β-Adrenergic signaling, monoamine oxidase A and antioxidant defence in the myocardium of SHR and SHR-mtBN conplastic rat strains: the effect of chronic hypoxia
Tóm tắt
The β-adrenergic signaling pathways and antioxidant defence mechanisms play important roles in maintaining proper heart function. Here, we examined the effect of chronic normobaric hypoxia (CNH, 10% O2, 3 weeks) on myocardial β-adrenergic signaling and selected components of the antioxidant system in spontaneously hypertensive rats (SHR) and in a conplastic SHR-mtBN strain characterized by the selective replacement of the mitochondrial genome of SHR with that of the more ischemia–resistant Brown Norway strain. Our investigations revealed some intriguing differences between the two strains at the level of β-adrenergic receptors (β-ARs), activity of adenylyl cyclase (AC) and monoamine oxidase A (MAO-A), as well as distinct changes after CNH exposure. The β2-AR/β1-AR ratio was significantly higher in SHR-mtBN than in SHR, apparently due to increased expression of β2-ARs. Adaptation to hypoxia elevated β2-ARs in SHR and decreased the total number of β-ARs in SHR-mtBN. In parallel, the ability of isoprenaline to stimulate AC activity was found to be higher in SHR-mtBN than that in SHR. Interestingly, the activity of MAO-A was notably lower in SHR-mtBN than in SHR, and it was markedly elevated in both strains after exposure to hypoxia. In addition to that, CNH markedly enhanced the expression of catalase and aldehyde dehydrogenase-2 in both strains, and decreased the expression of Cu/Zn superoxide dismutase in SHR. Adaptation to CNH intensified oxidative stress to a similar extent in both strains and elevated the IL-10/TNF-α ratio in SHR-mtBN only. These data indicate that alterations in the mitochondrial genome can result in peculiar changes in myocardial β-adrenergic signaling, MAO-A activity and antioxidant defence and may, thus, affect the adaptive responses to hypoxia.
Tài liệu tham khảo
Hajri T, Ibrahimi A, Coburn CT, Knapp FF, Kurtz T, Pravenec M, Abumrad NA (2001) Defective fatty acid uptake in the spontaneously hypertensive rat is a primary determinant of altered glucose metabolism, hyperinsulinemia, and myocardial hypertrophy. J Biol Chem 276:23661–23666
Itter G, Jung W, Juretschke P, Schoelkens BA, Linz W (2004) A model of chronic heart failure in spontaneous hypertensive rats (SHR). Lab Anim 38:138–148
Penna C, Pasqua T, Amelio D, Perrelli MG, Angotti C, Tullio F, Mahata SK, Tota B, Pagliaro P, Cerra MC, Angelone T (2014) Catestatin increases the expression of anti-apoptotic and pro-angiogenetic factors in the post-ischemic hypertrophied heart of SHR. PLoS One 9:e102536
Ravingerová T, Bernátová I, Matejíková J, Ledvényiová V, Nemčeková M, Pecháňová O, Tribulová N, Slezák J (2011) Impaired cardiac ischemic tolerance in spontaneously hypertensive rats is attenuated by adaptation to chronic and acute stress. Exp Clin Cardiol 16:e23–e29
Kolar F, Parratt JR (1997) Antiarrhythmic effect of ischemic preconditioning in hearts of spontaneously hypertensive rats. Exp Clin Cardiol 2:124–128
Neckář J, Šilhavy J, Zídek V, Landa V, Mlejnek P, Šimáková M, Seidman JG, Seidman C, Kazdová L, Klevstig M, Novák F, Vecka M, Papoušek F, Houštěk J, Drahota Z, Kurtz TW, Kolář F, Pravenec M (2012) CD36 overexpression predisposes to arrhythmias but reduces infarct size in spontaneously hypertensive rats: gene expression profile analysis. Physiol Genom 44:173–182
Klevstig M, Manakov D, Kasparova D, Brabcova I, Papousek F, Zurmanova J, Zidek V, Silhavy J, Neckar J, Pravenec M, Kolar F, Novakova O, Novotny J (2013) Transgenic rescue of defective Cd36 enhances myocardial adenylyl cyclase signaling in spontaneously hypertensive rats. Pflugers Arch 465:1477–1486
