Madhavi P. Kadakia

Alpha-Melanocyte–Stimulating Hormone Suppresses Oxidative Stress through a p53-Mediated Signaling Pathway in Human Melanocytes

Epidermal melanocytes are skin cells specialized in melanin production. Activation of the melanocortin 1 receptor (MC1R) on melanocytes by α-melanocyte–stimulating hormone (α-MSH) induces synthesis of the brown/black pigment eumelanin that confers photoprotection from solar UV radiation (UVR). Contrary to keratinocytes, melanocytes are slow proliferating cells that persist in the skin for decades, in an environment with high levels of UVR-induced reactive oxygen species (ROS). We previously reported that in addition to its role in pigmentation, α-MSH also reduces oxidative stress and enhances the repair of DNA photoproducts in melanocytes, independent of melanin synthesis. Given the significance of ROS in carcinogenesis, here we investigated the mechanisms by which α-MSH exerts antioxidant effects in melanocytes. We show that activation of the MC1R by α-MSH contributes to phosphorylation of p53 on serine 15, a known requirement for stabilization and activation of p53, a major sensor of DNA damage. This effect is mediated by the cAMP/PKA pathway and by the activation of phosphoinositide 3-kinase (PI3K) ATR and DNA protein kinase (DNA-PK). α-MSH increases the levels of 8-oxoguanine DNA glycosylase (OGG1) and apurinic apyrimidinic endonuclease 1 (APE-1/Ref-1), enzymes essential for base excision repair. Nutlin-3, an HDM2 inhibitor, mimicked the effects of α-MSH resulting in reduced phosphorylation of H2AX (γ-H2AX), a marker of DNA damage. Conversely, the p53 inhibitor pifithrin-α or silencing of p53 abolished the effects of α-MSH and augmented oxidative stress. These results show that p53 is an important target of the downstream MC1R signaling that reduces oxidative stress and possibly malignant transformation of melanocytes. Mol Cancer Res; 10(6); 778–86. ©2012 AACR.

CXCL12/CXCR4 Protein Signaling Axis Induces Sonic Hedgehog Expression in Pancreatic Cancer Cells via Extracellular Regulated Kinase- and Akt Kinase-mediated Activation of Nuclear Factor κB IMPLICATIONS FOR BIDIRECTIONAL TUMOR-STROMAL INTERACTIONS

Background: CXCL12/CXCR4 and hedgehog pathways, predominantly acting in paracrine fashion, play important roles in pancreatic cancer pathobiology. Results: CXCL12/CXCR4 signaling regulates the expression of hedgehog ligand, the sonic hedgehog, in pancreatic cancer cells. Conclusion: Our findings indicate a novel molecular link between CXCL12/CXCR4 and hedgehog pathways. Significance: Our data provide a molecular basis for an active bidirectional tumor-stromal interaction in pancreatic cancer. Recent evidence suggests a major role of tumor-stromal interactions in pancreatic cancer pathobiology. The chemokine CXCL12 (stromal cell-derived factor 1 (SDF-1)), abundantly produced by stromal cells, promotes progression, metastasis, and chemoresistance of pancreatic cancer cells. On the other hand, pancreatic tumor cell-derived sonic hedgehog (SHH) acts predominantly on stromal cells to induce desmoplasia and, thus, has a paracrine effect on tumorigenesis and therapeutic outcome. In this study, we examined the association between these two proteins of pathological significance in pancreatic cancer. Our data demonstrate that CXCL12 leads to a dose- and time-dependent up-regulation of SHH in pancreatic cancer cells. CXCL12-induced SHH up-regulation is specifically mediated through the receptor CXCR4 and is dependent on the activation of downstream Akt and ERK signaling pathways. Both Akt and ERK cooperatively promote nuclear accumulation of NF-κB by inducing the phosphorylation and destabilization of its inhibitory protein, IκB-α. Using dominant negative IκB-α, a SHH promoter (deletion mutant) reporter, and chromatin immunoprecipitation assays, we demonstrate that CXCL12 exposure enhances direct binding of NF-κB to the SHH promoter and that suppression of NF-κB activation abrogates CXCL12-induced SHH expression. Finally, our data demonstrate a strong correlative expression of CXCR4 and SHH in human pancreatic cancer tissues, whereas their expression is not observed in the normal pancreas. Altogether, our data reveal a novel mechanism underlying aberrant SHH expression in pancreatic cancer and identify a molecular link facilitating bidirectional tumor-stromal interactions.

