Prostaglandin and leukotriene metabolism in senescence (Homo sapiens)

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279972773792277927232102779992StressROSPTGESdihomo-15d-PGJ2RASPGG2EP2 (extracellular)Cytosolic phospholipase A2GsCOX-1cAMPPGE2PTGDSArachidonic acidGGT1PGH2PGI215d-PGJ2COX-2DPEP2PGD2IGFBP5PLCAdenylate CyclaseMembrane phospholipidsALOX5APCOX-1Adrenic acidSenescenceLTA4HLTC4HGGT5TXA2p38 MAPKLTD4 DPEPCytosolic phospholipase A22COX-2PGD SynthasePGE SynthasePGI SynthaseTxA SynthasePGF SynthasePGF2alphaEP1 (extracellular)EP3 (extracellular)EP4 (extracellular)GiGq777Adenylate CyclasecAMPP4481, 59555, 10410101051, 1056951548101888610ALOX5APCa2+ALOX5LTC4SLTA4HALOX15Bp21LTB45-HPETELTD4p53RB1ALOX15LTA4LTE4LTC4SIRT1ALOX12CysLT1Rp53PRB1PSenescenceCa2+p53SASP?7


Description

Prostaglandins are active lipid molecules that are shown to have a great impact on cellular senescence (Wiley et al., 2021). Prostaglandins are derived from arachidonic acid, which is cleaved by the enzyme cytosolic phospholipase A2 (cPLA2) from the membrane phospholipids (Yang et al., 2011).

The cyclooxygenase 2 (COX-2)-prostaglandin E2 (PGE2) pathway takes part in the induction, as well as the maintenance of senescence. COX-2 is the inducing enzyme which causes the conversion of AA into PGH2 and PGG2, which are then readily converted into PGF2⍺, PGD2, PGE2, PGI2, and TxA2 through prostaglandin synthases (Cormenier et al., 2017; Martien et al., 2013). The produced active prostaglandins can then act on intracellular receptors and trigger a downward signalling cascade, leading to the stimulation or inhibition of cAMP or the stimulation of Ca2+. The cAMP-dependent pathway leads to the stimulation of the insulin-like growth factor binding protein 5 (IGFBP5) production, which then also activates p53. P53 activation reinforces senescence by stimulating the expression of COX mRNA, thus creating a positive feedback loop (Yang et al., 2011).

Two important active prostaglandins, namely dihomo-15d-PGJ2 and 15d-PGJ2 are highly elevated in senescent cells and induce COX-1 and 2, PTGES and PTGDS production through the activation of RAS and subsequently p53, reinforcing the positive feedback loop. Dihomo-15d-PGJ2 is the most highly elevated senescence-associated prostaglandin and is produced by the elongation of arachidonic acid into adrenic acid, which is then enzymatically converted to yield the prostaglandin. 15d-PGJ2 on the other hand is produced through the dehydration of the active prostaglandin PGD2. In addition, RAS stimulates the secretion of SASP factors, which can consequently affect surrounding cells (Wiley et al., 2021).

Leukotrienes play an important role in the pathogenesis of inflammation. Just like prostaglandins, leukotrienes are synthesized from arachidonic acid that was cleaved from the membrane phospholipids (Wiley et al., 2019). ALOX12, ALOX15, ALOX5AP, LTC4S, LTA4H, ALOX15B and ALOX5, which are enzymes that conversion of arachidonic acid to either leukotriene A4 (LT4A) or Arachidonic acid 5-hydroperoxide (5-HPETE), are upregulated in senescence (Wiley et al., 2019; H�ƒÆ’�‚¤fner et al., 2019). The produced LTA4 can be converted into LTB4 or LTC4. LTC4 can then be consecutively cleaved into LTD4 and LTE4 (Suryadevara et al., 2020). All the mentioned leukotrienes are increased in cellular senescence and are thought to be part of the SASP (Lin & Xu, 2020).

LTD4 is of particular importance in cellular senescence due to its increased interaction with the cysteinyl leukotriene receptor 1 (CysLT1R) (Wei et al., 2018; Song et al., 2019). This interaction has various consequences, such as the release of intracellular Ca2+, an increase of p21 and it also inhibits sirtuin 1 (SIRT1). SIRT1 regulates the cell cycle by inhibiting the phosphorylation of p53 and the release of various cytokines (Wei et al., 2018). Therefore, it increases the release of pro-inflammatory cytokines and induce cellular senescence via the activation of p53 (Song et al., 2019).

