Downregulation of p57kip2 promotes cell invasion via LIMK/cofilin pathway in human nasopharyngeal carcinoma cells

The members of Rho family are well known for their regulation of actin cytoskeleton to control cell migration. The Cip/kip members of cyclin‐dependent (CDK) inhibitors have shown to implicate in cell migration and cytoskeletal dynamics. p57^kip2, a CDK inhibitor, is frequently down‐regulated in several malignancy tumors. However, its biological roles in human nasopharyngeal carcinoma (NPC) cells remained to be investigated. Here, we found p57^kip2 has nuclear and cytoplasm distributions and depletion of endogenous p57^kip2 did not change the cell‐cycle progression. Inhibition of cell proliferation by mitomycin C promoted FBS‐mediated cell migration and accompanied with the downregulation of ΔNp63α and p57^kip2, but did not change the level of p27^kip1, another CDK inhibitor. By using siRNA transfection and cell migration/invasion assays, we found that knockdown of p57^kip2, but not ΔNp63α, involved in promotion of NPC cell migration and invasion via decrease of phospho‐cofilin (p‐cofilin). Treatment with Y‐27632, a specific ROCK inhibitor, we found that dysregulation of ROCK/cofilin pathway decreased p‐cofilin expression and induced cell migration. This change of p‐cofilin induced actin remodeling and pronounced increase of membrane protrusions. Further, silence of p57^kip2 not only decreased the interaction between p57^kip2 and LIMK‐1 assayed by immunoprecipitation but also reduced the level of phospho‐LIMK1/2. Therefore, this study indicated that dysregulation of p57^kip2 promoted cell migration and invasion through modulation of LIMK/cofilin signaling and suggested this induction of inappropriate cell motility might contribute to promoting tumor cell for metastasis. J. Cell. Biochem. 112: 3459–3468, 2011. © 2011 Wiley Periodicals, Inc.     

ROCK‐dependent phosphorylation of NUP62 regulates p63 nuclear transport and squamous cell carcinoma proliferation

p63, more specifically its ΔNp63α isoform, plays essential roles in squamous cell carcinomas (SCCs), yet the mechanisms controlling its nuclear transport remain unknown. Nucleoporins (NUPs) are a family of proteins building nuclear pore complexes (NPC) and mediating nuclear transport across the nuclear envelope. Recent evidence suggests a cell type‐specific function for certain NUPs; however, the significance of NUPs in SCC biology remains unknown. In this study, we show that nucleoporin 62 (NUP62) is highly expressed in stratified squamous epithelia and is further elevated in SCCs. Depletion of NUP62 inhibits proliferation and augments differentiation of SCC cells. The impaired ability to maintain the undifferentiated status is associated with defects in ΔNp63α nuclear transport. We further find that differentiation‐inducible Rho kinase reduces the interaction between NUP62 and ΔNp63α by phosphorylation of phenylalanine–glycine regions of NUP62, attenuating ΔNp63α nuclear import. Our results characterize NUP62 as a gatekeeper for ΔNp63α and uncover its role in the control of cell fate through regulation of ΔNp63α nuclear transport in SCC.     

Loss of ΔNp63α promotes mitotic exit in epithelial cells

Protein p63 is a key regulator in cell proliferation and cell differentiation in stratified squamous epithelium. ΔNp63α is the most commonly expressed p63 isoform, which is often overexpressed in human tumor. In the present work we report the potential involvement of ΔNp63α in cell cycle regulation. ΔNp63α accumulated in mitotic cells but its expression decreased during mitotic exit. Moreover, ΔNp63α knockdown promoted mitotic exit. ΔNp63α shares a conserved destruction box (D-box) motif with other potential targets of the Anaphase-Promoting Complex/Cyclosome (APC/C). Overexpression of APC/C coactivator Cdh1 destabilized ΔNp63α. Our results suggest that ΔNp63α level is cell cycle-regulated and may play a role in the regulation of mitotic exit.     

The two faces of p63, Janus of the p53 gene family

The TP53 family member TP63 encodes two main isoforms TAp63 and ΔNp63 with distinct, often opposite functions during development and in the adult. ΔNp63 is crucial for the formation of the ectodermal derivatives and epidermis, while TAp63 is essential for heart development. In the adult, ΔNp63 behaves as a cell survival factor, controlling cell proliferation, adhesion and cell differentiation. In contrast, TAp63 is a proapoptotic factor that protects oocytes from genotoxic insults and prevents premature aging of dermal stem cells. In agreement with these activities, TAp63 is often lost and ΔNp63 overexpressed in cancer cells. Because of their opposite and competitive effects, p63 isoforms could be viewed as Janus two faces. The review focuses on the accumulating data on the p63 functions and regulation in the last decade.     

