K. Eric Paulson

TNF-α induction of lipolysis is mediated through activation of the extracellular signal related kinase pathway in 3T3-L1 adipocytes†‡

Tumor necrosis factor‐α (TNF‐α) increases adipocyte lipolysis after 6–12 h of incubation. TNF‐α has been demonstrated to activate mitogen‐activated protein (MAP) kinases including extracellular signal‐related kinase (ERK) and N‐terminal‐c‐Jun‐kinase (JNK) in different cell types. To determine if the MAP kinases have a role in TNF‐α‐induced lipolysis, 3T3‐L1 adipocytes were treated with the cytokine (10 ng/ml), in the presence or absence of PD98059 or U0126 (100 µM), specific inhibitors of ERK activity. We demonstrated that U0126 or PD98059 blocked TNF‐α‐induced ERK activity and decreased TNF‐α‐induced lipolysis by 65 or 76% respectively. The peroxisome‐proliferator‐activated receptor γ (PPARγ) agonists, rosiglitazone (ros), and 15‐deoxy‐Δ‐12,14‐ prostaglandin J2 (PGJ2) have been demonstrated to block TNF‐α‐induced lipolysis. Pretreatment of adipocytes with these agents almost totally blocked TNF‐α‐induced ERK activation and reduced lipolysis by greater than 90%. TNF‐α also stimulated JNK activity, which was not affected by PD98059 or PPARγ agonist treatment. The expression of perilipin, previously proposed to contribute to the mechanism of lipolysis, is diminished in response to TNF‐α treatment. Pretreatment of adipocytes with PD98059 or ros significantly blocked the TNF‐α‐induced reduction of perilipin A protein level as determined by Western analysis. These data suggest that activation of the ERK pathway is an early event in the mechanism of TNF‐α‐induced lipolysis.

Suppression of Wnt Signaling by the Green Tea Compound (–)-Epigallocatechin 3-Gallate (EGCG) in Invasive Breast Cancer Cells REQUIREMENT OF THE TRANSCRIPTIONAL REPRESSOR HBP1

Genetic and biochemical de-regulation of Wnt signaling is correlated with breast and other cancers. Our goal was to identify compounds that block Wnt signaling as a first step toward investigating new strategies for suppression of invasive and other breast cancers. In a limited phytonutrient screen, EGCG ((–)-epigallocatechin 3-gallate), the major phytochemical in green tea, emerged as an intriguing candidate. Epidemiological studies have associated green tea consumption with reduced recurrence of invasive and other breast cancers. Wnt signaling was inhibited by EGCG in a dose-dependent manner in breast cancer cells. The apparent mechanism targeted the HBP1 transcriptional repressor, which we had previously characterized as a suppressor of Wnt signaling. EGCG treatment induced HBP1 transcriptional repressor levels through an increase in HBP1 mRNA stability, but not transcriptional initiation. To test functionality, DNA-based short hairpin RNA (shRNA) was used to knockdown the endogenous HBP1 gene. Consistently, the HBP1 knockdown lines had reduced sensitivity to EGCG in the suppression of Wnt signaling and of a target gene (c-MYC). Because our ongoing studies clinically link abrogation of HBP1 with invasive breast cancer, we tested if EGCG also regulated biological functions associated with de-regulated Wnt signaling and with invasive breast cancer. EGCG reduced both breast cancer cell tumorigenic proliferation and invasiveness in an HBP1-dependent manner. Together, the emerging mechanism is that EGCG blocks Wnt signaling by inducing the HBP1 transcriptional repressor and inhibits aspects of invasive breast cancer. These studies provide a framework for considering future studies in breast cancer treatment and prevention.

Negative regulation of the Wnt–β‐catenin pathway by the transcriptional repressor HBP1

In certain cancers, constitutive Wnt signaling results from mutation in one or more pathway components. The result is the accumulation and nuclear localization of β‐catenin, which interacts with the lymphoid enhancer factor‐1 (LEF)/T‐cell factor (TCF) family of HMG‐box transcription factors, which activate important growth regulatory genes, including cyclin D1 and c‐myc. As exemplified by APC and axin, the negative regulation of β‐catenin is important for tumor suppression. Another potential mode of negative regulation is transcriptional repression of cyclin D1 and other Wnt target genes. In mammals, the transcriptional repressors in the Wnt pathway are not well defined. We have previously identified HBP1 as an HMG‐box repressor and a cell cycle inhibitor. Here, we show that HBP1 is a repressor of the cyclin D1 gene and inhibits the Wnt signaling pathway. The inhibition of Wnt signaling and growth requires a common domain of HBP1. The apparent mechanism is an inhibition of TCF/LEF DNA binding through a physical interaction with HBP1. These data suggest that the suppression of Wnt signaling by HBP1 may be a mechanism to prevent inappropriate proliferation.

