SF3B1 inhibition disrupts malignancy and prolongs survival in glioblastoma patients through BCL2L1 splicing and mTOR/ß-catenin pathways imbalances.
Animals
Apoptosis
Cell Line, Tumor
Cell Proliferation
Disease Models, Animal
Glioblastoma
/ genetics
Humans
Mice
Phosphoproteins
/ metabolism
RNA Splicing Factors
/ metabolism
Survival Analysis
TOR Serine-Threonine Kinases
/ metabolism
Transfection
Xenograft Model Antitumor Assays
bcl-X Protein
/ metabolism
beta Catenin
/ metabolism
Antitumor therapy
BCL2L1 splicing variants
Glioblastoma
Glioma mouse models
Splicing factor SF3B1
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:
27 Jan 2022
27 Jan 2022
Historique:
received:
19
08
2021
accepted:
03
01
2022
entrez:
28
1
2022
pubmed:
29
1
2022
medline:
24
3
2022
Statut:
epublish
Résumé
Glioblastoma is one of the most devastating cancer worldwide based on its locally aggressive behavior and because it cannot be cured by current therapies. Defects in alternative splicing process are frequent in cancer. Recently, we demonstrated that dysregulation of the spliceosome is directly associated with glioma development, progression, and aggressiveness. Different human cohorts and a dataset from different glioma mouse models were analyzed to determine the mutation frequency as well as the gene and protein expression levels between tumor and control samples of the splicing-factor-3B-subunit-1 (SF3B1), an essential and druggable spliceosome component. SF3B1 expression was also explored at the single-cell level across all cell subpopulations and transcriptomic programs. The association of SF3B1 expression with relevant clinical data (e.g., overall survival) in different human cohorts was also analyzed. Different functional (proliferation/migration/tumorspheres and colonies formation/VEGF secretion/apoptosis) and mechanistic (gene expression/signaling pathways) assays were performed in three different glioblastomas cell models (human primary cultures and cell lines) in response to SF3B1 blockade (using pladienolide B treatment). Moreover, tumor progression and formation were monitored in response to SF3B1 blockade in two preclinical xenograft glioblastoma mouse models. Our data provide novel evidence demonstrating that the splicing-factor-3B-subunit-1 (SF3B1, an essential and druggable spliceosome component) is low-frequency mutated in human gliomas (~ 1 %) but widely overexpressed in glioblastoma compared with control samples from the different human cohorts and mouse models included in the present study, wherein SF3B1 levels are associated with key molecular and clinical features (e.g., overall survival, poor prognosis and/or drug resistance). Remarkably, in vitro and in vivo blockade of SF3B1 activity with pladienolide B drastically altered multiple glioblastoma pathophysiological processes (i.e., reduction in proliferation, migration, tumorspheres formation, VEGF secretion, tumor initiation and increased apoptosis) likely by suppressing AKT/mTOR/ß-catenin pathways, and an imbalance of BCL2L1 splicing. Together, we highlight SF3B1 as a potential diagnostic and prognostic biomarker and an efficient pharmacological target in glioblastoma, offering a clinically relevant opportunity worth to be explored in humans.
Sections du résumé
BACKGROUND
BACKGROUND
Glioblastoma is one of the most devastating cancer worldwide based on its locally aggressive behavior and because it cannot be cured by current therapies. Defects in alternative splicing process are frequent in cancer. Recently, we demonstrated that dysregulation of the spliceosome is directly associated with glioma development, progression, and aggressiveness.
METHODS
METHODS
Different human cohorts and a dataset from different glioma mouse models were analyzed to determine the mutation frequency as well as the gene and protein expression levels between tumor and control samples of the splicing-factor-3B-subunit-1 (SF3B1), an essential and druggable spliceosome component. SF3B1 expression was also explored at the single-cell level across all cell subpopulations and transcriptomic programs. The association of SF3B1 expression with relevant clinical data (e.g., overall survival) in different human cohorts was also analyzed. Different functional (proliferation/migration/tumorspheres and colonies formation/VEGF secretion/apoptosis) and mechanistic (gene expression/signaling pathways) assays were performed in three different glioblastomas cell models (human primary cultures and cell lines) in response to SF3B1 blockade (using pladienolide B treatment). Moreover, tumor progression and formation were monitored in response to SF3B1 blockade in two preclinical xenograft glioblastoma mouse models.
