Gene/Protein
Disease
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Enzyme
Compound
Pivot Concepts:
Gene/Protein
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Target Concepts:
Gene/Protein
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Query: EC:2.7.11.13 (
protein kinase C
)
49,245
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The mouse
NQO2
cDNA and gene with flanking regions were cloned and sequenced. Analysis of the primary structure of the mouse
NQO2
protein revealed the presence of glycosylation, myristylation,
protein kinase C
and caseine kinase II phosphorylation sites. These sites are conserved in the human
NQO2
protein. The mouse
NQO2
gene promoter contains several important cis-elements, including the antioxidant response element (ARE), the xenobiotic response element (XRE), and an Sp1 binding site. Northern analysis of eight mouse tissues indicated wide variations in the expression of the
NQO2
and NQO1 genes.
NQO2
gene expression was higher in liver and testis compared with the NQO1 gene, which was highest in the heart. NQO1 gene expression was undetectable in the testis. Mouse kidney showed significantly higher expression levels of NQO1 compared with
NQO2
. Brain, spleen, lung, and skeletal muscle showed undetectable levels of
NQO2
and NQO1 gene expression.
NQO2
activity followed a more or less similar pattern of tissue-specific expression as
NQO2
RNA. Interestingly, the
NQO2
activity remained unchanged in the NQO1-/-mice tissues compared with NQO1+/+ mice, with the exception of the liver. The livers from NQO1-/-mice showed a 45% increase in
NQO2
activity compared with the NQO1+/+ mice. The mouse
NQO2
cDNA was subcloned into the pMT2 eukaryotic expression vector which, upon transfection in monkey kidney COS1 cells, produced a significant increase in
NQO2
activity. Deletion of 54 amino acids from the N-terminus of the mouse
NQO2
protein resulted in the loss of
NQO2
expression and activity in transfected COS1 cells. This indicates that deletion of exon(s) encoding the N-terminus of
NQO2
from the endogenous gene in mouse embryonic (ES) stem cells should result in
NQO2
-null mice.
...
PMID:Mouse NRH:quinone oxidoreductase (NQO2): cloning of cDNA and gene- and tissue-specific expression. 1090 42
Melatonin, an endogenous signal of darkness, is an important component of the body's internal time-keeping system. As such it regulates major physiological processes including the sleep wake cycle, pubertal development and seasonal adaptation. In addition to its relevant antioxidant activity, melatonin exerts many of its physiological actions by interacting with membrane MT1 and MT2 receptors and intracellular proteins such as
quinone reductase 2
, calmodulin, calreticulin and tubulin. Here we review the current knowledge about the properties and signaling of melatonin receptors as well as their potential role in health and some diseases. Melatonin MT1 and MT2 receptors are G protein coupled receptors which are expressed in various parts of the CNS (suprachiasmatic nuclei, hippocampus, cerebellar cortex, prefrontal cortex, basal ganglia, substantia nigra, ventral tegmental area, nucleus accumbens and retinal horizontal, amacrine and ganglion cells) and in peripheral organs (blood vessels, mammary gland, gastrointestinal tract, liver, kidney and bladder, ovary, testis, prostate, skin and the immune system). Melatonin receptors mediate a plethora of intracellular effects depending on the cellular milieu. These effects comprise changes in intracellular cyclic nucleotides (cAMP, cGMP) and calcium levels, activation of certain
protein kinase C
subtypes, intracellular localization of steroid hormone receptors and regulation of G protein signaling proteins. There are circadian variations in melatonin receptors and responses. Alterations in melatonin receptor expression as well as changes in endogenous melatonin production have been shown in circadian rhythm sleep disorders, Alzheimer's and Parkinson's diseases, glaucoma, depressive disorder, breast and prostate cancer, hepatoma and melanoma. This paper reviews the evidence concerning melatonin receptors and signal transduction pathways in various organs. It further considers their relevance to circadian physiology and pathogenesis of certain human diseases, with a focus on the brain, the cardiovascular and immune systems, and cancer.
...
PMID:Physiological effects of melatonin: role of melatonin receptors and signal transduction pathways. 2518 59
Melatonin acts both as a hormone of the pineal gland and as a local regulator molecule in various tissues. Quantities of total tissue melatonin exceed those released from the pineal. With regard to this dual role, to the orchestrating, systemic action on various target tissues, melatonin is highly pleiotropic. Numerous secondary effects result from the control of the circadian pacemaker and, in seasonal breeders, of the hypothalamic/pituitary hormonal axes. In mammals, various binding sites for melatonin have been identified, the membrane receptors MT(1) and MT(2), which are of utmost chronobiological importance, ROR and RZR isoforms as nuclear receptors from the retinoic acid receptor superfamily,
quinone reductase 2
, calmodulin, calreticulin, and mitochondrial binding sites. The G protein-coupled receptors (GPCRs) MT(1) and MT(2) are capable of parallel or alternate signaling via different Galpha subforms, in particular, Galpha(i) (2/) (3) and Galpha(q), and via Gbetagamma, as well. Multiple signaling can lead to the activation of different cascades and/or ion channels. Melatonin frequently decreases cAMP, but also activates phospholipase C and
protein kinase C
, acts via the MAP kinase and PI3 kinase/Akt pathways, modulates large conductance Ca(2+)-activated K(+) and voltage-gated Ca(2+) channels. MT(1) and MT(2) can form homo and heterodimers, and MT(1) interacts with other proteins in the plasma membrane, such as an orphan GPCR, GPR50, and the PDZ domain scaffolding protein MUPP1, effects which negatively or positively influence signaling capacity. Cross-talks between different signaling pathways, including influences of the membrane receptors on nuclear binding sites, are discussed. (c) 2009 International Union of Biochemistry and Molecular Biology, Inc.
...
PMID:Melatonin: signaling mechanisms of a pleiotropic agent. 1944 47
Phase II enzymes are induced primarily through the common electrophile response element (EpRE) signaling. Studies performed in different cell types and with different inducer appear to indicate variation in the upstream signaling pathways involved in the induction of these phase II genes. Nonetheless, whether variation in signaling among phase II genes in the same cell with the same inducer is unclear. This study is designed to answer this question using human bronchial epithelial cells (HBE1 cells) as a model and screening with a variety of protein kinase inhibitors with varying degrees of specificity. Two electrophiles, 4-hydroxynonenal (HNE) and acrolein, induced the expression of phase II genes (GCLC, GCLM, NQO1,
NQO2
, HO-1, and GSTM-1). Nrf2 silencing significantly decreased the induction of all of these genes, confirming the involvement of Nrf2-EpRE signaling. ERK and p38MAPK inhibitors had no effect, while a JNK inhibitor abrogated the GCLC and GCLM induction by HNE, but not that by acrolein. Among the
PKC
inhibitors used, one eliminated gene induction by HNE and acrolein, while two others showed no effects. One PI3K inhibitor decreased the induction of GCLM, NQO1,
NQO2
and HO-1, but not GCLC and GST-M1; on the other hand, the inhibitory effects of another PI3K inhibitor on gene induction seems to be gene- and inducer- specific. In conclusion, our data suggest that although phase II genes are coordinately induced through Nrf2-EpRE signaling by electrophiles, the upstream signaling pathways involved are gene- and inducer- specific. It is also suggested that commercial kinase inhibitors may produce non-specific effects on phase II gene expression via mechanisms unrelated to their purported specificity.
...
PMID:Signaling pathways involved in phase II gene induction by alpha, beta-unsaturated aldehydes. 1965 97