EGFR through STAT3 modulates ΔN63α expression to sustain tumor‐initiating cell proliferation in squamous cell carcinomas

Many squamous cell carcinomas (SCCs) are characterized by high levels of EGFR and by overexpression of the ΔNp63α isoform. Here, we investigated the regulation of ΔNp63α expression upon EGFR activation and the role of the EGFR–ΔNp63α axis in proliferation of SCC tumor‐initiating cells (TICs). SCC cell lines A‐431, Cal‐27, and SCC‐25 treated with EGF showed a time‐dependent increase in ΔNp63α expression at the protein and mRNA levels, which was blocked by the tyrosine kinase inhibitor (TKI) Lapatinib. RNA interference experiments suggested the role of STAT3 in regulating ΔNp63α expression downstream of EGFR. Inactivation of EGFR by the monoclonal antibody Cetuximab and RNA interference against STAT3 or ΔNp63α impaired the TICs ability to grow under non‐differentiating conditions. Radiation treatment, which triggers EGFR activation, induced ΔNp63α accumulation without affecting TICs proliferation, whereas the combination Cetuximab plus radiation significantly reduced TICs growth under non‐differentiating conditions. Together, our findings provide evidence that ΔNp63α expression is regulated by EGFR activation through STAT3 and that the EGFR–ΔNp63α axis is crucial for proliferation of TICs present in SCCs. J. Cell. Physiol. 228: 871–878, 2013. © 2012 Wiley Periodicals, Inc.     

Regulation of ΔNp63α by NFκΒ

ΔNp63α, the dominant negative isoform of the p63 family is an essential survival factor in head and neck squamous cell carcinoma. This isoform has been shown to be down regulated in response to several DNA damaging agents, thereby enabling an effective cellular response to genotoxic agents. Here, we identify a key molecular mechanism underlying the regulation of ΔNp63α expression in response to extrinsic stimuli, such as chemotherapeutic agents. We show that ΔNp63α interacts with NF-κΒ in presence of cisplatin. We find that NF-κΒ promotes ubiquitin-mediated proteasomal degradation of ΔNp63α. Chemotherapy-induced stimulation of NF-κΒ leads to degradation of ΔNp63α and augments trans-activation of p53 family-induced genes involved in the cellular response to DNA damage. Conversely, inhibition of NF-κΒ with siRNA-mediated silencing NF-κΒ expression attenuates chemotherapy induced degradation of ΔNp63α . These data demonstrate that NF-κΒ plays an essential role in regulating ΔNp63α in response to extrinsic stimuli. Our findings suggest that the activation of NF-κΒ may be a mechanism by which levels of ΔNp63α are reduced, thereby rendering the cells susceptible to cell death in the face of cellular stress or DNA damage.     

TAp63 plays compensatory roles in p53-deficient cancer cells under genotoxic stress

p53, p63, and p73 belong to the p53 family of proteins, which mediate development, differentiation, and various other cellular responses. p53 is involved in many anti-cancer mechanisms, such as cell cycle regulation, apoptosis, and the maintenance of genomic integrity. The p63 gene is controlled by two promoters that direct the expression of two isoforms, one with and one without transactivating properties, known as TAp63 and ΔNp63. In this study, p53-deficient cells (Hep3B and PC-3) and p53-expressing cells (A549 and HepG2) were treated with doxorubicin to examine the possible roles of TAp63 in these cells under genotoxic stress; TAp63 expression was induced in p53-deficient cell lines, but not in p53-expressing cell lines. The ectopic expression of p53 in p53-deficient cells (Hep3B) reduced TAp63 promoter activity, and knockdown of TAp63 attenuated doxorubicin-induced cell growth arrest by promoting cell cycle progression, leading to an increase in the percentage of G(2)/M cells. Moreover, knockdown of TAp63 increased cell sensitivity to doxorubicin-induced genomic damage. Our results suggest that TAp63 may play a compensatory role in cell cycle regulation and DNA damage repair in p53-deficient cancer cells.     

Cell density-dependent acetylation of ΔNp63α is associated with p53-dependent cell cycle arrest

ΔNp63α is a p63 isoform that is predominantly expressed in the epidermal stem cells and in cancer. To find the regulatory pathways of ΔNp63α, we assessed whether ΔNp63α is acetylated and determined the functional implications of acetylation. First, the hinge region of p63 was shown to be acetylated by PCAF, similarly to other p53 family members. Second, acetylation synergistically induced cytoplasmic localization of ΔNp63α. Finally, acetyl-ΔNp63α was induced during high-density culture, suggesting that acetylation of ΔNp63α may reinforce cell cycle arrest upon cell contact. Altogether, these findings suggest that acetylation of ΔNp63α contributes to the epidermal homeostasis.     

