Treatment with recombinant Sirt1 rewires the cardiac lipidome and rescues diabetes-related metabolic cardiomyopathy.
Animals
Humans
Mice
Diabetes Mellitus
/ metabolism
Diabetic Cardiomyopathies
/ genetics
Heart Failure
/ metabolism
Inflammation
/ metabolism
Lipidomics
Lipids
Myocytes, Cardiac
/ metabolism
PPAR gamma
/ metabolism
Sirtuin 1
/ genetics
Stroke Volume
Triglycerides
/ metabolism
Ventricular Function, Left
Cardiometabolic
Diabetes
Lipidome
Metabolic cardiomyopathy
Sirt1
Therapy
Journal
Cardiovascular diabetology
ISSN: 1475-2840
Titre abrégé: Cardiovasc Diabetol
Pays: England
ID NLM: 101147637
Informations de publication
Date de publication:
13 11 2023
13 11 2023
Historique:
received:
19
09
2023
accepted:
07
11
2023
medline:
15
11
2023
pubmed:
14
11
2023
entrez:
14
11
2023
Statut:
epublish
Résumé
Metabolic cardiomyopathy (MCM), characterized by intramyocardial lipid accumulation, drives the progression to heart failure with preserved ejection fraction (HFpEF). Although evidence suggests that the mammalian silent information regulator 1 (Sirt1) orchestrates myocardial lipid metabolism, it is unknown whether its exogenous administration could avoid MCM onset. We investigated whether chronic treatment with recombinant Sirt1 (rSirt1) could halt MCM progression. db/db mice, an established model of MCM, were supplemented with intraperitoneal rSirt1 or vehicle for 4 weeks and compared with their db/ + heterozygous littermates. At the end of treatment, cardiac function was assessed by cardiac ultrasound and left ventricular samples were collected and processed for molecular analysis. Transcriptional changes were evaluated using a custom PCR array. Lipidomic analysis was performed by mass spectrometry. H9c2 cardiomyocytes exposed to hyperglycaemia and treated with rSirt1 were used as in vitro model of MCM to investigate the ability of rSirt1 to directly target cardiomyocytes and modulate malondialdehyde levels and caspase 3 activity. Myocardial samples from diabetic and nondiabetic patients were analysed to explore Sirt1 expression levels and signaling pathways. rSirt1 treatment restored cardiac Sirt1 levels and preserved cardiac performance by improving left ventricular ejection fraction, fractional shortening and diastolic function (E/A ratio). In left ventricular samples from rSirt1-treated db/db mice, rSirt1 modulated the cardiac lipidome: medium and long-chain triacylglycerols, long-chain triacylglycerols, and triacylglycerols containing only saturated fatty acids were reduced, while those containing docosahexaenoic acid were increased. Mechanistically, several genes involved in lipid trafficking, metabolism and inflammation, such as Cd36, Acox3, Pparg, Ncoa3, and Ppara were downregulated by rSirt1 both in vitro and in vivo. In humans, reduced cardiac expression levels of Sirt1 were associated with higher intramyocardial triacylglycerols and PPARG-related genes. In the db/db mouse model of MCM, chronic exogenous rSirt1 supplementation rescued cardiac function. This was associated with a modulation of the myocardial lipidome and a downregulation of genes involved in lipid metabolism, trafficking, inflammation, and PPARG signaling. These findings were confirmed in the human diabetic myocardium. Treatments that increase Sirt1 levels may represent a promising strategy to prevent myocardial lipid abnormalities and MCM development.
Sections du résumé
BACKGROUND
Metabolic cardiomyopathy (MCM), characterized by intramyocardial lipid accumulation, drives the progression to heart failure with preserved ejection fraction (HFpEF). Although evidence suggests that the mammalian silent information regulator 1 (Sirt1) orchestrates myocardial lipid metabolism, it is unknown whether its exogenous administration could avoid MCM onset. We investigated whether chronic treatment with recombinant Sirt1 (rSirt1) could halt MCM progression.
