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SATB2 is a Modulator of p63(alpha) in Cancer and DevelopmentChung, Jacky 14 August 2013 (has links)
p63(alpha) belongs to the p53-family of proteins and has full-length (TA) as well as truncated ((delta)N) p63(alpha) isoforms. Previous studies have shown that TA and (delta)Np63(alpha) play multiple roles in cancer and development. In cancer, (delta)Np63(alpha)-mediated transcriptional repression promotes oncogenesis while transactivation by TAp63(alpha) is critical during development. Despite their importance, little is known regarding how TA or (delta)Np63(alpha) is regulated and factors influencing the function of p63(alpha) have yet to be identified.
Here, I identify Special AT-rich Binding Protein 2 (SATB2) as a protein that forms a complex with and modulates the function of p63(alpha). SATB2 is detected in multiple head and neck squamous cell carcinoma (HNSCC) cell lines that also show overexpression of (delta)Np63(alpha). Histological analysis on tumor specimens revealed that SATB2 is predominantly expressed in advanced-stage HNSCC cancers. SATB2 increases DNA-binding capabilities of (delta)Np63(alpha), augmenting (delta)Np63(alpha) repression of apoptotic gene expression. Knockdown of SATB2 in HNSCC cells sensitizes cancer cells towards chemotherapy- and radiation-induced apoptosis. These results indicate that SATB2 functions as a co-factor and promotes the transrepression function of (delta)Np63(alpha) in HNSCC.
In addition to examining the role of SATB2 in HNSCC, I also investigated the effect of SATB2 on the ability of TAp63(alpha) to induce gene expression. In particular, perp has been shown to be a critical downstream target of p63 during development. ChIP analysis revealed that while SATB2 increases TAp63(alpha)-binding to apoptotic gene promoters, SATB2 decreases TAp63(alpha) localization on the perp promoter and inhibits p63(alpha)-mediated perp induction. SATB2 more readily interacts with human disease-associated p63(alpha) mutations that are found in the SAM domain, further inhibiting transcriptional properties of these mutants. Together, my results suggest that SATB2 is an important modulator of p63(alpha) in cancer and development.
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SATB2 is a Modulator of p63(alpha) in Cancer and DevelopmentChung, Jacky 14 August 2013 (has links)
p63(alpha) belongs to the p53-family of proteins and has full-length (TA) as well as truncated ((delta)N) p63(alpha) isoforms. Previous studies have shown that TA and (delta)Np63(alpha) play multiple roles in cancer and development. In cancer, (delta)Np63(alpha)-mediated transcriptional repression promotes oncogenesis while transactivation by TAp63(alpha) is critical during development. Despite their importance, little is known regarding how TA or (delta)Np63(alpha) is regulated and factors influencing the function of p63(alpha) have yet to be identified.
Here, I identify Special AT-rich Binding Protein 2 (SATB2) as a protein that forms a complex with and modulates the function of p63(alpha). SATB2 is detected in multiple head and neck squamous cell carcinoma (HNSCC) cell lines that also show overexpression of (delta)Np63(alpha). Histological analysis on tumor specimens revealed that SATB2 is predominantly expressed in advanced-stage HNSCC cancers. SATB2 increases DNA-binding capabilities of (delta)Np63(alpha), augmenting (delta)Np63(alpha) repression of apoptotic gene expression. Knockdown of SATB2 in HNSCC cells sensitizes cancer cells towards chemotherapy- and radiation-induced apoptosis. These results indicate that SATB2 functions as a co-factor and promotes the transrepression function of (delta)Np63(alpha) in HNSCC.
In addition to examining the role of SATB2 in HNSCC, I also investigated the effect of SATB2 on the ability of TAp63(alpha) to induce gene expression. In particular, perp has been shown to be a critical downstream target of p63 during development. ChIP analysis revealed that while SATB2 increases TAp63(alpha)-binding to apoptotic gene promoters, SATB2 decreases TAp63(alpha) localization on the perp promoter and inhibits p63(alpha)-mediated perp induction. SATB2 more readily interacts with human disease-associated p63(alpha) mutations that are found in the SAM domain, further inhibiting transcriptional properties of these mutants. Together, my results suggest that SATB2 is an important modulator of p63(alpha) in cancer and development.
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Role of Distal Regulatory Elements in Cancer Progression and TherapyHamdan, Feda Hisham Moh'd 12 December 2018 (has links)
No description available.
