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Myocyte Shearing, Myocardial Sheets, and Microtubules

2006; Lippincott Williams & Wilkins; Volume: 98; Issue: 1 Linguagem: Inglês

10.1161/01.res.0000200395.82480.8d

1524-4571

Andrew D. McCulloch, Jeffrey H. Omens,

Muscle Physiology and Disorders

HomeCirculation ResearchVol. 98, No. 1Myocyte Shearing, Myocardial Sheets, and Microtubules Free AccessEditorialPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessEditorialPDF/EPUBMyocyte Shearing, Myocardial Sheets, and Microtubules Andrew D. McCulloch and Jeffrey H. Omens Andrew D. McCullochAndrew D. McCulloch From the Department of Bioengineering, University of California San Diego, La Jolla, Calif. and Jeffrey H. OmensJeffrey H. Omens From the Department of Bioengineering, University of California San Diego, La Jolla, Calif. Originally published6 Jan 2006https://doi.org/10.1161/01.RES.0000200395.82480.8dCirculation Research. 2006;98:1–3The cytoskeleton of cardiac myocytes is a complex network of many interacting protein filaments and associated proteins with multiple functions: it forms structures responsible for maintaining cell shape and contractile filament registration, structural integrity, internal transport and cell division, and scaffolding for several putative signaling cascades.1 The tight coupling between the extracellular matrix and components of the cytoskeleton at the cell membrane suggests that, in addition to transmitting contractile forces generated by the myofilaments to the matrix and the cardiac chambers, the cytoskeleton may also be important for propagating external physical signals into the cell.2Mutations in a growing list of cytoskeletal genes are associated with cardiomyopathies. Disruption of desmin, plakoglobin, N-cadherin, plectin, and vinculin all produce a dilated cardiac phenotype with impaired function, either in fetal development or after birth.3,4,5 These are elements of the cytoskeleton that connect intracellular structures with the extracellular matrix, and thus are likely force-transmitting components in the myocyte. Originally, Chien6 proposed that defects in the cytoskeletal component of the myocyte result in a dilated cardiomyopathic phenotype, whereas mutations in the sarcomeric proteins typically generate a pattern of hypertrophic cardiomyopathy with preserved ventricular systolic function in addition to the myocyte hypertrophy and disarray.7 But as more data have accumulated, the picture has become more complex, and cytoskeletal defects have been implicated in hypertrophic as well as dilated cardiomyopathies.8Cytoskeletal proteins have been implicated in several load-sensing pathways, and there is evidence that cytoskeletal proteins play a critical role in biomechanical signaling and may be involved with ventricular dilation and heart failure.9,10 These studies have led to the hypothesis that there may exist a common pathway to cardiac dilation and failure, and the critical components of this "failure transition"11 are likely to be structural themselves or closely related to force transmitting elements.The complex structure and multiple functions of the cytoskeleton make it inherently difficult to study on a quantitative scale.12 Its physical and signaling properties rely not only on its molecular structure but its dynamic three-dimensional organization. Experimental interventions that disrupt components of the cytoskeleton can alter the distribution of stresses within the other components. Separating the "inside-out" force transmission functions of the cytoskeleton from the "outside-in" mechanotransduction and signaling roles is challenging, especially in vivo. Yet it is likely that both play a significant role in cardiac remodeling and heart failure. Defects in the actin-associated cytoskeleton causing dilated cardiomyopathy, such as the deletion of muscle LIM protein (MLP)13—a Z-disc-associated structural protein interacting with actin, titin, and alpha-actinin14—have been shown to result in alterations both to biomechanical signal transduction and to diastolic mechanical properties.15 Understanding the precise molecular mechanisms of these alterations will require a comprehensive theoretical framework for the biophysics and mechanical properties of the cytoskeletal network within the context of the intact myocyte.Both from a molecular viewpoint and a biophysical and mechanotransduction perspective, the microtubule network is among the