Arachidonic acid drives adaptive responses to chemotherapy-induced stress in malignant mesothelioma.
ALDH
Arachidonic acid
Chemoresistance
MPM
Malignant pleural mesothelioma
NFkB
Spheroids
cPLA2
Journal
Journal of experimental & clinical cancer research : CR
ISSN: 1756-9966
Titre abrégé: J Exp Clin Cancer Res
Pays: England
ID NLM: 8308647
Informations de publication
Date de publication:
02 Nov 2021
02 Nov 2021
Historique:
received:
31
07
2021
accepted:
24
09
2021
entrez:
3
11
2021
pubmed:
4
11
2021
medline:
16
2
2022
Statut:
epublish
Résumé
Background High resistance to therapy and poor prognosis characterizes malignant pleural mesothelioma (MPM). In fact, the current lines of treatment, based on platinum and pemetrexed, have limited impact on the survival of MPM patients. Adaptive response to therapy-induced stress involves complex rearrangements of the MPM secretome, mediated by the acquisition of a senescence-associated-secretory-phenotype (SASP). This fuels the emergence of chemoresistant cell subpopulations, with specific gene expression traits and protumorigenic features. The SASP-driven rearrangement of MPM secretome takes days to weeks to occur. Thus, we have searched for early mediators of such adaptive process and focused on metabolites differentially released in mesothelioma vs mesothelial cell culture media, after treatment with pemetrexed. Mass spectrometry-based (LC/MS and GC/MS) identification of extracellular metabolites and unbiased statistical analysis were performed on the spent media of mesothelial and mesothelioma cell lines, at steady state and after a pulse with pharmacologically relevant doses of the drug. ELISA based evaluation of arachidonic acid (AA) levels and enzyme inhibition assays were used to explore the role of cPLA2 in AA release and that of LOX/COX-mediated processing of AA. QRT-PCR, flow cytometry analysis of ALDH expressing cells and 3D spheroid growth assays were employed to assess the role of AA at mediating chemoresistance features of MPM. ELISA based detection of p65 and IkBalpha were used to interrogate the NFkB pathway activation in AA-treated cells. We first validated what is known or expected from the mechanism of action of the antifolate. Further, we found increased levels of PUFAs and, more specifically, arachidonic acid (AA), in the transformed cell lines treated with pemetrexed. We showed that pharmacologically relevant doses of AA tightly recapitulated the rearrangement of cell subpopulations and the gene expression changes happening in pemetrexed -treated cultures and related to chemoresistance. Further, we showed that release of AA following pemetrexed treatment was due to cPLA2 and that AA signaling impinged on NFkB activation and largely affected anchorage-independent, 3D growth and the resistance of the MPM 3D cultures to the drug. AA is an early mediator of the adaptive response to pem in chemoresistant MPM and, possibly, other malignancies.
Identifiants
pubmed: 34727953
doi: 10.1186/s13046-021-02118-y
pii: 10.1186/s13046-021-02118-y
pmc: PMC8561918
doi:
Substances chimiques
Antineoplastic Agents
0
Arachidonic Acid
27YG812J1I
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Pagination
344Informations de copyright
© 2021. The Author(s).
Références
Pathol Oncol Res. 2015 Sep;21(4):1133-40
pubmed: 25971681
Cancer Cell. 2011 Sep 13;20(3):370-83
pubmed: 21907927
Trends Pharmacol Sci. 2019 Oct;40(10):774-789
pubmed: 31515079
J Exp Clin Cancer Res. 2018 Dec 17;37(1):318
pubmed: 30558661
Pathol Res Pract. 2019 Jun;215(6):152398
pubmed: 31003849
Oncogene. 2018 May;37(18):2367-2378
pubmed: 29445137
Mol Oncol. 2019 Feb;13(2):185-201
pubmed: 30353652
Oncogene. 2012 Jun 28;31(26):3148-63
pubmed: 22020330
World J Stem Cells. 2019 Sep 26;11(9):693-704
pubmed: 31616544
Adv Drug Deliv Rev. 2020;159:245-293
pubmed: 32711004
Nat Rev Immunol. 2008 Nov;8(11):837-48
pubmed: 18927578
Cell. 2020 Jun 25;181(7):1596-1611.e27