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Protection of CD4<sup>+</sup> T Cells From Hepatitis C Virus Infection-Associated Senescence via ∆Np63-miR-181a-Sirt1 PathwayZhou, Yun, Li, Guang Y., Ren, Jun P., Wang, Ling, Zhao, Juan, Ning, Shun B., Zhang, Ying, Lian, Jian Q., Huang, Chang X., Jia, Zhan S., Moorman, Jonathan P., Yao, Zhi Q. 01 November 2016 (has links)
T cell dysfunction has a crucial role in establishing and maintaining viral persistence. We have previously shown a decline in miR-181a, which regulates CD4+ T cell responses via DUSP6 overexpression, in individuals with hepatitis C virus (HCV) infection. Here, we describe accelerated T cell senescence in HCV-infected individuals compared with age-and sex-matched healthy subjects. Mechanistic studies revealed that up-regulation of transcription factor ∆Np63 led to the decline of miR-181a expression, resulting in an overexpression of the antiaging protein Sirt1, in CD4+ T cells from HCV-infected individuals. Either reconstituting miR-181a or silencing ∆Np63 or Sirt1 expression in CD4+ T cells led to accelerated T cell senescence, as evidenced by an increased senescence-associated b-galactosidase (SA-β-gal) expression, shortened telomere length, and decreased EdU incorporation; this suggests that HCV-induced T cell senescence is counterregulated by the ∆Np63-miR-181a-Sirt1 pathway. An increase of IL-2 production was observed in these senescent CD4+ T cells and was driven by a markedly reduced frequency of Foxp3+ regulatory T (Treg) cells and increased number of Foxp3- effector T (Teff) cells upon manipulating the ∆Np63-miR-181a-Sirt1 pathway. In conclusion, these findings provide novel mechanistic insights into how HCV uses cellular senescent pathways to regulate T cell functions, revealing new targets for rejuvenating impaired T cell responses during chronic viral infection.
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Establishing tissue-specific chromatin organization during development of the epidermis. Nuclear architecture of different layers of murine epidermis and the role of p63 and Satb1 in establishing tissue-specific organization of the epidermal differentiation complex locus.Gdula, Michal R. January 2011 (has links)
During development, multipotent stem cells establish tissue-specific
programmes of gene expression that underlie a process of differentiation into
specialized cell types.
It was shown in the study that changes in the nuclear architecture during
terminal keratinocyte differentiation show correlation with the dynamics of the
transcriptional and metabolic activity. In particular, terminal differentiation is
accompanied by the decrease of nuclear volume, elongation of its shape,
reduction of the number and fusion of nucleoli, increase in the number of
centromeric clusters and a dramatic decrease of the transcriptional activity.
Global changes in the nuclear architecture of epidermal keratinocytes are
associated with marked remodelling of the higher-order chromatin structure of
the epidermal differentiating complex (EDC). EDC is positioned peripherally in
the epidermal nuclei at E11.5 when its genes show low expression levels and
relocates towards the nuclear interior at E16.5 when EDC genes are markedly
upregulated.
P63 transcription factor serving as a master regulator of epidermal development
is involved in the control of EDC relocation in epidermal progenitor cells. The
epidermis of E16.5 p63KO exhibits significantly more peripheral positioning of
the EDC loci, compared to wild-type.
The genome organizer Satb1 serving as a direct p63 target controls higher
order chromatin folding of the central part of EDC and Satb1 knockout mice
show alterations of epidermal development and expression of the EDC
encoded genes. Thus, this study shows that the programme of epidermal development and
terminal differentiation is regulated by p63 and other factors and include marked
remodelling of three-dimensional nuclear organization and positioning of tissue
specific gene loci. In addition to the direct involvement of p63 in controlling the
expression of tissue-specific genes, p63 via regulation of the chromatin
remodelling factors such as Satb1 promotes establishing specific conformation
of the EDC locus required for efficient expression of terminal differentiation-associated genes.