better-studied components in the cytoskeleton.16 A substantial body of evidence implicates microtubule polymerization and depolymerization in myocyte dysfunction in some models of ventricular hypertrophy,17 though not all. Studies have shown that microtubules contribute significantly to the viscoelastic properties of myocytes,18 especially their passive viscosity.19With few exceptions, studies of the mechanical properties of myocytes and the contributions of the microtubules have used a single uniaxial mechanical test, most commonly measuring the longitudinal elastic stiffness or viscosity of the cell. However, the resting and active myocardium is well known to be anisotropic.20 Even the mechanotransduction responses of micropatterned cultured myocytes to stretch in vitro are anisotropic, with differential induction of hypertrophic gene expression and protein synthesis by longitudinal versus transverse stretch.21 One isolated cell study measured the axial and transverse mechanical properties of single myocytes,22 but the intact myocardium also experiences substantial shearing stresses and strains in vivo.23 Tagawa and colleagues24 used magnetic twisting rheometry to probe the viscoelastic properties of the myocyte cytoskeleton. However, information on the anisotropic material properties of myocytes under multi-axial tension, compression and shear, and the contributions of cytoskeletal structures, remains sparse.In this issue of Circulation Research, Nishimura and coworkers25 describe a novel combination of single cell mechanical tests that they have used to probe the elastic properties of isolated adult rat ventricular myocytes under axial tension, transverse compression, as well as axial and longitudinal shearing. Using a combination of flexible and rigid carbon microfibers, latex microspheres and thin glass plates together with piezoelectric translators, these authors constructed an ingenious suite of micromechanical tests for stretching single myocytes, indenting them transversely with a 10-μm microsphere, and shearing them two glass plates displaced axially or transversely.When normal rat ventricular myocytes were treated with colchicine to depolymerize microtubules or paclitaxil to hyperpolymerize them, there were no significant alterations in elastic stiffnesses for axial tension, transverse compression, or transverse shear. However, longitudinal shearing stiffness was significantly decreased by colchicine and increased by paclitaxil. Although viscous properties were not measured as comprehensively, the comparative specificity of this result is what makes it most interesting, because it affords the opportunity to distinguish the contributions of different compartments of the cell skeleton to specific mechanical responses. Ultimately, this will require the development of structurally and biophysically detailed computational models of myocyte micromechanics based on the macromolecular structure and interactions of the cytoskeletal filaments systems. In an early step toward this goal, the authors have developed a finite element model of intramyocyte stress distributions that includes elements for the microtubule network, the actin cytoskeleton, membrane, and myofilaments.The material properties assigned to each component are oversimplified and somewhat arbitrary. For example, the properties of the myofilaments are modeled using a constitutive law for the whole myocardium, whose resting properties are also dependent on the extracellular matrix. Nevertheless, the model did show that alterations in microtubule density had a significant influence on longitudinal shear stiffness but not on transverse shear stiffness or axial elastic properties consistent with the experimental observations. The authors did not report the changes in the model on transverse compressive stiffness. Although changes in transverse compressive stiffness did not reach statistical significance in the myocyte experimental measurements, the mean values were 40% to 50% greater for paclitaxil-treated cells than those incubated in colchicine. More cells or a larger range of doses may have revealed a significant effect.These observations and the computational analysis are in keeping with the "tensegrity" hypothesis of cell mechanics proposed by Ingber.26 When the famed architect Buckminster-Fuller coined the term, he characterized a tensegrity structure as one that derives stability (especially in shear) from continuous tension