RESULTS
RESULTS
Our data provide novel evidence demonstrating that the splicing-factor-3B-subunit-1 (SF3B1, an essential and druggable spliceosome component) is low-frequency mutated in human gliomas (~ 1 %) but widely overexpressed in glioblastoma compared with control samples from the different human cohorts and mouse models included in the present study, wherein SF3B1 levels are associated with key molecular and clinical features (e.g., overall survival, poor prognosis and/or drug resistance). Remarkably, in vitro and in vivo blockade of SF3B1 activity with pladienolide B drastically altered multiple glioblastoma pathophysiological processes (i.e., reduction in proliferation, migration, tumorspheres formation, VEGF secretion, tumor initiation and increased apoptosis) likely by suppressing AKT/mTOR/ß-catenin pathways, and an imbalance of BCL2L1 splicing.
CONCLUSIONS
CONCLUSIONS
Together, we highlight SF3B1 as a potential diagnostic and prognostic biomarker and an efficient pharmacological target in glioblastoma, offering a clinically relevant opportunity worth to be explored in humans.
Identifiants
pubmed: 35086552
doi: 10.1186/s13046-022-02241-4
pii: 10.1186/s13046-022-02241-4
pmc: PMC8793262
doi:
Substances chimiques
Bcl2l1 protein, mouse
0
Phosphoproteins
0
RNA Splicing Factors
0
Sf3b1 protein, mouse
0
bcl-X Protein
0
beta Catenin
0
mTOR protein, mouse
EC 2.7.1.1
TOR Serine-Threonine Kinases
EC 2.7.11.1
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Pagination
39Subventions
Organisme : NIH HHS
ID : R03NS101529
Pays : United States
Organisme : Ministerio de Ciencia, Innovación y Universidades
ID : FPU18-06009
Organisme : American Cancer Society
ID : RSG-16-217-01-TBG
Organisme : Ministerio de Ciencia, Innovación y Universidades
ID : PID2019-105564RB-I00
Organisme : Ministerio de Ciencia, Innovación y Universidades
ID : PID2019-105201RB-I00
Organisme : NINDS NIH HHS
ID : R03 NS101529
Pays : United States
Organisme : NIH HHS
ID : R33CA236687
Pays : United States
Organisme : Ministerio de Ciencia, Innovación y Universidades
ID : FPU16-05059
Organisme : Junta de Andalucía
ID : BIO-0139
Informations de copyright
© 2022. The Author(s).
Références
Prog Neurobiol. 2011 Mar;93(3):421-43
pubmed: 21219963
FASEB J. 2017 Nov;31(11):4682-4696
pubmed: 28705809
Cancer Cell. 2016 Sep 12;30(3):404-417
pubmed: 27622333
J Antibiot (Tokyo). 2004 Mar;57(3):188-96
pubmed: 15152804
Clin Cancer Res. 2019 Sep 15;25(18):5537-5547
pubmed: 31263031
Cancers (Basel). 2019 Mar 06;11(3):
pubmed: 30845654
Neuro Oncol. 2020 Oct 30;22(12 Suppl 2):iv1-iv96
pubmed: 33123732
Genome Biol. 2021 Jan 26;22(1):48
pubmed: 33499924
Cell. 2016 Jan 28;164(3):550-63
pubmed: 26824661
Nat Commun. 2017 Oct 24;8(1):1123
pubmed: 29066722
Cell Death Differ. 1999 Dec;6(12):1169-73
pubmed: 10637432
Cell. 2011 Mar 4;144(5):646-74
pubmed: 21376230
N Engl J Med. 2011 Dec 29;365(26):2497-506
pubmed: 22150006
Cell. 1993 Aug 27;74(4):597-608
pubmed: 8358789
CA Cancer J Clin. 2020 Jul;70(4):299-312
pubmed: 32478924
Bioconjug Chem. 2008 May;19(5):1009-16
pubmed: 18393455
Cancer Cell. 2010 Jan 19;17(1):98-110
pubmed: 20129251
J Clin Endocrinol Metab. 2019 Aug 1;104(8):3389-3402
