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Query: UNIPROT:P04637 (
p53
)
77,613
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The
tumor suppressor p53
is inactivated by multiple mechanisms that include mutations of the
p53
gene itself and increased levels of the
p53
inhibitors MDM2 and
MDM4
. Mice lacking Mdm2 or Mdm4 exhibit embryo-lethal phenotypes that are completely rescued by concomitant deletion of
p53
. Here we show that Mdm2 and Mdm4 haploinsufficiency leads to increased
p53
activity, exhibited as increased sensitivity to DNA damage and decreased transformation potential. Moreover, in in vivo tumor development, Emu-myc Mdm4+/- mice show a delayed onset of B-cell lymphomas compared to Emu-myc mice. Additionally, Mdm2+/- Mdm4+/- double-heterozygous mice are not viable and exhibit defects in hematopoiesis and cerebellar development. The defects in Mdm2+/- Mdm4+/- mice are corrected by deletion of a single
p53
allele. These findings highlight the exquisite sensitivity of
p53
to Mdm2 and Mdm4 levels and suggest that some cell types may be more sensitive to therapeutic drugs that inhibit the Mdm-
p53
interaction.
...
PMID:Haploinsufficiency of Mdm2 and Mdm4 in tumorigenesis and development. 1752 34
The
p53 tumor suppressor
is mutated in most human tumors. MDM2, a well-known inhibitor of
p53
, is overexpressed in a large number of tumors, suggesting that increased levels of MDM2 also contribute to tumorigenesis. A novel
p53
inhibitor,
MDM4
, was more recently identified. The role of
MDM4
in cancer development is not well understood. We set out to examine the levels of
MDM4
by immunohistochemistry in head and neck squamous carcinomas (HNSC) to ask whether high
MDM4
levels could contribute to its development and progression. In addition, MDM2 and
p53
levels were examined to identify overlapping expression patterns.
MDM4
is present at high levels in 50% of HNSC. In addition, overexpression of MDM2 was detected in 80% of tumors, many of which were also positive for
MDM4
. A subset of tumors displayed high levels of all 3 proteins. Sequencing of the
p53
gene revealed that tumors with positive immunoreactivity for MDM2 or
MDM4
, some of which also had high levels of
p53
, did not carry mutations in this gene. Thus, the detection of
p53
by immunohistochemistry was not synonymous with the presence of
p53
mutations. Expression of both MDM2 and
MDM4
in tumors without
p53
mutations strongly suggests that MDM2 and
MDM4
inhibit the activity of this tumor suppressor in HNSC.
...
PMID:High levels of the p53 inhibitor MDM4 in head and neck squamous carcinomas. 1765 83
The transcription factor
p53
is under negative regulation by the ubiquitin ligase MDM2 and its close homologue
MDM4
. In the bound complex between MDM2 and
p53
, the transactivation domain of
p53
adopts an amphipathic helical conformation which optimizes the spatial organization of three key hydrophobic residues (Phe19, Trp23, Leu26) for maximum interactions. The interaction with MDM2 is known to be abrogated by phosphorylation of Ser/Thr residues in the MDM2 N-terminal domain and in the
p53
transactivation domain. In the latter, phosphorylation of Thr18 has been attributed to destabilize a key hbond between Thr18 and Asp21. This interaction has been thought to be critical for the formation of the helical conformation of the
p53
transactivation domain. Molecular dynamics simulations of the
p53
transactivation domain suggest that phosphorylation of either Thr18 or Ser20 does not disrupt its helical structure but does result in reduced affinities for MDM2. While interactions between the Thr18 and Asp21 are indeed broken due to charge-charge repulsions, the peptide has enough inherent flexibility to form alternate patterns of hbonds, resulting in the maintenance of helicity. Electrostatics of MDM2 reveal local anionic patches in the region where Thr18 docks. These suggest that repulsions will arise because the MDM2 surface will force the
p53
to bind in a manner that will place the negatively charged phosphorylated Thr18 near this anionic region. A similar, albeit somewhat attenuated pattern of electrostatic modulations, is seen for a model of
MDM4
that has been built. Mutants of MDM2 and
MDM4
have been designed to attenuate this anionicity and have been computationally demonstrated to enhance the binding of the phosphorylated peptides.