and discontinuous compression. In the present model, the continuous tension arises from pre-tension in the actin cytoskeleton and the microtubules are the discontinuous compressive members. Although the model is clearly a simplification, the new experimental findings suggest that these new, more comprehensive multi-axial studies of single myocyte mechanics have the potential to elucidate specific structural roles of individual cytoskeletal compartments.It is difficult to extrapolate the significance of these new findings in isolated myocytes directly to ventricular mechanics in vivo. Yet there is ample reason to believe they are important. It is well known that the myocardium undergoes complex three-dimensional deformations during the cardiac cycle. In particular, transverse and longitudinal shearing comprise significant components of three-dimensional myocardial stress and strain.23 Shear is also associated with ventricular torsion during contraction and relaxation, which is important for maintaining transmural uniformity of fiber stresses and strains during ejection and filling.27,28 Studies also suggest that alterations in systolic torsion are sensitive indicators of systolic dysfunction in ischemia and other pathological conditions.29Transverse shearing between myocardial laminae or "sheets" has also been shown to play a significant role in wall thickening.30 Left ventricular torsion during relaxation is driven by lengthening of myofibers in the epicardial layers, and is associated with rearrangement of myolaminar sheets in the endocardial layers.31 Although most of the transverse shearing strains are probably accommodated by sheet rearrangement and the extracellular matrix, shear stresses must also be transmitted to the myocytes within the myocardial laminae. The first intervention reported to dramatically alter transverse myocardial shears was ectopic pacing.32 Subsequently, studies of chronic ventricular pacing demonstrated asymmetric ventricular remodeling associated with the decreased wall stress in early activated myocardium and increased systolic stresses in late-activated regions.33 The prevalence of ventricular conduction delays in dilated cardiomyopathy (especially associated with left bundle branch block) and the potential to partially restore systolic function with cardiac resynchronization, have focused interest on structural remodeling associated electromechanical dysynchrony in the failing heart.34 Changes in myocardial laminar orientations during dilation and remodeling contribute to decreased myocyte number across the wall of the failing heart35 and may decrease the efficiency by which fiber shortening and transverse shears can be converted into systolic wall thickening.In this issue of Circulation Research, Helm and coworkers36 investigated whether electromechanical heterogeneity in a canine model of the dysynchronous failing heart may lead to regional alterations in myocardial fiber or sheet architecture. They performed diffusion tensor MRI in isolated perfusion-fixed dog hearts to estimate the distributions of ventricular myofiber and sheet orientations at sub-millimeter resolution without the need for laborious dissection and histology. The resulting large data sets were compared statistically between normal and dysynchronous failing groups using novel techniques from computational anatomy. Although myofiber angles were not significantly altered independent of gross geometric changes in the dysynchronous failing hearts, early-activated sites showed significant reorientation of myocardial laminae whereas there was no change in late-activated sites. This remodeling may affect regional wall mechanics and electrical conduction. Although the study of Helm and colleagues focused on the variability of regional mean fiber and sheet orientations between normal and failing subjects, there is also substantial local dispersion, especially of subendocardial sheet orientations. This should be reflected in the degree of diffusion tensor anisotropy and would be interesting to examine using these new analytical methods.On November 18th, 2005, the National Heart, Lung, and Blood Institute released a new Request for Applications (RFA-HL-06-004) for exploratory research in systems biology. The program emphasizes the use of new computational modeling techniques and experimental measurements to develop integrative analyses of complex phenotypes in heart, lung, blood, and sleep disorders. The