IkappaB kinase beta promotes cell survival by antagonizing p53 functions through DeltaNp73alpha phosphorylation and stabilization

ΔNp73α, a dominant-negative inhibitor of p53 and p73, exhibits antiapoptotic and transforming activity in in vitro models and is often found to be upregulated in human cancers. The mechanisms involved in the regulation of ΔNp73α protein levels in normal and cancer cells are poorly characterized. Here, we show that that IκB kinase beta (IKKβ) increases ΔNp73α protein stability independently of its ability to activate NF-κB. IKKβ associates with and phosphorylates ΔNp73α at serine 422 (S422), leading to its accumulation in the nucleus, where it binds and represses several p53-regulated genes. S422A mutation in ΔNp73α abolished IKKβ-mediated stabilization and inhibition of p53-regulated gene expression. Inhibition of IKKβ activity by chemical inhibitors, overexpression of dominant-negative mutants, or gene silencing by siRNA also resulted in ΔNp73α destabilization, which under these conditions was rapidly translocated into the cytoplasm and degraded by a calpain-mediated mechanism. We also present evidence for the IKKβ and ΔNp73α cross talk in cancer-derived cell lines and primary cancers. Our data unveil a new mechanism involved in the regulation of the p73 and p53 network.     

Tumor‐suppressive roles of ΔNp63β‐miR‐205 axis in epithelial–mesenchymal transition of oral squamous cell carcinoma via targeting ZEB1 and ZEB2

We previously revealed that epithelial‐to‐mesenchymal transition (EMT) was mediated by ΔNp63β, a splicing variant of ΔNp63, in oral squamous cell carcinoma (OSCC). Recent studies have highlighted the involvement of microRNA (miRNA) in EMT of cancer cells, though the mechanism remains unclear. To identify miRNAs responsible for ΔNp63β‐mediated EMT, miRNA microarray analyses were performed by ΔNp63β‐overexpression in OSCC cells; SQUU‐B, which lacks ΔNp63 expression and displays EMT phenotypes. miRNAs microarray analyses revealed miR‐205 was the most up‐regulated following ΔNp63β‐overexpression. In OSCC cells, miR‐205 expression was positively associated with ΔNp63 and negatively with zinc‐finger E‐box binding homeobox (ZEB) 1 and ZEB2, potential targets of miR‐205. miR‐205 overexpression by miR‐205 mimic transfection into SQUU‐B cells led to decreasing ZEB1, ZEB2, and mesenchymal markers, increasing epithelial markers, and reducing cell motilities, suggesting inhibition of EMT phenotype. Interestingly, the results opposite to this phenomenon were obtained by transfection of miR‐205 inhibitor into OSCC cells, which express ΔNp63 and miR‐205. Furthermore, target protector analyses revealed direct regulation by miR‐205 of ZEB1 and ZEB2 expression. These results showed tumor‐suppressive roles of ΔNp63β and miR‐205 by inhibiting EMT thorough modulating ZEB1 and ZEB2 expression in OSCC.     

The Fatty Acid Synthase Gene is a Conserved p53 Family Target Gene from Worm to Human

The discovery that the p53 family consists of three members (p53, p63 and p73) in vertebrates and of a single homolog in invertebrates has raised the challenge of understanding the functions of the ancestor and how they have evolved and differentiated within the duplicated genes in vertebrates. Here, we report that the fatty acid synthase (FAS) gene, encoding for a key enzyme involved in the biogenesis of membrane lipids in rapidly proliferating cells, is a conserved target of the p53 family throughout the evolution. We show that CEP-1, the C. elegans p53 homolog, is able to bind the two p53 family responsive elements (REs) identified in the worm fasn-1 gene. Moreover, we demonstrate that fasn-1 expression is modulated by CEP-1 in vivo, by comparing wild-type and CEP-1 knockout worms. In human, luciferase and chromatin immunoprecipitation assays demonstrate that TAp73α and ΔNp63α, but not p53, TAp73β and TAp63α bind the two p53 REs of the human FASN gene. We show that the ectopic expression of TAp73β and ΔNp63α leads to an increase of FASN mRNA levels, while their silencing produces a decrease of FASN expression. Furthermore, we present data showing a correlation between ΔNp63α and FASN expression in cellular proliferation. Of relevant importance is that fasn-1 is the first CEP-1 direct target gene identified so far in C. elegans and our results suggest a new CEP-1 role in cellular proliferation and development, besides the one already described in apoptosis of germ cells. These data confirm the hypothesis that the ancestral functions of the single invertebrate gene may have been spread out among the three vertebrate members, each of them have acquired specific role in cell cycle regulation.