...
PMID:Modulation of the p53-MDM2 interaction by phosphorylation of Thr18: a computational study. 1795 42
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
MDM2 is a ubiquitin ligase that is best known for its essential function in the negative regulation of
p53
. In addition, MDM2 expression is associated with tumor progression in a number of common cancers, and in some cases, this has been shown to be independent of
p53
status. MDM2 has been shown to promote the degradation of a number of other proteins involved in the regulation of normal cell growth and proliferation, including
MDM4
and RB1. Here, we describe the identification of a novel substrate for the MDM2 ubiquitin ligase: dihydrofolate reductase (DHFR). MDM2 binds directly to DHFR and catalyses its monoubiquitination and not its polyubiquitination. In addition, MDM2 expression reduces DHFR activity in a
p53
-independent manner, but has no effect upon the steady-state level of expression of DHFR. We show that changes in MDM2 expression alter folate metabolism in cells as evidenced by MDM2-dependent alteration in the sensitivity of cells to the antifolate drug methotrexate. Furthermore, we show that the ability of MDM2 to inhibit DHFR activity depends upon an intact MDM2 RING finger. Our studies provide for the first time a link between MDM2, an oncogene with a critical ubiquitin ligase activity and a vital one-carbon donor pathway involved in epigenetic regulation, and DNA metabolism, which has wide ranging implications for both cell biology and tumor development.
...
PMID:MDM2 regulates dihydrofolate reductase activity through monoubiquitination. 1845 Nov 49
Mutational inactivation of
p53
is a hallmark of most human tumors. Loss of
p53
function also occurs by overexpression of negative regulators such as MDM2 and
MDM4
. Deletion of Mdm2 or Mdm4 in mice results in
p53
-dependent embryo lethality due to constitutive
p53
activity. However, Mdm2(-/-) and Mdm4(-/-) embryos display divergent phenotypes, suggesting that Mdm2 and Mdm4 exert distinct control over
p53
. To explore the interaction between Mdm2 and Mdm4 in
p53
regulation, we first generated mice and cells that are triple null for
p53
, Mdm2, and Mdm4. These mice had identical survival curves and tumor spectrum as
p53
(-/-) mice, substantiating the principal role of Mdm2 and Mdm4 as negative
p53
regulators. We next generated mouse embryo fibroblasts null for
p53
with deletions of Mdm2, Mdm4, or both; introduced a retrovirus expressing a temperature-sensitive
p53
mutant, p53A135V; and examined
p53
stability and activity. In this system,
p53
activated distinct target genes, leading to apoptosis in cells lacking Mdm2 and a cell cycle arrest in cells lacking Mdm4. Cells lacking both Mdm2 and Mdm4 had a stable
p53
that initiated apoptosis similar to Mdm2-null cells. Additionally, stabilization of
p53
in cells lacking Mdm4 with the Mdm2 antagonist nutlin-3 was sufficient to induce a cell death response. These data further differentiate the roles of Mdm2 and Mdm4 in the regulation of
p53
activities.
...
PMID:Mdm2 and Mdm4 loss regulates distinct p53 activities. 1856 99
The N-terminal domain of
MDM4
binds to the N-terminal transactivation domain of the
tumor suppressor p53
and is an important negative regulator of its transactivation activity. As such, inhibition of the binding of
MDM4
to
p53
is a target for anticancer therapy. The protein has not been crystallized satisfactorily for structural studies without the addition of an N-terminal
p53
peptide. We selected a single-domain antibody (VH9) that bound to the human domain with a dissociation constant of 44 nM. We solved the structure of the complex at 2.0-A resolution. The asymmetric unit contained eight molecules of VH9 and four molecules of
MDM4
. A molecule of VH9 was located in each transactivation domain binding site, and the four non-
MDM4
-bound VH9 domains provided additional crystal contacts. There are differences between the structures of human
MDM4
domain bound to VH9 and those of human and zebra fish
MDM4
bound to a
p53
peptide. Molecular dynamics simulations showed that the binding pocket in the three
MDM4
structures converged to a common conformation after removal of the ligands, indicating that the differences are due to induced fit. The largest conformational changes were for the
MDM4
molecules bound to
p53
. The simulated and observed structures should aid rational drug design. The use of single-domain antibodies to aid crystallization by creating a molecular scaffold may have a wider range of applications.