pubmed: 32559461
Mol Cell Biol. 2000 Feb;20(4):1436-47
pubmed: 10648628
Stem Cell Reports. 2020 Aug 11;15(2):374-388
pubmed: 32649903
Oncotarget. 2015 Jul 20;6(20):18134-50
pubmed: 26136339
Mol Oncol. 2019 Jun;13(6):1419-1432
pubmed: 31033201
BMC Cancer. 2020 Sep 17;20(1):891
pubmed: 32942996
Biochemistry. 1993 Jun 15;32(23):5935-40
pubmed: 8018213
Nutr Cancer. 2018 Aug-Sep;70(6):840-850
pubmed: 30273003
Cancer Res. 2010 Dec 15;70(24):10299-309
pubmed: 21159649
Oncotarget. 2017 Dec 22;9(70):33403-33415
pubmed: 30279970
Anticancer Res. 2019 Jul;39(7):3809-3814
pubmed: 31262908
BMC Mol Biol. 2002 Dec 4;3:16
pubmed: 12466023
Biology (Basel). 2020 Dec 21;9(12):
pubmed: 33371508
Cells. 2021 Jan 06;10(1):
pubmed: 33419140
Semin Cancer Biol. 2011 Dec;21(6):354-9
pubmed: 21925603
J Thorac Cardiovasc Surg. 2010 Aug;140(2):352-5
pubmed: 20653100
J Cardiovasc Pharmacol. 2008 Jan;51(1):71-7
pubmed: 18209571
Oncogene. 2011 Jun 16;30(24):2707-17
pubmed: 21278794
Curr Opin Cell Biol. 1993 Apr;5(2):274-80
pubmed: 7685181
Cell Death Dis. 2012 Dec 20;3:e446
pubmed: 23254289
Br J Clin Pharmacol. 1980 Nov;10(5):453-7
pubmed: 7437257
J Clin Oncol. 2003 Jul 15;21(14):2636-44
pubmed: 12860938
Front Pharmacol. 2021 Jan 28;11:599965
pubmed: 33584277
Cell Cycle. 2012 Jan 1;11(1):132-40
pubmed: 22185775
Br J Pharmacol. 2012 Dec;167(8):1691-701
pubmed: 22831644
Adv Exp Med Biol. 2016;890:57-74
pubmed: 26703799
J Dev Biol. 2019 Apr 08;7(2):
pubmed: 30965570
Adv Neurobiol. 2016;12:367-80
pubmed: 27651264
Oncogene. 2004 Sep 23;23(44):7345-54
pubmed: 15286702
BMC Cancer. 2014 Apr 30;14:304
pubmed: 24884875
Theranostics. 2021 Jan 1;11(3):1377-1395
pubmed: 33391540
PLoS One. 2015 May 01;10(5):e0119549
pubmed: 25932953
J Adv Res. 2018 Mar 13;11:23-32
pubmed: 30034873
Mol Cell Biol. 2020 Jan 3;40(2):
pubmed: 31658996
Lancet Oncol. 2019 Feb;20(2):239-253
pubmed: 30660609
Nucleic Acids Res. 2015 Jul 1;43(W1):W566-70
pubmed: 25969447
Radiat Oncol. 2020 Aug 14;15(1):197
pubmed: 32799884
Mol Cell Biol. 1993 Oct;13(10):6231-40
pubmed: 8413223
Lancet Respir Med. 2019 Mar;7(3):260-270
pubmed: 30660511
Photochem Photobiol. 2019 Jan;95(1):462-463
pubmed: 30485439
Clin Cancer Res. 2002 Jun;8(6):1857-62
pubmed: 12060628
Cancers (Basel). 2021 Jun 10;13(12):
pubmed: 34200553
Theranostics. 2020 Jul 9;10(19):8721-8743
pubmed: 32754274
Carcinogenesis. 2005 Sep;26(9):1520-6
pubmed: 15878913
Br J Cancer. 2007 Oct 22;97(8):1071-6
pubmed: 17912246
Int Immunopharmacol. 2007 Nov;7(11):1488-95
pubmed: 17761353
Cell Death Differ. 2009 Aug;16(8):1146-55
pubmed: 19343038
J Mol Med (Berl). 2019 Feb;97(2):231-242
pubmed: 30539198
Agents Actions. 1991 Sep;34(1-2):117-20
pubmed: 1665285
J Eur Acad Dermatol Venereol. 2017 Jul;31(7):1161-1167
pubmed: 28107559
Cell Stem Cell. 2017 Mar 2;20(3):303-314.e5
pubmed: 28041894
Ann Transl Med. 2016 Dec;4(24):518
pubmed: 28149880
Cancer Manag Res. 2020 Dec 31;12:13553-13566
pubmed: 33408525
Oncotarget. 2015 May 20;6(14):12637-53
pubmed: 25868979
Cancer Lett. 2021 Jan 28;497:165-177
pubmed: 33080311
Genomics. 1996 Sep 1;36(2):296-304
pubmed: 8812456
J Urol. 2008 May;179(5):1668-75
pubmed: 18343442
J Lipid Mediat Cell Signal. 1995 Oct;12(2-3):83-117
pubmed: 8777586
J Immunother Cancer. 2020 Nov;8(2):
pubmed: 33243934
J Clin Invest. 2001 Jun;107(11):1339-45
pubmed: 11390413
Mol Biol Rep. 2020 Feb;47(2):1435-1443
pubmed: 31838656
Int J Cancer. 2011 Oct 15;129(8):2042-9
pubmed: 21165952
PLoS One. 2012;7(12):e52188
pubmed: 23272224
J Immunol. 2007 Jun 1;178(11):7097-109
pubmed: 17513759
Biomed Pharmacother. 2020 Sep;129:110354
pubmed: 32540644
Oncogene. 2018 Mar;37(10):1369-1385
pubmed: 29311642
Expert Rev Anticancer Ther. 2003 Apr;3(2):145-56
pubmed: 12722874
BMC Cancer. 2018 Aug 24;18(1):848
pubmed: 30143021
Sci Rep. 2019 Sep 16;9(1):13316
pubmed: 31527632
J Nutr. 2012 Jul;142(7):1266-71
pubmed: 22623387
J Immunol. 1998 Oct 1;161(7):3421-30
pubmed: 9759860
Lung Cancer. 2009 May;64(2):207-10
pubmed: 18926592