METHODS
db/db mice, an established model of MCM, were supplemented with intraperitoneal rSirt1 or vehicle for 4 weeks and compared with their db/ + heterozygous littermates. At the end of treatment, cardiac function was assessed by cardiac ultrasound and left ventricular samples were collected and processed for molecular analysis. Transcriptional changes were evaluated using a custom PCR array. Lipidomic analysis was performed by mass spectrometry. H9c2 cardiomyocytes exposed to hyperglycaemia and treated with rSirt1 were used as in vitro model of MCM to investigate the ability of rSirt1 to directly target cardiomyocytes and modulate malondialdehyde levels and caspase 3 activity. Myocardial samples from diabetic and nondiabetic patients were analysed to explore Sirt1 expression levels and signaling pathways.
RESULTS
rSirt1 treatment restored cardiac Sirt1 levels and preserved cardiac performance by improving left ventricular ejection fraction, fractional shortening and diastolic function (E/A ratio). In left ventricular samples from rSirt1-treated db/db mice, rSirt1 modulated the cardiac lipidome: medium and long-chain triacylglycerols, long-chain triacylglycerols, and triacylglycerols containing only saturated fatty acids were reduced, while those containing docosahexaenoic acid were increased. Mechanistically, several genes involved in lipid trafficking, metabolism and inflammation, such as Cd36, Acox3, Pparg, Ncoa3, and Ppara were downregulated by rSirt1 both in vitro and in vivo. In humans, reduced cardiac expression levels of Sirt1 were associated with higher intramyocardial triacylglycerols and PPARG-related genes.
CONCLUSIONS
In the db/db mouse model of MCM, chronic exogenous rSirt1 supplementation rescued cardiac function. This was associated with a modulation of the myocardial lipidome and a downregulation of genes involved in lipid metabolism, trafficking, inflammation, and PPARG signaling. These findings were confirmed in the human diabetic myocardium. Treatments that increase Sirt1 levels may represent a promising strategy to prevent myocardial lipid abnormalities and MCM development.
Identifiants
pubmed: 37957697
doi: 10.1186/s12933-023-02057-2
pii: 10.1186/s12933-023-02057-2
pmc: PMC10644415
doi:
Substances chimiques
Lipids
0
PPAR gamma
0
Sirt1 protein, mouse
EC 3.5.1.-
Sirtuin 1
EC 3.5.1.-
Triglycerides
0
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
312Informations de copyright
© 2023. The Author(s).
Références
Front Physiol. 2021 Oct 12;12:755060
pubmed: 34712151
Sci Rep. 2016 Nov 30;6:38186
pubmed: 27901083
FEBS J. 2015 Nov;282(21):4242-53
pubmed: 26284828
Cell Death Dis. 2020 Mar 13;11(3):186
pubmed: 32170070
Pharmaceuticals (Basel). 2022 Oct 28;15(11):
pubmed: 36355510
Biomed Pharmacother. 2017 Jun;90:386-392
pubmed: 28380414
J Chromatogr A. 2016 Apr 1;1440:123-134
pubmed: 26928874
Life Sci. 2022 Apr 1;294:120371
pubmed: 35122795