Age-associated increase in PGE2 synthesis and COX activity in murine macrophages is reversed by vitamin E

We previously showed that increased macrophage and PGE2 production with age is due to enhanced cyclooxygenase (COX) activity and COX-2 expression. This study determined the effect of vitamin E supplementation on macrophage PGE2 synthesis in young and old mice and its underlying mechanism. Mice were fed 30 or 500 parts per million vitamin E for 30 days. Lipopolysaccharide (LPS)-stimulated macrophages from old mice produced significantly more PGE2 than those from young mice. Vitamin E supplementation reversed the increased PGE2 production in old mice but had no effect on macrophage PGE2production in young mice. In both LPS-stimulated and unstimulated macrophages, COX activity was significantly higher in old than in young mice at all intervals. Vitamin E supplementation completely reversed the increased COX activity in old mice to levels comparable to those of young mice but had no effect on macrophage COX activity of young mice or on COX-1 and COX-2 protein or COX-2 mRNA expression in young or old mice. Thus vitamin E reverses the age-associated increase in macrophage PGE2 production and COX activity. Vitamin E exerts its effect posttranslationally, by inhibiting COX activity.We previously showed that increased macrophage and PGE2 production with age is due to enhanced cyclooxygenase (COX) activity and COX-2 expression. This study determined the effect of vitamin E supplementation on macrophage PGE2 synthesis in young and old mice and its underlying mechanism. Mice were fed 30 or 500 parts per million vitamin E for 30 days. Lipopolysaccharide (LPS)-stimulated macrophages from old mice produced significantly more PGE2 than those from young mice. Vitamin E supplementation reversed the increased PGE2 production in old mice but had no effect on macrophage PGE2 production in young mice. In both LPS-stimulated and unstimulated macrophages, COX activity was significantly higher in old than in young mice at all intervals. Vitamin E supplementation completely reversed the increased COX activity in old mice to levels comparable to those of young mice but had no effect on macrophage COX activity of young mice or on COX-1 and COX-2 protein or COX-2 mRNA expression in young or old mice. Thus vitamin E reverses the age-associated increase in macrophage PGE2 production and COX activity. Vitamin E exerts its effect posttranslationally, by inhibiting COX activity.

Ceramide-induced and Age-associated Increase in Macrophage COX-2 Expression Is Mediated through Up-regulation of NF-κB Activity

We have shown that the age-associated increase in lipopolysaccharide (LPS)-stimulated macrophages (Mφ) prostaglandin E2 (PGE2) production is because of ceramide-induced up-regulation of cyclooxygenase (COX)-2 transcription that leads to increased COX-2 expression and enzyme activity. To determine the mechanism of the age-related and ceramide-dependent increase in COX-2 transcription, we investigated the role of various transcription factors involved in COX-2 gene expression. The results showed that LPS-initiated activations of both consensus and COX-2-specific NF-κB, but not AP-1 and CREB, were significantly higher in Mφ from old mice than those from young mice. We further showed that the higher NF-κB activation in old Mφ was because of greater IκB degradation in the cytoplasm and p65 translocation to the nucleus. An IκB phosphorylation inhibitor, Bay 11-7082, inhibited NF-κB activation, as well as PGE2 production, COX activity, COX-2 protein, and mRNA expression in both young and old Mφ. Similar results were obtained by blocking NF-κB binding activity using a NF-κB decoy. Furthermore, NF-κB inhibition resulted in significantly greater reduction in PGE2 production and COX activity in old compared with young Mφ. Addition of ceramide to the young Mφ, in the presence or absence of LPS, increased NF-κB activation in parallel with PGE2 production. Bay 11-7082 or NF-κB decoy prevented this ceramide-induced increase in NF-κB binding activity and PGE2 production. These findings strongly suggest that the age-associated and ceramide-induced increase in COX-2 transcription is mediated through higher NF-κB activation, which is, in turn, because of a greater IκB degradation in old Mφ.