Regulation of p63 Function by Mdm2 and MdmX

p63, a p53-related protein, has been shown to activate p53-responsive genes and induce apoptosis in certain cell types. In this study, we examined the effects of Mdm2 and MdmX proteins on p63 transactivation, apoptosis, and protein levels. The isoforms of p63 most structurally similar to p53, p63gamma (p51A) and p63alpha (p51B), were chosen for study. Our results confirm earlier reports demonstrating that although both p63 isoforms can transactivate p53-responsive promoters and induce apoptosis, p63gamma has a stronger transactivation potential and is a more potent inducer of apoptosis than is p63alpha. In addition, both Mdm2 and MdmX were able to inhibit the transactivation induced by p63gamma and p63alpha. However, only Mdm2 overexpression led to a detectable decrease in p63-induced apoptosis. Although Mdm2 binding to p53 triggers ubiquitin-mediated proteosome degradation, p63 protein levels were unaltered by association with either Mdm2 or MdmX. Finally, immunofluorescence experiments showed that both p63 isoforms were localized in the nucleus and could be exported when coexpressed with Mdm2 but not with MdmX. These findings suggest that both Mdm2 and MdmX can downregulate p63 transactivation potential; however, only Mdm2 is capable of inhibiting the apoptotic function of p63 by removing it from the nucleus.

p63 Overexpression Induces the Expression of Sonic Hedgehog

p63 and p73 are members of the p53 protein family and have been shown to play an important role in cell death, development, and tumorigenesis. In particular, p63 has been shown to be involved in the maintenance of epidermal stem cells and in the stratification of the epidermis. Sonic Hedgehog (Shh) is a morphogen that has also been implicated to play a role in epithelial stem cell proliferation and in the development of organs. Recently, Shh has also been shown to play an important role in the progression of a variety of cancers. In this report, we show that p63 and p73 but not p53 overexpression induces Shh expression. In particular, p63γ and p63β (both TA and ΔN isoforms) and TAp73β isoform induce Shh. Expression of Shh was found to be significantly reduced in mouse embryo fibroblasts obtained from p63−/− mice. The naturally occurring p63 mutant TAp63γ(R279H) and the tumor suppressor protein p14ARF inhibited the TAp63γ-mediated transactivation of Shh. The region −228 to −102 bp of Shh promoter was found to be responsive to TAp63γ-induced transactivation and TAp63γ binds to regions within the Shh promoter in vivo. The results presented in this study implicate p63 in the regulation of the Shh signaling pathway. (Mol Cancer Res 2006;4(10):759–68)

Identification of vitamin D receptor as a target of p63.

p63, a p53 homolog has been shown to play a role in development and cancer. p63 is essential for both commitment of ectoderm to stratified epithelia and for the proliferative potential of epithelial stem cells. p63 knockout mice are born with severe development defects and lack organs of epithelial origin. In addition, p63 has also been shown to play a role in cancer development through the differential regulation of genes with tumor suppressor function and genes involved in metastasis. In order to understand the role of p63 in cancer and development, genes that are specifically regulated by p63 but not p53 were identified. In this study, we provide evidence that p63γ specifically upregulates vitamin D Receptor (VDR). In contrast, p53 does not appear to be involved in upregulation of VDR expression. Additionally, we demonstrate that a naturally occurring p63 missense mutant, p63γ (R279H) and p14ARF, both act in a dominant negative manner to inhibit p63γ-mediated upregulation of VDR. Furthermore, using chromatin immunoprecipitation assays, we demonstrated that p63 directly binds to the VDR promoter in vivo. Our findings clearly demonstrate that VDR is a direct target of p63 and suggests that p63 may play a role in cancer and differentiation through modulation of the VDR pathway.

Cellular internalization and targeting of semiconductor quantum dots

Peptide-mediated internalization and organelle targeting of quantum dots.

Clay enriched silk biomaterials for bone formation.

The formation of silk protein/clay composite biomaterials for bone tissue formation is described. Silk fibroin serves as an organic scaffolding material offering mechanical stability suitable for bone-specific uses. Clay montmorillonite (Cloisite® Na(+)) and sodium silicate are sources of osteoinductive silica-rich inorganic species, analogous to bioactive bioglass-like bone repair biomaterial systems. Different clay particle-silk composite biomaterial films were compared with silk films doped with sodium silicate as controls for the support of human bone marrow derived mesenchymal stem cells in osteogenic culture. The cells adhered to and proliferated on the silk/clay composites over 2 weeks. Quantitative real time polymerase chain reaction analysis revealed increased transcript levels for alkaline phosphatase, bone sialoprotein, and collagen type 1 osteogenic markers in the cells cultured on the silk/clay films in comparison with the controls. Early evidence of bone formation based on collagen deposition at the cell-biomaterial interface was also found, with more collagen observed for the silk films with higher contents of clay particles. The data suggest that silk/clay composite systems may be useful for further study for bone regenerative needs.