pubmed: 30901032
J Clin Invest. 2019 Feb 1;129(2):676-693
pubmed: 30481162
Neuro Oncol. 2015 Feb;17(2):189-99
pubmed: 25165193
J Clin Invest. 2021 Jan 4;131(1):
pubmed: 33031100
Neuron. 2019 Nov 6;104(3):442-449
pubmed: 31697921
Nat Rev Clin Oncol. 2020 Aug;17(8):457-474
pubmed: 32303702
Leukemia. 2020 Oct;34(10):2621-2634
pubmed: 32358566
Nat Med. 2016 Sep 7;22(9):976-86
pubmed: 27603132
Cancer Lett. 2015 Apr 10;359(2):299-306
pubmed: 25637790
Blood. 2016 Jul 28;128(4):574-83
pubmed: 27235137
Cancer Cell. 2018 Aug 13;34(2):211-224.e6
pubmed: 30078747
Nucleic Acids Res. 2014 Oct 29;42(19):12070-81
pubmed: 25294838
J Environ Public Health. 2018 Jun 24;2018:7910754
pubmed: 30034480
Genomics Proteomics Bioinformatics. 2021 Feb;19(1):1-12
pubmed: 33662628
Lancet Oncol. 2009 May;10(5):459-66
pubmed: 19269895
Cancer Lett. 2021 Jan 1;496:72-83
pubmed: 33038489
EMBO Mol Med. 2013 May;5(5):737-50
pubmed: 23592547
Cell Rep. 2015 Jul 14;12(2):258-71
pubmed: 26146073
Methods Mol Biol. 2013;946:1-13
pubmed: 23179822
Mol Cell. 2015 Oct 1;60(1):105-17
pubmed: 26431027
Transl Res. 2019 Oct;212:89-103
pubmed: 31344348
World Neurosurg. 2018 Aug;116:505-517
pubmed: 30049045
Mol Cancer Res. 2014 Sep;12(9):1195-204
pubmed: 24807918
Nat Commun. 2020 May 19;11(1):2506
pubmed: 32427851
Acta Neuropathol. 2018 Jul;136(1):153-166
pubmed: 29687258
Neuro Oncol. 2017 Jan;19(1):139-141
pubmed: 28031383
Neuro Oncol. 2019 Nov 1;21(Suppl 5):v1-v100
pubmed: 31675094
Oncogene. 2014 Nov 13;33(46):5311-8
pubmed: 24336324
J Proteome Res. 2015 Jun 5;14(6):2707-13
pubmed: 25873244
Biochim Biophys Acta Rev Cancer. 2017 Aug;1868(1):333-340
pubmed: 28554667
Crit Rev Biochem Mol Biol. 2019 Oct;54(5):443-465
pubmed: 31744343
Cell. 2019 Aug 8;178(4):835-849.e21
pubmed: 31327527
Cancer Cell. 2014 Sep 8;26(3):374-389
pubmed: 25203323
Trends Genet. 2017 May;33(5):336-348
pubmed: 28372848
Nat Commun. 2020 Mar 18;11(1):1438
pubmed: 32188845
Cancers (Basel). 2019 Sep 26;11(10):
pubmed: 31561558
J Clin Endocrinol Metab. 2009 Jul;94(7):2634-43
pubmed: 19401364
Nucleic Acids Res. 2015 Apr 30;43(8):4202-18
pubmed: 25845590
Methods Mol Biol. 2015;1332:3-23
pubmed: 26285742
Cell Stem Cell. 2016 Nov 3;19(5):599-612
pubmed: 27570067
Blood. 2016 Apr 28;127(17):2122-30
pubmed: 26837699
J Clin Oncol. 2005 Apr 1;23(10):2411-22
pubmed: 15800333
Cell. 2019 Jun 13;177(7):1888-1902.e21
pubmed: 31178118
Nature. 2012 Nov 15;491(7424):399-405
pubmed: 23103869
Cancer Discov. 2014 Aug;4(8):956-71
pubmed: 24893890
Nature. 2012 Jun 10;486(7403):353-60
pubmed: 22722193
EBioMedicine. 2020 Jan;51:102547
pubmed: 31902674
Brain. 2020 Dec 5;143(11):3273-3293
pubmed: 33141183
Acta Neuropathol. 2016 Jun;131(6):803-20
pubmed: 27157931
Nat Methods. 2012 Jul;9(7):671-5
pubmed: 22930834
Cancer Cell. 2018 Aug 13;34(2):225-241.e8
pubmed: 30107174
Nat Commun. 2020 May 15;11(1):2408
pubmed: 32415113
Methods Mol Biol. 2018;1828:79-90
pubmed: 30171536
Cell Death Dis. 2019 Feb 21;10(3):177
pubmed: 30792387
Cancer Discov. 2020 Jun;10(6):806-821
pubmed: 32188705
Clin Cancer Res. 2013 Nov 15;19(22):6064-6
pubmed: 24097858
Methods Mol Biol. 2018;1828:91-124
pubmed: 30171537