The HBP1 Transcriptional Repressor Participates in RAS-Induced Premature Senescence

ABSTRACT Oncogene-mediated premature senescence has emerged as a potential tumor-suppressive mechanism in early cancer transitions. Previous work shows that RAS and p38 MAPK participate in premature senescence, but transcriptional effectors have not been identified. Here, we demonstrate that the HBP1 transcriptional repressor participates in RAS- and p38 MAPK-induced premature senescence. In cell lines, we had previously isolated HBP1 as a retinoblastoma (RB) target but have determined that it functions as a proliferation regulator by inhibiting oncogenic pathways as a transcriptional repressor. In primary cells, the results indicate that HBP1 is a necessary component of premature senescence by RAS and p38 MAPK. Similarly, a knockdown of WIP1 (a p38 MAPK phosphatase) induced premature senescence that also required HBP1. Furthermore, HBP1 requires regulation by RB, in which few transcriptional regulators for premature senescence have been shown. Together, the data suggest a model in which RAS and p38 MAPK signaling engage HBP1 and RB to trigger premature senescence. As an initial step toward clinical relevance, a bioinformatics approach shows that the relative expression levels of HBP1 and WIP1 correlated with decreased relapse-free survival in breast cancer patients. Together, these studies highlight p38 MAPK, HBP1, and RB as important components for a premature-senescence pathway with possible clinical relevance to breast cancer.

HBP1 repression of the p47phox gene: cell cycle regulation via the NADPH oxidase.

ABSTRACT Several studies have linked the production of reactive oxygen species (ROS) by the NADPH oxidase to cellular growth control. In many cases, activation of the NADPH oxidase and subsequent ROS generation is required for growth factor signaling and mitogenesis in nonimmune cells. In this study, we demonstrate that the transcriptional repressor HBP1 (HMG box-containing protein 1) regulates the gene for the p47phox regulatory subunit of the NADPH oxidase. HBP1 represses growth regulatory genes (e.g., N-Myc, c-Myc, and cyclin D1) and is an inhibitor of G1 progression. The promoter of the p47phox gene contains six tandem high-affinity HBP1 DNA-binding elements at positions −1243 to −1318 bp from the transcriptional start site which were required for repression. Furthermore, HBP1 repressed the expression of the endogenous p47phox gene through sequence-specific binding. With HBP1 expression and the subsequent reduction in p47phox gene expression, intracellular superoxide production was correspondingly reduced. Using both the wild type and a dominant-negative mutant of HBP1, we demonstrated that the repression of superoxide production through the NADPH oxidase contributed to the observed cell cycle inhibition by HBP1. Together, these results indicate that HBP1 may contribute to the regulation of NADPH oxidase-dependent superoxide production through transcriptional repression of the p47phox gene. This study defines a transcriptional mechanism for regulating intracellular ROS levels and has implications in cell cycle regulation.

Epigallocatechin-3-gallate inhibits stem-like inflammatory breast cancer cells.

Inflammatory Breast Cancer (IBC) is a highly aggressive form of cancer characterized by high rates of proliferation, lymphangiogenesis and metastasis, and an overall poor survival. As regular green tea consumption has been associated with improved prognosis of breast cancer patients, including decreased risk of recurrence, here the effects of the green tea polyphenol epigallocatechin-3-gallate (EGCG) were tested on two IBC lines: SUM-149 and SUM-190. EGCG decreased expression of genes that promote proliferation, migration, invasion, and survival. Consistently, growth, invasive properties, and survival of IBC cells were reduced by EGCG treatment. EGCG also reduced lymphangiogenesis-promoting genes, in particular VEGF-D. Conditioned media from EGCG-treated IBC cells displayed decreased VEGF-D secretion and reduced ability to promote lymphangiogenesis in vitro as measured by hTERT-HDLEC lymphatic endothelial cell migration and tube formation. Tumorsphere formation by SUM-149 cells was robustly inhibited by EGCG, suggesting effects on self-renewal ability. Stem-like SUM-149 cells with high aldehyde dehydrogenase (ALDH) activity, previously implicated in poor patient prognosis, were isolated. EGCG treatment reduced growth and induced apoptosis of the stem-like SUM-149 cells in culture. In an orthotopic mouse model, EGCG decreased growth of pre-existing tumors derived from ALDH-positive stem-like SUM-149 cells and their expression of VEGF-D, which correlated with a significant decrease in peritumoral lymphatic vessel density. Thus, EGCG inhibits the overall aggressive IBC phenotype. Reduction of the stem-like cell compartment by EGCG may explain the decreased risk of breast cancer recurrence among green tea drinkers. Recent clinical trials demonstrate the efficacy of green tea polyphenol extracts in treatment of prostate cancer and lymphocytic leukemia with low toxicity. Given the poor prognosis of IBC patients, our findings suggest further exploration of EGCG or green tea in combinatorial treatments against active IBC disease or in maintenance regimens to avoid recurrence is warranted.