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Mechanisms of epigenetic regulation in epidermal keratinocytes during skin development. Role of p63 transcription factor in the establishment of lineage-specific gene expression programs in keratinocytes via regulation of nuclear envelope-associated genes and Polycomb chromatin remodelling factors.Rapisarda, Valentina January 2014 (has links)
During tissues development multipotent progenitor cells establish tissue-specific
gene expression programmes, leading to differentiation into specialized cell types. It
has been previously shown that the transcription factor p63, a master regulator of skin
development, controls the expression of adhesion molecules and essential
cytoskeleton components. It has also been shown that p63 plays an important role in
establishing distinct three-dimensional conformations in the Epidermal Differentiation
Complex (EDC) locus (Fessing et al., 2011). Here we show that in p63-null mice about
32% of keratinocytes showed altered nuclear morphology. Alterations in the nuclear
shape were accompanied by decreased expression of nuclear lamins (Lamin A/C and
Lamin B1), proteins of the LINC complex (Sun-1, nesprin-2/3) and Plectin. Plectin links
components of the nuclear envelope (nesprin-3) with cytoskeleton and ChIP-qPCR
assay with adult epidermal keratinocytes showed p63 binding to the consensus binding
sequences on Plectin 1c, Sun-1 and Nesprin-3 promoters.
As a possible consequence of the altered expression of nuclear lamins and
nuclear envelope-associated proteins, changes in heterochromatin distribution as well
as decrease of the expression of several polycomb proteins (Ezh2, Ring1B, Cbx4) has
been observed in p63-null keratinocytes. Moreover, recent data in our lab have showed
that p63 directly regulates Cbx4, a component of the polycomb PRC1 complex.
Here we show that mice lacking Cbx4 displayed a skin phenotype, which partially
resembles the one observed in p63-null mice with reduced epidermal thickness and
keratinocyte proliferation.
All together these data demonstrate that p63-regulated gene expression program
in epidermal keratinocytes includes not only genes encoding adhesion molecules,
cytoskeleton proteins (cytokeratins) and chromatin remodelling factors (Satb1, Brg1),
but also polycomb proteins and components of the nuclear envelope, suggesting the
existence of a functional link between cytoskeleton, nuclear architecture and three
dimensional nuclear organization.
Other proteins important for proper epidermal development and stratification, are
cytokeratins. Here, we show that keratin genes play an essential role in spatial
organization of other lineage-specific genes in keratinocytes during epidermal
development. In fact, ablation of keratin type II locus from chromosome 15 in epidermal
keratinocytes led to changes in the genomic organization with increased distance
between the Loricrin gene located on chromosome 3 as well as between Satb1 gene
located on chromosome 17 and keratin type II locus, resulting in a more peripheral
localization of these genes in the nucleus. As a possible consequence of their
peripheral localization, reduced expression of Loricrin and Satb1 has also been
observed in keratins type II-deficient mice. These findings together with recent
circularized chromosome conformation capture (4C) data, strongly suggest that keratin
5, Loricrin and Satb1 are part of the same interactome, which is required for the proper
expression of these genes and proper epidermal development and epidermal barrier
formation.
Taken together these data suggest that higher order chromatin remodelling and
spatial organization of genes in the nucleus are important for the establishment of
lineage-specific differentiation programs in epidermal progenitor cells. These data
provide an important background for further analyses of nuclear architecture in the
alterations of epidermal differentiation, seen in pathological conditions, such as
psoriasis and epithelial skin cancers.
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Aberrant splicing of the p63 gene in the accelerated development of epithelial cancerPitt, Keshia 12 February 2024 (has links)
p63, a homologue of the transcription factor p53, is essential for maintaining the proliferative capacity of epithelial stem cells. The p63 gene yields two major isoforms transcribed from dual promoters at its N-terminus and at least three different splice variants at its C-terminus. The TAp63 isoform functions as a p53-like tumor suppressor and transactivates p53 gene targets. In contrast, ΔNp63α predominates in epithelial stem cells and regulates their proliferative potential, whilst also acting as an oncogene by suppressing the function of both p53 and TAp63 in a dominant-negative manner. ΔNp63α is frequently upregulated in human epithelial cancers and has been theorized to play a role in tumorigenesis.
Our prior studies found that an aberrantly spliced ΔNp63α isoform heterozygous for a lack of exon 4-coded sequences (hereafter referred to as Δ4) appeared to be specifically expressed in squamous cell carcinomas, suggesting a potential link between this new isoform and a specific type of cancer.
Our study aimed to elucidate the involvement of this aberrantly spliced p63 isoform in the initiation and/or development of epithelial cancer. We established a p63+/Δ4 mouse model to obtain a baseline for the effect of one aberrant allele on both embryonic and adult mouse development. We found that p63+/Δ4 mouse embryos developed normally and that over a period of 74 weeks, the p63+/Δ4 mice developed normally and lived lifespans equivalent to their wildtype counterparts, though a small proportion of the p63+/Δ4 colony showed minor issues with inflammation.