MdmX Inhibits Smad Transactivation

Mdm2 overexpression confers a growth promoting activity upon cells primarily by downregulating the p53 tumor suppressor protein. Nevertheless, Mdm2 deregulation has also been implicated in inhibiting TGF-β growth repression in a p53 independent manner. Our goal in this study was to examine whether overexpression of Mdm2 or MdmX, a Mdm2-related protein, could affect Smad-induced transactivation. As downstream signaling elements of the TGF-β pathway, Smads represent one potential target for Mdm2 and MdmX. Here we show that MdmX but not Mdm2 is capable of inhibiting Smad induced transactivation. Based on deletion mutant analysis, MdmX inhibition of Smad transactivation was independent of the p53 and Mdm2 interaction domains, yet required amino acid residues 128–444. Using TGF-β sensitive HepG2 cells, MdmX overexpression was shown to inhibit TGF-β induced Smad transactivation. Additionally, mouse embryo fibroblasts (MEFs) lacking p53 and MdmX showed enhanced Smad transactivation when compared to MEFs lacking either p53 or p53 and Mdm2. Interestingly, the inhibition of Smad transactivation by MdmX could be reversed by p300, a functional co-activator of Smads and a necessary factor for Mdm2 nuclear export and did not result from altered Smad localization. In vitro studies demonstrate that MdmX binds to p300 as well as Smad3 and Smad4. Taken together, these results suggest that inhibition of Smad-induced transactivation by MdmX occurs by altering Smad interaction with its coactivator p300.

ΔNp63α regulates keratinocyte proliferation by controlling PTEN expression and localization

ΔNp63α, implicated as an oncogene, is upregulated by activated Akt, part of a well-known cell survival pathway. Inhibition of Akt activation by phosphatase and tensin homolog deleted on chromosome 10 (PTEN) and the presence of putative p63-binding sites in the pten promoter led us to investigate whether ΔNp63α regulates PTEN expression. Knockdown of ΔNp63α led to increases in PTEN levels and loss of activated Akt, while overexpression of ΔNp63α decreased PTEN levels and elevated active Akt. The repression of PTEN by ΔNp63α occurs independently of p53 status, as loss of ΔNp63α increases PTEN expression in cell lines with and without functional p53. In addition, decreased levels of ΔNp63α resulted in an increase in nuclear PTEN. Conversely, in vivo nuclear PTEN was absent in the proliferative basal layer of the epidermis where ΔNp63α expression is highest. Additionally, we show that in keratinocytes a balance between ΔNp63α and PTEN regulates Akt activation and maintains normal proliferation rates. This balance is disrupted in non-melanoma skin cancers through increased ΔNp63α levels, and could enhance proliferation and subsequent neoplastic development. Our studies show that ΔNp63α negatively regulates PTEN, thereby providing a feedback loop between PTEN, Akt and ΔNp63α, which has an integral role in skin cancer development.

Epidermal growth factor: layered silicate nanocomposites for tissue regeneration.

Wound healing is a complex, multistep process that can be summarized into three stages, namely, hemostasis and inflammation, proliferation, and finally, tissue remodeling. Battlefield wound healing demands rapid hemostasis using clotting or cauterizing agents to immediately limit blood loss, but this occurs at the expense of proper tissue repair beyond hemostasis. Layered silicate clays such as kaolin and montmorillonite (MMT) have been previously shown to induce blood clotting due to their ability to form charged interactions with clotting factors. The charge characteristics of sodium MMT (Na-MMT) also enable functionalization with active biomolecules. Herein we functionalized Na-MMT with epidermal growth factor (EGF) via ion exchange reaction to create a nanocomposite (MMT-EGF) with approximately 0.004 EGF molecules per Na(+) exchange site and conduct biochemical analyses of keratinocytes after treatment with MMT-EGF. Our results demonstrate that EGF immobilized on MMT retains the ability to activate the epidermal growth factor receptor (EGRF), causing phosphorylation of the AKT and MEK1 pathways, as well as upregulation of its downstream target gene expression involved in cell growth and migration. This study also shows that like EGF, MMT-EGF treatment can stimulate cell migration in vitro, which is dependent on ERK1/2 phosphorylation.