Nuclear receptors in lipid metabolism and toxicity (Canis familiaris)

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DIETXenobioticsDIETGene expressionRight click for commentsRetinoic acidCYP2C9LOC485935LOC481133CYP3A4RARAPPARGPPARDRARGLanosterolBile AcidsLOC486962LOC486804CholesterolABCG57-DehydroCholesterolLOC608452NR1H3ABCA1VDRRHOXF2SteroidsCYPIIB11CYP2E1CYP4A11CYP1A2PPARALOC486962CYP3A4ABCG1LOC485619Acetyl CoAIsoprenoidsCYPIIB11CYP2C9RARBOxysterolABCB4ABCB11NR1I2ABCA1CYP2C9ABCB1abcg6ABCD3CYP3A4LOC486962ABCD2Fatty AcidsABCC21,25-Dihydroxy-Vitamins D3NR1I3NR1H4ABCA1ABCC3


Description

Nuclear receptors are transcription factors that are activated upon binding to its ligands. Initially, they had been classified as classic endocrine nuclear hormone receptors and orphan receptors. However, further studies have led to the identification of lipid ligands for some of these ‘adopted’ orphan receptors, which are responsible for lipid metabolism, storage or elimination. One of the characteristics of these receptors is that they act by forming heterodimers with retinoid X receptor (RXR). The receptors include peroxisome proliferators-Activated receptors (PPARs) for fatty acids, liver X receptor (LCR) for oxysterols, Farnesoid X receptors (FXR) for bile acids and steroid xenobiotic receptor/X receptor (SXR/PXR or Nsil2) for xenobiotics. Other orphan receptors also require RXR for its functions are vitamin D receptor (VDR) for vitamin D and retinoic acid receptor (RAR) for retinoid acids, although these receptors are not involved in lipid metabolism. Upon binding to various ligands, three classes of proteins are synthesized including lipid binding proteins, the ATP-binding cassette (ABC) transporters and cytochrome P450 member proteins which catalyzes lipid anabolism, metabolism and elimination. In addition to lipid metabolism, some members of the cytochrome P450 family genes are responsible for activation of procarcinogens, detoxification of environmental toxins and metabolism of drugs and xenobiotics. In particular, CAR, Nsil2 and recently identified VDR are important in up-regulation of these cytochromes. Of all the human cytochrome P450 genes, only a few CYP1A2, CYP2C9, CYP2C19, CYP2D6, CYP2E1 and CYP3A4 account for most toxicity effects, specifically CYP3A is responsible for clearing approximately half of the clinically prescribed drugs. For instance, acetaminophen, one of the most commonly used drug, is toxic in high doses due to the activation of CAR and the drug’s subsequentconversion to acetyl-p-benzoquinone imine (NAPQI) by CYP1A2, CYP2E1 and CYP3A.

Comments

GenMAPP notes 
Nuclear receptors are transcription factors that are activated upon binding to its ligands. Initially, they had been classified as classic endocrine nuclear hormone receptors and orphan receptors. However, further studies have led to the identification of lipid ligands for some of these ‘adopted’ orphan receptors, which are responsible for lipid metabolism, storage or elimination. One of the characteristics of these receptors is that they act by forming heterodimers with retinoid X receptor (RXR). The receptors include peroxisome proliferators-Activated receptors (PPARs) for fatty acids, liver X receptor (LCR) for oxysterols, Farnesoid X receptors (FXR) for bile acids and steroid xenobiotic receptor/X receptor (SXR/PXR or Nsil2) for xenobiotics. Other orphan receptors also require RXR for its functions are vitamin D receptor (VDR) for vitamin D and retinoic acid receptor (RAR) for retinoid acids, although these receptors are not involved in lipid metabolism. Upon binding to various ligands, three classes of proteins are synthesized including lipid binding proteins, the ATP-binding cassette (ABC) transporters and cytochrome P450 member proteins which catalyzes lipid anabolism, metabolism and elimination.


In addition to lipid metabolism, some members of the cytochrome P450 family genes are responsible for activation of procarcinogens, detoxification of environmental toxins and metabolism of drugs and xenobiotics. In particular, CAR, Nsil2 and recently identified VDR are important in up-regulation of these cytochromes. Of all the human cytochrome P450 genes, only a few CYP1A2, CYP2C9, CYP2C19, CYP2D6, CYP2E1 and CYP3A4 account for most toxicity effects, specifically CYP3A is responsible for clearing approximately half of the clinically prescribed drugs. For instance, acetaminophen, one of the most commonly used drug, is toxic in high doses due to the activation of CAR and the drug’s subsequentconversion to acetyl-p-benzoquinone imine (NAPQI) by CYP1A2, CYP2E1 and CYP3A.