After our initial observations, we established an experimental mouse model to test the effect of oncogenic stimulation on p63+/Δ4 mice. In the first model, we administered the oral carcinogen 4-nitroquinoline 1-oxide to mirror the histological and molecular changes seen in human oral carcinogenesis. We observed significant dysplasia in the tongue epithelia of p63+/Δ4 mice compared to that of wildtype. With this data, we developed the hypothesis that expression of Δ4 accelerates tumorigenesis in the presence of oncogenic stimulation.
To further test this possibility, we generated a second mouse model: a triple transgenic Cre-inducible mouse model under the control of epithelial cell-specific promotor gene, keratin 14 (K14). This cross introduced a mutated Kras gene to the p63+/Δ4 lineage, as well as to control wildtype mice bred with the same Cre elements. Upon administration of tamoxifen, genetic recombination caused expression of both mutant Kras G12D and Δ4 in K14-positive tissues and subsequent malignant transformation. Among these K14-positive tissues were the oral epithelia, which presented with dysplasia more severe than that of control mice expressing either Kras or Δ4 alone and which matched the phenotype-genotype associations observed in our 4NQO experiment.
Lastly, we attempted to create an antibody specific to Δ4 that could eliminate the need for our current two-antibody identification strategy. Though we did not succeed, we found value in elucidating the genetic sequence requirements to create the artificial peptide that we used for mouse immunization. We attempted to optimize established hybridoma protocols and developed a Δ4-specific screening process to determine viable candidates for expansion.
In conclusion, this study is the first characterization of a hitherto unknown mutant splice variant of a gene vital to stem cell maintenance and epithelial development. It is the first demonstration of this gene mutation’s responsibility for the acceleration of squamous cell carcinoma, which carries implications for potential therapeutic treatments. / 2026-02-12T00:00:00Z
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DIFFERENTIAL REGULATION OF VITAMIN D RECEPTOR (VDR) BY p53, p63 AND p73Kommagani, Ramakrishna 14 May 2009 (has links)
No description available.
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p63 and Brg1 control developmentally regulated higher-order chromatin remodelling at the epidermal differentiation complex locus in epidermal progenitor cellsMardaryev, Andrei N., Gdula, Michal R., Yarker, Joanne L., Emelianov, V.U., Poterlowicz, Krzysztof, Sharov, A.A., Sharova, T.Y., Scarpa, J.A., Chambon, P., Botchkarev, Vladimir A., Fessing, Michael Y. January 2014 (has links)
No
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p63 transcription factor regulates nuclear shape and expression of nuclear envelope-associated genes in epidermal keratinocyteRapisarda, Valentina, Malashchuk, Igor, Asamaowei, Inemo E., Poterlowicz, Krzysztof, Fessing, Michael Y., Sharov, A.A., Karakesisoglou, I., Botchkarev, Vladimir A., Mardaryev, Andrei N. 06 June 2017 (has links)
Yes / The maintenance of a proper nuclear architecture and 3D organization of the genes, enhancer elements and transcription machinery plays an essential role in tissue development and regeneration. Here we show that in the developing skin, epidermal progenitor cells of mice lacking p63 transcription factor display alterations in the nuclear shape accompanied by marked decrease in expression of several nuclear envelop-associated components (Lamin B1, Lamin A/C, SUN1, Nesprin-3, Plectin) compared to controls. Furthermore, ChIP-qPCR assay showed enrichment of p63 on Sun1, Syne3 and Plec promoters, suggesting them as p63 targets. Alterations in the nuclei shape and expression of nuclear envelope-associated proteins were accompanied by altered distribution patterns of the repressive histone marks H3K27me3, H3K9me3 and heterochromatin protein 1- alpha in p63-null keratinocytes. These changes were also accompanied by downregulation of the transcriptional activity and relocation of the keratinocyte-specific gene loci away from the sites of active transcription towards the heterochromatin-enriched repressive nuclear compartments in p63-null cells. These data demonstrate functional links between the nuclear envelope organization, chromatin architecture and gene expression in keratinocytes and suggest nuclear envelope-associated genes as important targets mediating p63-regulated gene expression programme in the epidermis.
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