...
PMID:Structure of human MDM4 N-terminal domain bound to a single-domain antibody. 1908 22
MDM2 and
MDM4
, the murine double minute proteins, are oncogenes that function as important regulators of various proteins. One fundamental role for these proteins is regulation of the tumor suppressor,
p53
. Precise regulation of
p53
is vital for coordinated malignant suppression and cell survival. Alternative splice forms of MDM2 as well as
MDM4
have been associated with various cancers. Indeed, UV irradiation triggers alternative splicing of both MDM2 and
MDM4
. Coordinated alternative splicing in response to cellular stress or in cancerous cells regulates the posttranscriptional expression of these two genes and likely others. This concert of stress responsive mRNAs comprises the cancer spliceome and provides a fingerprint of coordinated alternative splicing in these aberrant cells. Although various transcripts have been described for both proteins, here we provide a precise catalog of the alternatively spliced transcripts of both genes and the cancers with which they are associated.
...
PMID:MDM2 and MDM4 splicing: an integral part of the cancer spliceome. 1927 24
A large body of evidence strongly suggests that the
p53 tumor suppressor
pathway is central in reducing cancer frequency in vertebrates. The protein product of the haploinsufficient mouse double minute 2 (MDM2) oncogene binds to and inhibits the
p53 protein
. Recent studies of human genetic variants in
p53
and MDM2 have shown that single nucleotide polymorphisms (SNPs) can affect
p53
signaling, confer cancer risk, and suggest that the pathway is under evolutionary selective pressure (1-4). In this report, we analyze the haplotype structure of
MDM4
, a structural homolog of MDM2, in several different human populations. Unusual patterns of linkage disequilibrium (LD) in the haplotype distribution of
MDM4
indicate the presence of candidate SNPs that may also modify the efficacy of the
p53
pathway. Association studies in 5 different patient populations reveal that these SNPs in
MDM4
confer an increased risk for, or early onset of, human breast and ovarian cancers in Ashkenazi Jewish and European cohorts, respectively. This report not only implicates
MDM4
as a key regulator of tumorigenesis in the human breast and ovary, but also exploits for the first time evolutionary driven linkage disequilibrium as a means to select SNPs of
p53
pathway genes that might be clinically relevant.
...
PMID:Altered tumor formation and evolutionary selection of genetic variants in the human MDM4 oncogene. 1949 87
MDM4
is a key regulator of
p53
, whose biological activities depend on both transcriptional activity and transcription-independent mitochondrial functions.
MDM4
binds to
p53
and blocks its transcriptional activity; however, the main cytoplasmic localization of
MDM4
might also imply a regulation of
p53
-mitochondrial function. Here, we show that
MDM4
stably localizes at the mitochondria, in which it (i) binds BCL2, (ii) facilitates mitochondrial localization of
p53
phosphorylated at Ser46 (p53Ser46(P)) and (iii) promotes binding between p53Ser46(P) and BCL2, release of cytochrome C and apoptosis. In agreement with these observations,
MDM4
reduction by RNA interference increases resistance to DNA-damage-induced apoptosis in a
p53
-dependent manner and independently of transcription. Consistent with these findings, a significant downregulation of
MDM4
expression associates with cisplatin resistance in human ovarian cancers, and
MDM4
modulation affects cisplatin sensitivity of ovarian cancer cells. These data define a new localization and function of
MDM4
that, by acting as a docking site for p53Ser46(P) to BCL2, facilitates the
p53
-mediated intrinsic-apoptotic pathway. Overall, our results point to
MDM4
as a double-faced regulator of
p53
.
...
PMID:MDM4 (MDMX) localizes at the mitochondria and facilitates the p53-mediated intrinsic-apoptotic pathway. 1952 40
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