Florea SM, Blatter LA (2012) Regulation of cardiac alternans by β-adrenergic signaling pathways. Am J Physiol Heart Circ Physiol 303:H1047–H1056
Frances C, Nazeyrollas P, Prevost A, Moreau F, Pisani J, Davani S, Kantelip JP, Millart H (2003) Role of beta 1- and beta 2-adrenoceptor subtypes in preconditioning against myocardial dysfunction after ischemia and reperfusion. J Cardiovasc Pharmacol 41:396–405
Tong H, Bernstein D, Murphy E, Steenbergen C (2005) The role of beta-adrenergic receptor signaling in cardioprotection. FASEB J 19:983–985
Salie R, Moolman JA, Lochner A (2011) The role of β-adrenergic receptors in the cardioprotective effects of beta-preconditioning (βPC). Cardiovasc Drugs Ther 25:31–46
Mader SL, Downing CL, Van Lunteren E (1991) Effect of age and hypoxia on beta-adrenergic receptors in rat heart. J Appl Physiol 71:2094–2098
Kacimi R, Richalet JP, Corsin A, Abousahl I, Crozatier B (1992) Hypoxia-induced downregulation of beta-adrenergic receptors in rat heart. J Appl Physiol 73:1377–1382
Mardon K, Merlet P, Syrota A, Mazière B (1998) Effects of 5-day hypoxia on cardiac adrenergic neurotransmission in rats. J Appl Physiol 85:890–897
León-Velarde F, Bourin MC, Germack R, Mohammadi K, Crozatier B, Richalet JP (2001) Differential alterations in cardiac adrenergic signaling in chronic hypoxia or norepinephrine infusion. Am J Physiol Regul Integr Comp Physiol 280:R274–R281
Hrbasová M, Novotny J, Hejnová L, Kolár F, Neckár J, Svoboda P (2003) Altered myocardial Gs protein and adenylyl cyclase signaling in rats exposed to chronic hypoxia and normoxic recovery. J Appl Physiol 94:2423–2432
Johnson TS, Young JB, Landsberg L (1983) Sympathoadrenal responses to acute and chronic hypoxia in the rat. J Clin Invest 71:1263–1272
Andersson DC, Fauconnier J, Yamada T, Lacampagne A, Zhang SJ, Katz A, Westerblad H (2011) Mitochondrial production of reactive oxygen species contributes to the β-adrenergic stimulation of mouse cardiomycytes. J Physiol 589:1791–1801
Mallet RT, Ryou MG, Williams AG, Howard L, Downey HF (2006) β1-Adrenergic receptor antagonism abrogates cardioprotective effects of intermittent hypoxia. Basic Res Cardiol 101:436–446
Zuo L, Roberts WJ, Tolomello RC, Goins AR (2013) Ischemic and hypoxic preconditioning protect cardiac muscles via intracellular ROS signaling. Front Biol 8:305–311
Kolár F, Jezková J, Balková P, Breh J, Neckár J, Novák F, Nováková O, Tomásová H, Srbová M, Ost’ádal B, Wilhelm J, Herget J (2007) Role of oxidative stress in PKC-delta upregulation and cardioprotection induced by chronic intermittent hypoxia. Am J Physiol Heart Circ Physiol 292:H224–H230
Kasparova D, Neckar J, Dabrowska L, Novotny J, Mraz J, Kolar F, Zurmanova J (2015) Cardioprotective and nonprotective regimens of chronic hypoxia diversely affect the myocardial antioxidant systems. Physiol Genom 47:612–620
Cadenas S, Aragonés J, Landázuri MO (2010) Mitochondrial reprogramming through cardiac oxygen sensors in ischaemic heart disease. Cardiovasc Res 88:219–228
Mueller IA, Grim JM, Beers JM, Crockett EL, O’Brien KM (2011) Inter-relationship between mitochondrial function and susceptibility to oxidative stress in red- and white-blooded Antarctic notothenioid fishes. J Exp Biol 214:3732–3741
Cortie CH, Hulbert AJ, Hancock SE, Mitchell TW, McAndrew D, Else PL (2015) Of mice, pigs and humans: an analysis of mitochondrial phospholipids from mammals with very different maximal lifespans. Exp Gerontol 70:135–143
Kelly RD, Rodda AE, Dickinson A, Mahmud A, Nefzger CM, Lee W, Forsythe JS, Polo JM, Trounce IA, McKenzie M, Nisbet DR, St John JC (2013) Mitochondrial DNA haplotypes define gene expression patterns in pluripotent and differentiating embryonic stem cells. Stem Cells 31:703–716
Wallace DC (2005) A mitochondrial paradigm of metabolic and degenerative diseases, aging, and cancer: a dawn for evolutionary medicine. Annu Rev Genet 39:359–407
Neckář J, Svatoňová A, Weissová R, Drahota Z, Zajíčková P, Brabcová I, Kolář D, Alánová P, Vašinová J, Šilhavý J, Hlaváčková M, Tauchmannová K, Milerová M, Ošťádal B, Červenka L, Žurmanová J, Kalous M, Nováková O, Novotný J, Pravenec M, Kolář F (2017) Selective replacement of mitochondrial DNA increases the cardioprotective effect of chronic continuous hypoxia in spontaneously hypertensive rats. Clin Sci 131:865–881
Anderson EJ, Efird JT, Davies SW, O’Neal WT, Darden TM, Thayne KA, Katunga LA, Kindell LC, Ferguson TB, Anderson CA, Chitwood WR, Koutlas TC, Williams JM, Rodriguez E, Kypson AP (2014) Monoamine oxidase is a major determinant of redox balance in human atrial myocardium and is associated with postoperative atrial fibrillation. J Am Heart Assoc 3:e000713
Waskova-Arnostova P, Elsnicova B, Kasparova D, Sebesta O, Novotny J, Neckar J, Kolar F, Zurmanova J (2013) Right-to-left ventricular differences in the expression of mitochondrial hexokinase and phosphorylation of Akt. Cell Physiol Biochem 31:66–79
Pfaffl MW (2001) A new mathematical model for relative quantification in real-time RT-PCR. Nucleic Acids Res 29:e45
Hahnova K, Kasparova D, Zurmanova J, Neckar J, Kolar F, Novotny J (2016) β-Adrenergic signaling in rat heart is similarly affected by continuous and intermittent normobaric hypoxia. Gen Physiol Biophys 35:165–167
Ihnatovych I, Hejnová L, Kostrnová A, Mares P, Svoboda P, Novotný J (2001) Maturation of rat brain is accompanied by differential expression of the long and short splice variants of G(s)alpha protein: identification of cytosolic forms of G(s)alpha. J Neurochem 79:88–97
Xu Y, Ku BS, Yao HY, Lin YH, Ma X, Zhang YH, Li XJ (2005) The effects of curcumin on depressive-like behaviors in mice. Eur J Pharmacol 518:40–46
Novotny J, Bourová L, Kolár F, Svoboda P (2001) Membrane-Bound and cytosolic forms of heterotrimeric G proteins in young and adult rat myocardium: influence of neonatal hypo- and hyperthyroidism. J Cell Biochem 82:215–224
Pilz J, Meineke I, Gleiter CH (2000) Measurement of free and bound malondialdehyde in plasma by high-performance liquid chromatography as the 2,4-dinitrophenylhydrazine derivative. J Chromatogr B Biomed Sci Appl 742:315–325
Chytilová A, Borchert GH, Mandíková-Alánová P, Hlaváčková M, Kopkan L, Khan MA, Imig JD, Kolář F, Neckář J (2015) Tumour necrosis factor-α contributes to improved cardiac ischaemic tolerance in rats adapted to chronic continuous hypoxia. Acta Physiol 214:97–108
Giannuzzi CE, Seidler FJ, Slotkin TA (1995) Beta-adrenoceptor control of cardiac adenylyl cyclase during development: agonist pretreatment in the neonate uniquely causes heterologous sensitization, not desensitization. Brain Res 694:271–278
Mieno S, Horimoto H, Sawa Y, Watanabe F, Furuya E, Horimoto S, Kishida K, Sasaki S (2005) Activation of beta2-adrenergic receptor plays a pivotal role in generating the protective effect of ischemic preconditioning in rat hearts. Scand Cardiovasc J 39:313–319
Fajardo G, Zhao M, Berry G, Wong LJ, Mochly-Rosen D, Bernstein D (2011) β2-adrenergic receptors mediate cardioprotection through crosstalk with mitochondrial cell death pathways. J Mol Cell Cardiol 51:781–789
Schömig A, Fischer S, Kurz T, Richardt G, Schömig E (1987) Nonexocytotic release of endogenous noradrenaline in the ischemic and anoxic rat heart: mechanism and metabolic requirements. Circ Res 60:194–205