Front Cell Dev Biol. 2021 Feb 16;9:634900
pubmed: 33718370
Circ Res. 2022 Sep 2;131(6):476-491
pubmed: 35968712
Pharmacol Res. 2022 Jan;175:106014
pubmed: 34856334
Cardiovasc Diabetol. 2018 Aug 2;17(1):111
pubmed: 30071860
Nature. 2007 Nov 29;450(7170):712-6
pubmed: 18046409
J Mol Cell Cardiol. 2012 Oct;53(4):521-31
pubmed: 22986367
Am J Physiol Heart Circ Physiol. 2010 Mar;298(3):H833-43
pubmed: 20008278
Cardiovasc Diabetol. 2021 Jan 4;20(1):2
pubmed: 33397369
Arterioscler Thromb Vasc Biol. 2020 May;40(5):1135-1147
pubmed: 32212849
Eur Heart J. 2019 Mar 21;40(12):997-1008
pubmed: 30629164
J Neuroinflammation. 2021 Sep 16;18(1):207
pubmed: 34530866
Circ Res. 2020 May 22;126(11):1628-1645
pubmed: 32437305
Circ Res. 2018 Feb 16;122(4):624-638
pubmed: 29449364
Eur Heart J. 2015 Apr 1;36(13):817-28
pubmed: 24801072
Circ Res. 2018 Jan 5;122(1):58-73
pubmed: 29092894
Oxid Med Cell Longev. 2021 Nov 3;2021:6372430
pubmed: 34777690
J Am Coll Cardiol. 2019 Feb 12;73(5):602-611
pubmed: 30732715
Oxid Med Cell Longev. 2022 Feb 27;2022:1509421
pubmed: 35265261
J Physiol. 2016 Apr 15;594(8):2061-73
pubmed: 26391109
Int J Mol Sci. 2022 Jan 17;23(2):
pubmed: 35055179
Front Cardiovasc Med. 2021 Oct 04;8:742178
pubmed: 34671656
Cell. 2012 Aug 3;150(3):620-32
pubmed: 22863012
Nat Rev Cardiol. 2020 Sep;17(9):585-607
pubmed: 32080423
Cardiovasc Res. 2022 Dec 9;118(15):3126-3139
pubmed: 34971360
Genet Mol Res. 2014 Jan 21;13(1):323-35
pubmed: 24535859
J Am Coll Cardiol. 2008 Sep 16;52(12):1006-12
pubmed: 18786482
Circ Res. 2019 Dec 6;125(12):1106-1120
pubmed: 31638474
Int J Cardiol. 2020 Dec 1;320:106-111
pubmed: 32738258
Diabetes Care. 2023 Jan 1;46(Suppl 1):S19-S40
pubmed: 36507649
Circ Heart Fail. 2020 Sep;13(9):e007197
pubmed: 32894987
Circ Res. 2019 Apr 26;124(9):e63-e80
pubmed: 30786847
J Mol Med (Berl). 2022 Dec;100(12):1721-1739
pubmed: 36396746
J Am Chem Soc. 2021 Jan 27;143(3):1416-1427
pubmed: 33439015
Diabetes Care. 2018 Jan;41(Suppl 1):S13-S27
pubmed: 29222373
J Am Coll Cardiol. 2023 May 9;81(18):1810-1834
pubmed: 37137592
Circ Res. 2018 Sep 14;123(7):868-885
pubmed: 30355082
Cell Metab. 2023 Mar 7;35(3):414-428.e3
pubmed: 36889281
J Cell Mol Med. 2020 Nov;24(21):12355-12367
pubmed: 32961025
Nature. 2019 Apr;568(7752):351-356
pubmed: 30971818
J Am Coll Cardiol. 2013 Jul 23;62(4):263-71
pubmed: 23684677
Eur Heart J. 2015 Dec 21;36(48):3404-12
pubmed: 26112889
Cardiovasc Res. 2023 Oct 16;119(12):2190-2201
pubmed: 37401647
Gastroenterology. 2014 Feb;146(2):539-49.e7
pubmed: 24184811
Physiol Rev. 2021 Oct 1;101(4):1745-1807
pubmed: 33949876
Cardiovasc Res. 2021 Jan 21;117(2):423-434
pubmed: 32666082
Cardiovasc Res. 2017 Mar 15;113(4):389-398
pubmed: 28395010
Anal Bioanal Chem. 2014 Dec;406(30):7937-48
pubmed: 25381612
Nat Rev Endocrinol. 2009 Jul;5(7):367-73
pubmed: 19455179
Nucleic Acids Res. 2010 Nov;38(21):7458-71
pubmed: 20660480
Am J Physiol Heart Circ Physiol. 2014 Dec 15;307(12):H1754-63
pubmed: 25326534