ALOX5 contributes to an increase in reactive oxygen species (ROS) (Catalano et al., 2005; Menna et al., 2010). These ROS are thought to activate p53 which binds to ALOX5 and further increases its action (H�ƒÆ’�‚¤fner et al., 2019). Moreover, ALOX5 uses Ca2+ as a cofactor and its increased intracellular concentration further promotes ALOX5's action (Menna et al., 2010). LTB4 is also stimulates the production of ROS. ALOX5 then stimulates the phosphorylation of p53 and activates p21 (Menna et al., 2010; Catalano et al., 2005). This then causes the dephosphorylation of the retinoblastoma protein (RB1). As a consequence, senescence is induced (Catalano et al., 2005).

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Bibliography

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  1. Menna C, Olivieri F, Catalano A, Procopio A; ''Lipoxygenase inhibitors for cancer prevention: promises and risks.''; Curr Pharm Des, 2010 PubMed Europe PMC Scholia
  2. Wiley CD, Brumwell AN, Davis SS, Jackson JR, Valdovinos A, Calhoun C, Alimirah F, Castellanos CA, Ruan R, Wei Y, Chapman HA, Ramanathan A, Campisi J, Jourdan Le Saux C; ''Secretion of leukotrienes by senescent lung fibroblasts promotes pulmonary fibrosis.''; JCI Insight, 2019 PubMed Europe PMC Scholia
  3. Catalano A, Rodilossi S, Caprari P, Coppola V, Procopio A; ''5-Lipoxygenase regulates senescence-like growth arrest by promoting ROS-dependent p53 activation.''; EMBO J, 2005 PubMed Europe PMC Scholia
  4. H�ƒÆ’�†â€™�ƒâ€ �¢â‚¬â„¢�ƒÆ’�¢â‚¬Å¡�ƒâ€š�‚¤fner AK, Kahnt AS, Steinhilber D; ''Beyond leukotriene formation-The noncanonical functions of 5-lipoxygenase.''; Prostaglandins Other Lipid Mediat, 2019 PubMed Europe PMC Scholia
  5. Wiley CD, Sharma R, Davis SS, Lopez-Dominguez JA, Mitchell KP, Wiley S, Alimirah F, Kim DE, Payne T, Rosko A, Aimontche E, Deshpande SM, Neri F, Kuehnemann C, Demaria M, Ramanathan A, Campisi J; ''Oxylipin biosynthesis reinforces cellular senescence and allows detection of senolysis.''; Cell Metab, 2021 PubMed Europe PMC Scholia
  6. Cormenier J, Martin N, Desl�ƒÆ’�†â€™�ƒâ€ �¢â‚¬â„¢�ƒÆ’�¢â‚¬Å¡�ƒâ€š�‚© J, Salazar-Cardozo C, Pourtier A, Abbadie C, Pluquet O; ''The ATF6�ƒÆ’�†â€™�ƒâ€¦�‚½�ƒÆ’�¢â‚¬Å¡�ƒâ€š�‚± arm of the Unfolded Protein Response mediates replicative senescence in human fibroblasts through a COX2/prostaglandin E2intracrine pathway.''; Mech Ageing Dev, 2018 PubMed Europe PMC Scholia
  7. Lin Y, Xu Z; ''Fibroblast Senescence in Idiopathic Pulmonary Fibrosis.''; Front Cell Dev Biol, 2020 PubMed Europe PMC Scholia
  8. Wei J, Chen S, Guo W, Feng B, Yang S, Huang C, Chu J; ''Leukotriene D4 induces cellular senescence in osteoblasts.''; Int Immunopharmacol, 2018 PubMed Europe PMC Scholia
  9. Yang HH, Kim C, Jung B, Kim KS, Kim JR; ''Involvement of IGF binding protein 5 in prostaglandin E(2)-induced cellular senescence in human fibroblasts.''; Biogerontology, 2011 PubMed Europe PMC Scholia
  10. Suryadevara V, Ramchandran R, Kamp DW, Natarajan V; ''Lipid Mediators Regulate Pulmonary Fibrosis: Potential Mechanisms and Signaling Pathways.''; Int J Mol Sci, 2020 PubMed Europe PMC Scholia

History

CompareRevisionActionTimeUserComment
134469view00:45, 22 July 2024EweitzStandardize case
125240view16:09, 30 January 2023NadiaJonckheereNew pathway

