading from the apo-MDM2 and apo-
MDMX
states to the
p53
-bound MDM2 and
p53
-bound
MDMX
states, respectively. The results have enabled us to identify a pool of diverse conformational states of the oncogenic proteins that affect the binding of
p53
and the presence of conserved and non-conserved interactions along the conformational transition pathway that may be exploited in the design of selective and dual modulators of MDM2 and
MDMX
activity.
...
PMID:Targeting the conformational transitions of MDM2 and MDMX: insights into dissimilarities and similarities of p53 recognition. 1882 7
The oncoproteins MDM2 and
MDMX
negatively regulate the activity and stability of the
tumor suppressor protein p53
--a cellular process initiated by MDM2 and/or
MDMX
binding to the N-terminal transactivation domain of
p53
. MDM2 and
MDMX
in many tumors confer
p53
inactivation and tumor survival, and are important molecular targets for anticancer therapy. We screened a duodecimal peptide phage library against site-specifically biotinylated
p53
-binding domains of human MDM2 and
MDMX
chemically synthesized via native chemical ligation, and identified several peptide inhibitors of the
p53
-MDM2/
MDMX
interactions. The most potent inhibitor (TSFAEYWNLLSP), termed PMI, bound to MDM2 and
MDMX
at low nanomolar affinities--approximately 2 orders of magnitude stronger than the wild-type
p53
peptide of the same length (ETFSDLWKLLPE). We solved the crystal structures of synthetic MDM2 and
MDMX
, both in complex with PMI, at 1.6 A resolution. Comparative structural analysis identified an extensive, tightened intramolecular H-bonding network in bound PMI that contributed to its conformational stability, thus enhanced binding to the 2 oncogenic proteins. Importantly, the C-terminal residue Pro of PMI induced formation of a hydrophobic cleft in
MDMX
previously unseen in the structures of
p53
-bound MDM2 or
MDMX
. Our findings deciphered the structural basis for high-affinity peptide inhibition of
p53
interactions with MDM2 and
MDMX
, shedding new light on structure-based rational design of different classes of
p53
activators for potential therapeutic use.
...
PMID:Structural basis for high-affinity peptide inhibition of p53 interactions with MDM2 and MDMX. 1925 50
The oncogenic proteins MDM2 and
MDMX
have distinct and critical roles in the control of the activity of the
p53 tumor suppressor protein
. Recently, we have used spatial coarse graining simulations to analyze the conformational transitions manifest in the
p53
recognition of MDM2 and
MDMX
. These conformational movements are different between MDM2 and
MDMX
and unveil the presence of conserved and nonconserved interactions in the
p53
binding cleft that may be exploited in the design of selective and dual modulators of the oncogenic proteins. In this study, we investigate the conformational profiles of apo- and
p53
-bound states of MDM2 and
MDMX
using molecular dynamic simulations along a time scale of 60 ns. The analysis of the trajectories is instrumental to discuss energetical and conformational aspects of
p53
recognition and to point out specific key residues whose conformational shifts have crucial roles in affecting the apo- and
p53
-bound states of MDM2 and
MDMX
. Among these, in particular, linear discriminant analyses identify diverse conformations of Y99/Y100 (
MDMX
/MDM2) as markers of the apo- and
p53
-bound states of the oncogenic proteins. The results of this study shed further light on different
p53
recognition in MDM2 and
MDMX
and may prove useful for the design and identification of new potent and selective synthetic modulators of
p53
-MDM2/
MDMX
interactions.
...
PMID:Targeting the conformational transitions of MDM2 and MDMX: insights into key residues affecting p53 recognition. 1950 40
The
p53
gene is crucial for effective tumor suppression in humans as supported by its universal inactivation in cancer cells either through mutations affecting the
p53
locus directly or through aberration of its normal regulation. The
p53
tumor repressor is regulated through a negative feedback loop involving its transcriptional target MDM2.
MDMX
is also an essential negative regulator of
p53
. Several computational models have been proposed to simulate the dynamics of the
p53
-MDM2 loop, but they do not include
MDMX
, only account for some basic interactions between
p53
and MDM2 and cannot capture the intrinsic noise in the loop. In this article, we present a comprehensive model for the
p53
-MDM2/
MDMX
loop that accounts for most known interactions among
p53
, MDM2 and
MDMX
. Our model is characterized by a set of molecular reactions, which enables us to employ stochastic simulation to investigate the dynamics of the loop. In agreement with experiments, our results show that
p53
and MDM2 undergo oscillations after DNA damage in the presence of noise, and the variation in oscillation amplitudes is much higher than that in oscillation periods. Our simulations predict that intrinsic noise contributes to 60%-70% of the total variation in oscillation amplitudes and periods. The protein levels of
p53
, MDM2, and
MDMX
after treatment with Nutlin in our simulations are also consistent with experimental results. Our simulation results further predict that
p53
levels increase dramatically after MDM2 is knocked out, but increase with a much less amount after
MDMX
is knocked out. This may partially explain why MDM2-null and
MDMX
-null mouse embryos die in different developmental stages. Our stochastic model and simulation provide insights into the variability of the behavior of the
p53
pathway and can be used to predict the dynamics of the pathway after certain interventions.
...
PMID:Stochastic modeling and simulation of the p53-MDM2/MDMX loop. 1958 May 21
p53 tumor suppressor
gene encodes for a critical cellular protein that regulate the integrity of the cell and can induce cell cycle arrest and/or apoptosis upon cellular stresses of several origins, including chemotherapeutics. Loss of
p53
function occurs in an estimated 50% of all cancers by mutations and deletions while in the presence of wild-type
p53
alleles other mechanisms may affect the expression and activity of
p53
. Alternate mechanisms include methylation of the promoter of
p53
, deletion or epigenetic inactivation of the
p53
-positive regulator p14/ARF, elevated expression of the
p53
regulators murine double minute 2 (MDM2) and
MDMX
, or alteration of upstream regulators of
p53
such as the kinase ATM. MDM2 is a
p53
E3 ubiquitin ligase that mediates the ubiquitin-dependent degradation of
p53
while p14/ARF is a small MDM2-binding protein that controls the activity of MDM2 by displacing
p53
and preventing its degradation.
MDMX
antagonize
p53
-dependent transcriptional control by interfering with
p53
transactivation function. The understanding of the key role of
p53
inactivation in cancer development generated considerable interest in developing compounds that are capable of restoring the
p53
functions. Several patents have been issued on such compounds. Adenovirus-based
p53
gene therapy as well as small molecules such as PRIMA that can restore the transcriptional transactivation function to mutant p53, or NUTLIN and RITA that interfere with MDM2-directed
p53
degradation, have tested in a preclinical setting and some of these approaches are currently in clinical development.
...
PMID:Restoring p53 function in cancer: novel therapeutic approaches for applying the brakes to tumorigenesis. 1966 72
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