The transcriptional repressor HBP1 is a target of the p38 mitogen-activated protein kinase pathway in cell cycle regulation

ABSTRACT The p38 mitogen-activated protein (MAP) kinase signaling pathway participates in both apoptosis and G1 arrest. In contrast to the established role in apoptosis, the documented induction of G1 arrest by activation of the p38 MAP kinase pathway has attracted recent attention with reports of substrates that are linked to cell cycle regulation. Here, we identify the high-mobility group box protein HBP1 transcriptional repressor as a new substrate for p38 MAP kinase. Our previous work had shown that HBP1 inhibits G1 progression in cell and animal models, and thus indicated that HBP1 could be a relevant substrate for p38 MAP kinase in cell cycle regulation. In the present work, a p38 MAP kinase docking site (amino acids [aa] 81 to 125) and a p38 MAP kinase phosphorylation site (serine 401) were identified in the HBP1 protein. Furthermore, the docking and phosphorylation sites on HBP1 were specific for p38 MAP kinase. In defining the role of p38 MAP kinase regulation, the inhibition of p38 MAP kinase activity was shown to decrease HBP1 protein levels by triggering protein instability, as manifested by a decrease in protein half-life. Consistently, a decrease in protein levels was accompanied by a decrease in overall DNA binding activity. A mutation of the p38 MAP kinase phosphorylation site at aa 401 [(S-A)401HBP1] also triggered HBP1 protein instability. While protein stability was compromised by mutation, the specific activities of (S-A)401HBP1 and of wild-type HBP1 appeared comparable for transcriptional repression. This comparison of transcription-specific activity highlighted that p38 MAP kinase regulated HBP1 protein levels but not the intrinsic activity for DNA binding or for transcriptional repression. Finally, p38 MAP kinase-mediated regulation of the HBP1 protein also contributed to the regulation of G1 progression. Together, our work supports a molecular framework in which p38 MAP kinase activity contributes to cell cycle inhibition by increasing HBP1 and other G1 inhibitory factors by regulating protein stability.

Role of membrane lipids in regulation of vulnerability to oxidative stress in PC12 cells: implication for aging

Previously, we reported that PC12 cells showed increased vulnerability to oxidative stress (OS) induced by H2O2 (as assessed by decrements in calcium recovery, i.e., the ability of cells to buffer Ca(2+) after a depolarization event) when the membrane levels of cholesterol (CHL) and sphingomyelin (SPH) were modified to approximate those seen in the neuronal membranes of old animals. The present study was designed to examine whether the enrichment of the membranes with SPH-CHL and increased cellular vulnerability to OS are mediated by neutral SPH-specific phospholipase C (N-Sase) and the intracellular antioxidant GSH. The results showed a significant up-regulation of N-Sase activity by both low (5 microM) and high (300 microM) doses of H2O2. However, under high doses of H2O2 the up-regulation of N-Sase is accompanied by a significant increase in reactive oxygen species and by a decrease in intracellular GSH. The enrichment of membranes with SPH-CHL significantly potentiated the effects of high doses of H2O2, by further reducing the intracellular GSH and further up-regulating the N-Sase activity. Furthermore, repleting intracellular GSH with 20 mM N-acetylcysteine treatment was sufficient to attenuate the effect of a low dose of H2O2 on Ca(2+) recovery in SPH-CHL-treated cells. Thus, these results suggested that age-related alterations in the membrane SPH-CHL levels could be important determinants of the susceptibility of neuronal cells to OS.