articles in this issue of Circulation Research by Nishimura and colleagues and Helm and coworkers represent progress at the cellular and whole organ scales toward the development of predictive multi-scale models of ventricular mechanics in the normal and failing heart.The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association.This publication was supported in part by National Institutes of Health grants HL43026, HL64321, HL32583, and HL46345.FootnotesCorrespondence to Andrew McCulloch, Department of Bioengineering, 0412, La Jolla, CA 92093. E-mail [email protected] References 1 Clark KA, McElhinny AS, Beckerle MC, Gregorio CC. Striated muscle cytoarchitecture: An intricate web of form and function. Annu Rev Cell Dev Biol. 2002; 18: 637–706.CrossrefMedlineGoogle Scholar2 Simpson DG, Terracio L, Terracio M, Price RL, Turner DC, Borg TK. Modulation of cardiac myocyte phenotype in vitro by the composition and orientation of the extracellular matrix. J Cell Physiol. 1994; 161: 89–105.CrossrefMedlineGoogle Scholar3 Li D, Tapscoft T, Gonzalez O, Burch PE, Quinones MA, Zoghbi WA, Hill R, Bachinski LL, Mann DL, Roberts R. Desmin mutation responsible for idiopathic dilated cardiomyopathy. Circulation. 1999; 100: 461–464.CrossrefMedlineGoogle Scholar4 Straub V, Campbell KP. Muscular distrophies and the dystrophin-glycoprotein complex. Curr Op Neuro. 1997; 10: 168–175.CrossrefMedlineGoogle Scholar5 Ruiz P, Birchmeier W. The plakoglobin knock-out mouse: A paradigm for the molecular analysis of cardiac cell junction formation. Trends Cardiovasc Med. 1998; 8: 97–101.CrossrefMedlineGoogle Scholar6 Chien KR. Stress pathways and heart failure. Cell. 1999; 98: 555–558.CrossrefMedlineGoogle Scholar7 Seidman CE, Seidman JG. Molecular genetics of inherited cardiomyopathies. In: Chien KR, ed. Molecular Basis of Heart Disease. Philadelphia, Pa: WB Saunders Co; 1998: 251–263.Google Scholar8 Fatkin D, Graham RM. Molecular mechanisms of inherited cardiomyopathies. Physiol Rev. 2002; 82: 945–980.CrossrefMedlineGoogle Scholar9 Hein S, Scholz D, Fujitani N, Rennollet H, Brandt T, Friedl A, Schaper A. Altered expression of titin and contractile proteins in failing human myocardium. J Mol Cell Cardiol. 1994; 26: 1291–1306.CrossrefMedlineGoogle Scholar10 Towbin JA. The role of cytoskeletal proteins in cardiomyopathies. Curr Opin Cell Biol. 1998; 10: 131–139.CrossrefMedlineGoogle Scholar11 Codd MB, Sugrue DD, Gersh BJ, Melton LJ III. Epidemiology of idiopathic dilated and hypertrophic cardiomyopathy: a population-based study in Olmsted County, Minnesota 1975–1984. Circulation. 1989; 80: 564–572.CrossrefMedlineGoogle Scholar12 Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Walter P. Molecular Biology of the Cell. New York, NY: Garland Science Publishing; 2002.Google Scholar13 Arber S, Hunter JJ, Ross J, Jr., Hongo M, Sansig G, Borg J, Perriard J-C, Chien KR, Caroni P. MLP-deficient mice exhibit a disruption of cardiac cytoarchitectural organization, dilated cardiomyopathy, and heart failure. Cell. 1997; 88: 393–403.CrossrefMedlineGoogle Scholar14 Knöll R, Hoshijima M, Hoffman HM, Person V, Lorenzen-Schmidt I, Bang ML, Hayashi T, Shiga N, Yasukawa H, Schaper W, McKenna W, Yokoyama M, Schork NJ, Omens JH, McCulloch AD, Kimura A, Gregorio CC, Poller W, Schaper J, Schultheiss HP, Chien KR. The cardiac mechanical stretch sensor machinery involves a Z disk complex that is defective in a subset of human dilated cardiomyopathy. Cell. 2002; 111: 943–956.CrossrefMedlineGoogle Scholar15 Lorenzen-Schmidt I, Stuyvers BD, ter Keurs HEDJ, Date M, Hoshijima M, Chien K, McCulloch AD, Omens JH. Young MLP deficient mice show diastolic dysfunction before the onset of dilated cardiomyopathy. J Mol Cell Cardiol. 2005; 39: 241–250.CrossrefMedlineGoogle Scholar16 Gelfand VI, Bershadsky AD. Microtubule dynamics: mechanism, regulation, and function. Annu Rev Cell Biol. 1991; 7: 93–116.CrossrefMedlineGoogle Scholar17 Zile MR, Koide M, Sato H, Ishiguro Y, Conrad CH, Buckley JM, Morgan JP, Cooper G 4th. Role of microtubules in the contractile dysfunction of hypertrophied myocardium. J Am Coll Cardiol. 1999; 33: 250–260.CrossrefMedlineGoogle Scholar18 Harris TS, Baicu CF, Conrad CH, Koide M, Buckley JM, Barnes M, Cooper G, IV, Zile MR. Constitutive properties of hypertrophied myocardium: cellular contribution to changes in myocardial stiffness. Am J Physiol Heart Circ Physiol. 2002; 282: 2173–2182.CrossrefGoogle Scholar19 Yamamoto S, