Portal de Periódicos da CAPES

Microtubules and Pressure-Overload Hypertrophy

1997; Lippincott Williams & Wilkins; Volume: 80; Issue: 2 Linguagem: Inglês

10.1161/01.res.80.2.295

1524-4571

Richard A. Walsh,

Genetics, Aging, and Longevity in Model Organisms

HomeCirculation ResearchVol. 80, No. 2Microtubules and Pressure-Overload Hypertrophy Free AccessResearch ArticlePDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessResearch ArticlePDF/EPUBMicrotubules and Pressure-Overload Hypertrophy Richard A. Walsh Richard A. WalshRichard A. Walsh Director of Cardiology & Cardiovascular Center, University of Cincinnati College of Medicine, PO Box 670542, Cincinnati, OH 45267-0542. Originally published1 Feb 1997https://doi.org/10.1161/01.RES.80.2.295Circulation Research. 1997;80:295–296Microtubules and Pressure-Overload HypertrophyCardiac hypertrophy is a process whereby an increase in chamber mass occurs largely by an increase in size of terminally differentiated cardiomyocytes in response to increased external and/or internal work. Hypertrophied cardiomyocytes have abnormal electrical and mechanical properties that underlie, at least in part, altered cardiovascular function in a variety of pathological states. In particular, heart failure of diverse origins is invariably accompanied by hypertrophy, and contractile failure appears to be an inevitable consequence of hypertrophic stimuli of sufficient severity and duration. Molecular and biochemical mechanisms that are responsible for functions of the hypertrophied cardiomyocyte are being intensively studied using genetically engineered mice, animal models of human disease, and clinical investigations. These approaches have identified important alterations in myofilament and calcium-cycling proteins, sarcolemmal ion pumps, channels, and receptors and in various signal transduction pathways of hypertrophied hearts.1In contrast to our knowledge of the importance of alterations in proteins that actively participate in myocyte contraction, relaxation, and growth, there is less information regarding the role of cytoarchitectural components of the cardiomyocyte in normal and pathological states. The cardiomyocyte cytoskeleton is composed of myofibrillar and extramyofibrillar or cytoplasmic compartments. Biophysical interactions among sarcolemmal integrin receptors and the cytoplasmic and myofibrillar cytoskeleton are largely unknown. The myofibrillar cytoskeleton includes titin (the largest protein known and the third most abundant cardiac protein), desmin, C protein, nebulin, and vinculin.2 The extramyofibrillar cytoskeleton of all eukaryotic cells, including the cardiomyocyte, is composed of an intertwined network of three classes of filamentous biopolymers: actin-containing microfilaments, intermediate filaments, and microtubules.3 Microtubules are polymers of α- and β-tubulin heterodimers that can polymerize and depolymerize to participate in multiple cellular processes, including growth and proliferation.4In a series of elegant studies, Cooper and colleagues567 have unambiguously established the importance of an increase in the amount and polymerization status of tubulin to cardiomyocyte function consequent to acute right ventricular feline pressure overload. They demonstrated increases in tubulin at the steady state message and protein level that were associated with impaired cardiomyocyte sarcomere dynamics as assessed by laser diffraction microscopy. Decreases in the polymerization state of tubulin with colchicine (10−6 mol/L) or low temperature largely reversed these abnormalities, whereas increased stability of tubulin polymerization effected by taxol administration (10−5 mol/L) produced the opposite effect.Tagawa et al8 in this issue of Circulation Research propose and establish that the principal mechanism for the dysfunctional effects of abnormal amounts and increased polymerization of tubulin in feline right ventricular hypertrophy appears to be an increase in cardiomyocyte stiffness and viscosity, as demonstrated by magnetic twisting cytometry. In this process, cardiomyocytes enzymatically extracted from right and left ventricles from cats that underwent pulmonary artery banding were decorated with ferromagnetic beads coated with a synthetic peptide that is specific for cell surface integrin receptors. Application of an intermittent magnetic field permitted direct measurement of the stress-strain relations from which estimates of the extramyofibrillar cell stiffness and viscosity were derived. Taken together, the study of Tagawa et al and previous studies clearly establish a critical role for alterations in amount and biophysical status of tubulin in the cardiomyocyte dysfunction observed in this model of right ventricular pressure-overload hypertrophy.Can the dysfunctional effects of increased tubulin protein demonstrated by Tagawa et al8 be extrapolated to other forms of pressure-overload hypertrophy or to cardiac hypertrophy in general? At the present time, the answer appears to be negative. The results appear to be load, species, and chamber specific. Cooper and colleagues (Tsutsui et al5 ) have previously shown that feline volume-overload hypertrophy produced by surgical creation of an atrial septal defect fails to alter microtubule density or cardiomyocyte function despite an increase in right ventricular chamber mass similar to that which they observed with pulmonary arterial banding. Left ventricular pressure-overload hypertrophy produced by descending thoracic aortic banding in guinea pigs failed to alter the protein level of tubulin, and perfusion with colchicine (10−6) failed to alter isovolumic left ventricular mechanics in normal ventricles, hypertrophied ventricles, or hypertrophied ventricles with contractile depression.9 Serial immunohistochemical studies in the rat revealed transient elevations of β-tubulin after ascending aortic banding that returned to normal after 2 weeks in contrast to the prolonged elevation of β-tubulin observed in feline acute right ventricular pressure-overload hypertrophy.101112Despite the apparent species, model, and chamber dependence of functionally significant alterations in the microtubules, feline right ventricular pressure-overload hypertrophy has been and will remain a valuable model to elucidate mechanisms responsible for functional alterations in pressure-overload hypertrophy and congestive heart failure. The study in the present issue of Circulation Research8 clearly demonstrates that alterations in the extramyofilament cytoskeletal matrix and their reversal can have profound functional consequences. The ability to modulate the amount and degree of polymerization of tubulin, the principal determinant of altered contractile function in this model, may have important therapeutic implications. Future studies of the cardiomyocyte cytoskeleton will likely focus on the role of alterations in microtubules in other mammalian species and, in particular, in human cardiac hypertrophy and congestive heart failure. In addition, critical examination of the fundamental role of alterations in titin and other myofilament cytoskeletal proteins in normal and pathological cardiac function is likely to occur. Titin is the major determinant of passive tension and restoring forces in cardiac and skeletal muscle,13 and the abundance of this protein appears to be increased in cardiac hypertrophy and failure (References 9, 14, 15, and also reviewed in this issue of Circulation Research15 ).FootnotesCorrespondence to Richard A. Walsh, MD, Director of Cardiology & Cardiovascular Center, University of Cincinnati College of Medicine, PO Box 670542, Cincinnati, OH 45267-0542. E-mail [email protected] References 1 Wagoner LE, Walsh RA. The cellular pathophysiology of progression to heart failure. Curr Opin Cardiol.1996; 11:237-244.CrossrefMedlineGoogle Scholar2 Maruyama K. Connectin, an elastic protein of striated muscle. Biophys Chem.1994; 50:73-85.CrossrefMedlineGoogle Scholar3 Ingber DE. Cellular tensegrity: defining new rules of biological design that govern the cytoskeleton. J Cell Sci.1993; 104:613-627.CrossrefMedlineGoogle Scholar4 Gelfand VI, Bershadsky AD. Microtubule dynamics: mechanism, regulation, and function. Annu Rev Cell Biol.1991; 7:93-116.CrossrefMedlineGoogle Scholar5 Tsutsui H, Ishihara K, Cooper G. Cytoskeletal role in the contractile dysfunction of hypertrophied myocardium. Science.1993; 260:682-687.CrossrefMedlineGoogle Scholar6 Tsutsui H, Tagawa H, Kent RL, McCollam PL, Ishihara K, Nagatsu M, Cooper G. Role of microtubules in contractile dysfunction of hypertrophied cardiocytes. Circulation.1994; 90:533-555.CrossrefMedlineGoogle Scholar7 Tagawa H, Rozich JD, Tsutsui H, Narishige T, Kuppuswamy D, Sato H, McDermott PJ, Koide M, Cooper G. Basis for increased microtubules in pressure-overload hypertrophied cardiocytes. Circulation.1996; 93:1230-1243.CrossrefMedlineGoogle Scholar8 Tagawa H, Wang N, Narishige T, Ingber DE, Zile MR, Cooper G IV. Cytoskeletal mechanics in pressure-overload cardiac hypertrophy. Circ Res. 1997;80:•••-•••.Google Scholar9 Collins JF, Pawloski-Dahm C, Davis MG, Ball N, Dorn GW II, Walsh RA. The role of the cytoskeleton in left ventricular pressure overload hypertrophy and failure. J Mol Cell Cardiol.1996; 28:1435-1443.CrossrefMedlineGoogle Scholar10 Samuel J, Schwartz K, Lompre A, Delcayre C, Marotte F, Swinghedauw B, Rappaport L. Immunological quantitation and localization of tubulin in adult rat heart isolated myocytes. Eur J Cell Biol.1983; 31:99-106.MedlineGoogle Scholar11 Rappaport L, Samuel JL, Bertier B, Bugaisky L, Marotte F, Mercadier A, Schwartz K. Isomyosins, microtubules and desmin during the onset of cardiac hypertrophy in the rat. Eur Heart J.1984; 5:243-250.CrossrefMedlineGoogle Scholar12 Samuel J, Marotte F, Delcayre C, Rappaport L. Microtubule reorganization is related to rate of heart myocyte hypertrophy in rat. Am J Physiol.1986; 251:H1118-H1125.MedlineGoogle Scholar13 Helmes M, Trombita´s K, Granzier H. Titin develops restoring force in rat cardiac myocytes. Circ Res.1996; 79:619-626.CrossrefMedlineGoogle Scholar14 Morano I, Hadicke K, Grom S, Koch A, Schwinger RH, Bohm M, Bartel S, Erdmann E, Krause E. Titin, myosin light chains and C-protein in the developing and failing human heart. J Mol Cell Cardiol.1994; 26:361-268.CrossrefMedlineGoogle Scholar15 Labeit S, Kolmerer B, Linke WA. The giant protein titin: emerging roles in physiology and pathophysiology. Circ Res. 1997;80:•••-•••.Google Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited ByHalim A, Narayanan G, Hato T, Ho L, Wan D, Siedlecki A, Rhee E, Allegretti A, Nigwekar S, Zehnder D, Hiemstra T, Bonventre J, Charytan D, Kalim S, Thadhani R, Lu T and Lim K (2022) Myocardial Cytoskeletal Adaptations in Advanced Kidney Disease, Journal of the American Heart Association, 11:5, Online publication date: 1-Mar-2022. Lim K, McGregor G, Coggan A, Lewis G and Moe S (2020) Cardiovascular Functional Changes in Chronic Kidney Disease: Integrative Physiology, Pathophysiology and Applications of Cardiopulmonary Exercise Testing, Frontiers in Physiology, 10.3389/fphys.2020.572355, 11 Shimura D, Nakai G, Jiao Q, Osanai K, Kashikura K, Endo K, Soga T, Goda N and Minamisawa S (2013) Metabolomic profiling analysis reveals chamber-dependent metabolite patterns in the mouse heart, American Journal of Physiology-Heart and Circulatory Physiology, 10.1152/ajpheart.00867.2012, 305:4, (H494-H505), Online publication date: 15-Aug-2013. Wilding J, Schneider J, Sang A, Davies K, Neubauer S and Clarke K (2004) Dystrophin‐ and MLP‐deficient mouse hearts: marked differences in morphology and function, but similar accumulation of cytoskeletal proteins, The FASEB Journal, 10.1096/fj.04-1731fje, 19:1, (79-81), Online publication date: 1-Jan-2005. Chakraborti S, Chakraborti T and Shaw G (2000) β-adrenergic mechanisms in cardiac diseases:, Cellular Signalling, 10.1016/S0898-6568(00)00087-5, 12:8, (499-513), Online publication date: 1-Aug-2000. Webster D and Patrick D (2000) Beating rate of isolated neonatal cardiomyocytes is regulated by the stable microtubule subset, American Journal of Physiology-Heart and Circulatory Physiology, 10.1152/ajpheart.2000.278.5.H1653, 278:5, (H1653-H1661), Online publication date: 1-May-2000. SWYNGHEDAUW B (1999) Molecular Mechanisms of Myocardial Remodeling, Physiological Reviews, 10.1152/physrev.1999.79.1.215, 79:1, (215-262), Online publication date: 1-Jan-1999. Palmer B, Valent S, Holder E, Weinberger H and Bies R (1998) Microtubules modulate cardiomyocyte β-adrenergic response in cardiac hypertrophy, American Journal of Physiology-Heart and Circulatory Physiology, 10.1152/ajpheart.1998.275.5.H1707, 275:5, (H1707-H1716), Online publication date: 1-Nov-1998. February 1, 1997Vol 80, Issue 2 Advertisement Article InformationMetrics https://doi.org/10.1161/01.RES.80.2.295 Originally publishedFebruary 1, 1997 KeywordscytoskeletonhypertrophycardiomyocytePDF download Advertisement