GenMAPP remarks 
Converted to human by GenMAPP.org
HomologyConvert 
This pathway was inferred from Homo sapiens pathway WP299(r21309) with a 74% conversion rate.

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History

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CompareRevisionActionTimeUserComment
107084view14:17, 17 September 2019MaintBotChEBI identifier normalization
106033view11:55, 16 August 2019MaintBotHMDB identifier normalization
96375view16:48, 10 March 2018EgonwReplaced a secondary ChEBI identifier with a primary identifier.
78444view10:27, 7 January 2015MaintBotadded missing graphIds
71472view19:17, 17 October 2013MaintBotAutomated update of data sources
67536view11:22, 26 June 2013DdiglesOntology Term : 'lipid metabolic pathway' added !
62304view11:09, 27 April 2013EgonwAdded a ChEBI identifier for 'steroid'.
62301view11:07, 27 April 2013EgonwConverted 'xenobiotics' to a DataNode and added the ChEBI id.
48156view18:51, 9 May 2012MaintBotUpdating from human to fix xrefs
40713view21:52, 1 March 2011MaintBotRemoved redundant pathway information and comments
35682view22:52, 12 February 2010KhanspersDescription
35681view22:52, 12 February 2010KhanspersModified description
33992view18:35, 9 December 2009MaintBotAutomatic update of empty xrefs
31726view11:56, 14 August 2009MaintBotFixed group labels
30668view22:39, 29 July 2009MaintBotNew pathway

External references

DataNodes

View all...
NameTypeDatabase referenceComment
1,25-Dihydroxy-Vitamins D3Metabolite
7-DehydroCholesterolMetabolite
ABCA1GeneProduct481651 (Entrez Gene)
ABCB11GeneProduct488390 (Entrez Gene)
ABCB1GeneProduct403879 (Entrez Gene)
ABCB4GeneProduct
ABCC2GeneProduct403632 (Entrez Gene)
ABCC3GeneProduct491084 (Entrez Gene)
ABCD2GeneProduct477643 (Entrez Gene)
ABCD3GeneProduct479939 (Entrez Gene)
ABCG1GeneProduct487777 (Entrez Gene)
ABCG5GeneProduct481354 (Entrez Gene)
Acetyl CoAMetabolite
Bile AcidsMetabolite3098 (ChEBI)
CYP1A2GeneProduct494010 (Entrez Gene)
CYP2C9GeneProduct
CYP2E1GeneProduct415128 (Entrez Gene)
CYP3A4GeneProduct
CYP4A11GeneProduct610385 (Entrez Gene)
CYPIIB11GeneProduct474177 (Entrez Gene)
CholesterolMetabolite
Fatty AcidsMetabolite35366 (ChEBI)
IsoprenoidsMetabolite24913 (ChEBI)
LOC481133GeneProduct481133 (Entrez Gene)
LOC485619GeneProduct485619 (Entrez Gene)
LOC485935GeneProduct485935 (Entrez Gene)
LOC486804GeneProduct486804 (Entrez Gene)
LOC486962GeneProduct486962 (Entrez Gene)
LOC608452GeneProduct608452 (Entrez Gene)
LanosterolMetabolite6374 (ChEBI)
NR1H3GeneProduct483625 (Entrez Gene)
NR1H4GeneProduct612928 (Entrez Gene) Farnesoid X-activated receptor
NR1I2GeneProduct403482 (Entrez Gene)
NR1I3GeneProduct488653 (Entrez Gene)
OxysterolMetabolite
PPARAGeneProduct403654 (Entrez Gene)
PPARDGeneProduct481756 (Entrez Gene)
PPARGGeneProduct403606 (Entrez Gene)
RARAGeneProduct480526 (Entrez Gene)
RARBGeneProduct477045 (Entrez Gene)
RARGGeneProduct486508 (Entrez Gene)
RHOXF2GeneProduct611154 (Entrez Gene)
Retinoic acidMetaboliteHMDB01852 (HMDB)
SteroidsMetabolite
VDRGeneProduct486588 (Entrez Gene)
abcg6GeneProduct

Annotated Interactions

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