Kaludercic N, Carpi A, Menabò R, Di Lisa F, Paolocci N (2011) Monoamine oxidases (MAO) in the pathogenesis of heart failure and ischemia/reperfusion injury. Biochim Biophys Acta 1813:1323–1332
Dănilă MD, Privistirescu AI, Mirica SN, Sturza A, Ordodi V, Noveanu L, Duicu OM, Muntean DM (2015) Acute inhibition of monoamine oxidase and ischemic preconditioning in isolated rat hearts: interference with postischemic functional recovery but no effect on infarct size reduction. Can J Physiol Pharmacol 93:819–825
Maher JT, Deniiston JC, Wolfe DL, Cymerman A (1978) Mechanism of the attenuated cardiac response to beta-adrenergic stimulation in chronic hypoxia. J Appl Physiol Respir Environ Exerc Physiol 44:647–651
Shatemirova KK, Zelenshchikova VA, Min’ko IV (1990) Catalytic properties of monoamine oxidases during adaptation to altitude chamber hypoxia. Kosm Biol Aviakosm Med 24:54–56
Yan F, Mu Y, Yan G, Liu J, Shen J, Luo G (2010) Antioxidant enzyme mimics with synergism. Mini Rev Med Chem 10:342–356
Nakanishi K, Tajima F, Nakamura A, Yagura S, Ookawara T, Yamashita H, Suzuki K, Taniguchi N, Ohno H (1995) Effects of hypobaric hypoxia on antioxidant enzymes in rats. J Physiol 489(Pt 3):869–876
Neckár J, Borchert GH, Hlousková P, Mícová P, Nováková O, Novák F, Hroch M, Papousek F, Ost’ádal B, Kolár F (2013) Brief daily episode of normoxia inhibits cardioprotection conferred by chronic continuous hypoxia. Role of oxidative stress and BKCa channels. Curr Pharm Des 19:6880–6889
Bu HM, Yang CY, Wang ML, Ma HJ, Sun H, Zhang Y (2015) K(ATP) channels and MPTP are involved in the cardioprotection bestowed by chronic intermittent hypobaric hypoxia in the developing rat. J Physiol Sci 65:367–376
Chen CH, Budas GR, Churchill EN, Disatnik MH, Hurley TD, Mochly-Rosen D (2008) Activation of aldehyde dehydrogenase-2 reduces ischemic damage to the heart. Science 321:1493–1495
Ohtsuji M, Katsuoka F, Kobayashi A, Aburatani H, Hayes JD, Yamamoto M (2008) Nrf1 and Nrf2 play distinct roles in activation of antioxidant response element-dependent genes. J Biol Chem 283:33554–33562
Chau CM, Evans MJ, Scarpulla RC (1992) Nuclear respiratory factor 1 activation sites in genes encoding the gamma-subunit of ATP synthase, eukaryotic initiation factor 2 alpha, and tyrosine aminotransferase. Specific interaction of purified NRF-1 with multiple target genes. J Biol Chem 267:6999–7006
Evans MJ, Scarpulla RC (1990) NRF-1: a trans-activator of nuclear-encoded respiratory genes in animal cells. Genes Dev 4:1023–1034
Scarpulla RC (2008) Transcriptional paradigms in mammalian mitochondrial biogenesis and function. Physiol Rev 88:611–638
Földes-Papp Z, Domej W, Demel U, Tilz GP (2005) Oxidative stress caused by acute and chronic exposition to altitude. Wien Med Wochenschr 155:136–142
Singh M, Thomas P, Shukla D, Tulsawani R, Saxena S, Bansal A (2013) Effect of subchronic hypobaric hypoxia on oxidative stress in rat heart. Appl Biochem Biotechnol 169:2405–2419
Liu JN, Zhang JX, Lu G, Qiu Y, Yang D, Yin GY, Zhang XL (2010) The effect of oxidative stress in myocardial cell injury in mice exposed to chronic intermittent hypoxia. Chin Med J 123:74–78
Zhou W, Li S, Wan N, Zhang Z, Guo R, Chen B (2012) Effects of various degrees of oxidative stress induced by intermittent hypoxia in rat myocardial tissues. Respirology 17:821–829
Wang WY, Wan WY, Zeng YM, Chen XY, Zhang YX (2013) Effect of Telmisartan on local cardiovascular oxidative stress in mouse under chronic intermittent hypoxia condition. Sleep Breath 17:181–187
Lecour S (2009) Activation of the protective Survivor Activating Factor Enhancement (SAFE) pathway against reperfusion injury: does it go beyond the RISK pathway? J Mol Cell Cardiol 47:32–40