Regina M. Graham scite author profile

The c- fos serum response element (SRE) is a primary nuclear target for intracellular signal transduction pathways triggered by growth factors. It is the target for both protein kinase C (PKC)-dependent and -independent signals. Function of the SRE requires binding of a cellular protein, termed serum response factor (SRF). A second protein, p62 TCF , recognizes the SRE-SRF complex to form a ternary complex. A mutated SRE that bound SRF but failed to form the ternary complex selectively lost response to PKC activators, but retained response to PKC-independent signals. Thus, two different signaling pathways act through discrete nuclear targets at the SRE. At least one of these pathways functions by recruitment of a pathway-specific accessory factor (p62 TCF ). These results offer a molecular mechanism to account for the biological specificity of signals that appear to act through common DNA sequence elements.

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Hyperinnervation of the Airways in Transgenic Mice Overexpressing Nerve Growth Factor

Hoyle

Graham

Finkelstein

et al. 1998

Am J Respir Cell Mol Biol

190

152

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Neuropeptides released from sensory nerve endings are potential mediators of airway inflammation in asthma and lung injury induced by inhalation of respiratory irritants. To develop an in vivo model for assessing the contribution of neurogenic inflammation in these processes, we have generated transgenic mice with altered innervation of the lung. To generate mice with an increased innervation of the airways, we placed the gene that encodes nerve growth factor (NGF) under control of the lung-specific Clara-cell secretory protein (CCSP) promoter. Two lineages of CCSP-NGF transgenic mice overexpressed NGF in the lung and developed a hyperinnervation of the airways. Immunohistochemistry for substance P, a substance P enzyme immunoassay, and catecholamine histofluorescence indicated that both tachykinin-containing sensory fibers and sympathetic fibers were increased around the airways of CCSP-NGF mice. Treatment of CCSP-NGF mice with the sympathetic-specific neurotoxin 6-hydroxydopamine (6-OHDA) eliminated the sympathetic component of the airway innervation, leaving a specific hyperinnervation by tachykinin-containing sensory fibers. CCSP-NGF mice were more sensitive than normal mice to capsaicin-induced increases in respiratory system resistance, demonstrating that the increased sensory innervation led to a change in airway function. We conclude that NGF overexpression from a lung-specific promoter produces anatomic and functional changes in lung innervation, and that CCSP-NGF mice will be useful for studying the role of neurogenic inflammation in airway disease.

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A unique pathway of cardiac myocyte death caused by hypoxia–acidosis

et al. 2004

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SUMMARY Chronic hypoxia in the presence of high glucose leads to progressive acidosis of cardiac myocytes in culture. The condition parallels myocardial ischemia in vivo, where ischemic tissue becomes rapidly hypoxic and acidotic. Cardiac myocytes are resistant to chronic hypoxia at neutral pH but undergo extensive death when the extracellular pH (pH[o]) drops below 6.5. A microarray analysis of 20 000 genes (cDNAs and expressed sequence tags)screened with cDNAs from aerobic and hypoxic cardiac myocytes identified>100 genes that were induced by >2-fold and ∼20 genes that were induced by >5-fold. One of the most strongly induced transcripts was identified as the gene encoding the pro-apoptotic Bcl-2 family member BNIP3. Northern and western blot analyses confirmed that BNIP3 was induced by 12-fold(mRNA) and 6-fold (protein) during 24 h of hypoxia. BNIP3 protein, but not the mRNA, accumulated 3.5-fold more rapidly under hypoxia–acidosis. Cell fractionation experiments indicated that BNIP3 was loosely bound to mitochondria under conditions of neutral hypoxia but was translocated into the membrane when the myocytes were acidotic. Translocation of BNIP3 coincided with opening of the mitochondrial permeability pore (MPTP). Paradoxically,mitochondrial pore opening did not promote caspase activation, and broad-range caspase inhibitors do not block this cell death pathway. The pathway was blocked by antisense BNIP3 oligonucleotides and MPTP inhibitors. Therefore,cardiac myocyte death during hypoxia–acidosis involves two distinct steps: (1) hypoxia activates transcription of the death-promoting BNIP3 gene through a hypoxia-inducible factor-1 (HIF-1) site in the promoter and (2) acidosis activates BNIP3 by promoting membrane translocation. This is an atypical programmed death pathway involving a combination of the features of apoptosis and necrosis. In this article, we will review the evidence for this unique pathway of cell death and discuss its relevance to ischemic heart disease. The article also contains new evidence that chronic hypoxia at neutral pH does not promote apoptosis or activate caspases in neonatal cardiac myocytes.

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BET bromodomain proteins are required for glioblastoma cell proliferation

et al. 2014

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Epigenetic proteins have recently emerged as novel anticancer targets. Among these, bromodomain and extra terminal domain (BET) proteins recognize lysine-acetylated histones, thereby regulating gene expression. Newly described small molecules that inhibit BET proteins BRD2, BRD3, and BRD4 reduce proliferation of NUT (nuclear protein in testis)-midline carcinoma, multiple myeloma, and leukemia cells in vitro and in vivo. These findings prompted us to determine whether BET proteins may be therapeutic targets in the most common primary adult brain tumor, glioblastoma (GBM). We performed NanoString analysis of GBM tumor samples and controls to identify novel therapeutic targets. Several cell proliferation assays of GBM cell lines and stem cells were used to analyze the efficacy of the drug I-BET151 relative to temozolomide (TMZ) or cell cycle inhibitors. Lastly, we performed xenograft experiments to determine the efficacy of I-BET151 in vivo. We demonstrate that BRD2 and BRD4 RNA are significantly overexpressed in GBM, suggesting that BET protein inhibition may be an effective means of reducing GBM cell proliferation. Disruption of BRD4 expression in glioblastoma cells reduced cell cycle progression. Similarly, treatment with the BET protein inhibitor I-BET151 reduced GBM cell proliferation in vitro and in vivo. I-BET151 treatment enriched cells at the G1/S cell cycle transition. Importantly, I-BET151 is as potent at inhibiting GBM cell proliferation as TMZ, the current chemotherapy treatment administered to GBM patients. Since I-BET151 inhibits GBM cell proliferation by arresting cell cycle progression, we propose that BET protein inhibition may be a viable therapeutic option for GBM patients suffering from TMZ resistant tumors.

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Regina M. Graham

Distinct Protein Targets for Signals Acting at the c- fos Serum Response Element

Hyperinnervation of the Airways in Transgenic Mice Overexpressing Nerve Growth Factor

A unique pathway of cardiac myocyte death caused by hypoxia–acidosis

BET bromodomain proteins are required for glioblastoma cell proliferation

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