External references

DataNodes

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NameTypeDatabase referenceComment
15d-PGJ2MetaboliteCHEBI:34159 (ChEBI)
5-HPETEMetaboliteHMDB11135 (HMDB)
ALOX12GeneProductENSG00000108839 (Ensembl)
ALOX15BGeneProductENSG00000179593 (Ensembl)
ALOX15GeneProductENSG00000161905 (Ensembl)
ALOX5APGeneProductENSG00000012779 (Ensembl)
ALOX5APGeneProductENSG00000132965 (Ensembl)
ALOX5GeneProductENSG00000012779 (Ensembl)
Adenylate CyclaseProteinA0A0A0MSC1 (Uniprot-TrEMBL)
Adrenic acidMetaboliteCHEBI:53487 (ChEBI)
Arachidonic acidMetaboliteHMDB01043 (HMDB)
COX-1GeneProductENSG00000095303 (Ensembl)
COX-2GeneProductENSG00000073756 (Ensembl)
Ca2+MetaboliteCHEBI:29108 (ChEBI)
CysLT1RProteinQ9Y271 (Uniprot-TrEMBL)
Cytosolic phospholipase A2ProteinP47712 (Uniprot-TrEMBL)
DPEP2GeneProductENSG00000167261 (Ensembl)
EP1 (extracellular)GeneProductENSG00000160951 (Ensembl)
EP2 (extracellular)GeneProductENSG00000125384 (Ensembl)
EP3 (extracellular)GeneProductENSG00000050628 (Ensembl)
EP4 (extracellular)GeneProductENSG00000171522 (Ensembl)
GGT1GeneProductENSG00000100031 (Ensembl)
GGT5GeneProductENSG00000099998 (Ensembl)
GiGeneProductENSG00000127955 (Ensembl)
GqGeneProductENSG00000156052 (Ensembl)
GsGeneProductENSG00000087460 (Ensembl)
IGFBP5GeneProductENSG00000115461 (Ensembl)
LTA4MetaboliteCHEBI:15651 (ChEBI)
LTA4HGeneProductENSG00000111144 (Ensembl)
LTB4MetaboliteCHEBI:15647 (ChEBI)
LTC4MetaboliteCHEBI:16978 (ChEBI)
LTC4HGeneProductENSG00000213316 (Ensembl)
LTC4SGeneProductENSG00000213316 (Ensembl)
LTD4 DPEPGeneProductENSG00000167261 (Ensembl)
LTD4MetaboliteCHEBI:28666 (ChEBI)
LTE4MetaboliteCHEBI:15650 (ChEBI)
Membrane phospholipidsMetaboliteCHEBI:16247 (ChEBI)
PGD SynthaseGeneProductENSG00000107317 (Ensembl)
PGD2MetaboliteCHEBI:15555 (ChEBI)
PGE SynthaseGeneProductPTGES (HGNC)
PGE2MetaboliteCHEBI:15551 (ChEBI)
PGF SynthaseGeneProductQ8TBF2 (Uniprot-TrEMBL)
PGF2alphaMetaboliteCHEBI:15553 (ChEBI)
PGG2MetaboliteCHEBI:27647 (ChEBI)
PGH2MetaboliteCHEBI:15554 (ChEBI)
PGI SynthaseGeneProductENSG00000124212 (Ensembl)
PGI2MetaboliteCHEBI:15552 (ChEBI)
PLCProteinA0A087WT80 (Uniprot-TrEMBL)
PTGDSGeneProductENSG00000107317 (Ensembl)
PTGESGeneProductENSG00000148344 (Ensembl)
RASProteinP01112 (Uniprot-TrEMBL)
RB1GeneProductENSG00000139687 (Ensembl)
ROSMetabolite26523 (ChEBI)
SASPPathwayWP3391 (WikiPathways)
SIRT1GeneProductENSG00000096717 (Ensembl)
SenescencePathwayWP615 (WikiPathways)
TXA2MetaboliteCHEBI:15627 (ChEBI)
TxA SynthaseGeneProductENSG00000059377 (Ensembl)
cAMPMetaboliteHMDB00058 (HMDB)
dihomo-15d-PGJ2Metabolite16061095 (PubChem-compound)
p21ProteinA0A024RCX5 (Uniprot-TrEMBL)
p38 MAPKGeneProductENSG00000185386 (Ensembl)
p53MetaboliteCHEBI:77731 (ChEBI)

Annotated Interactions

No annotated interactions

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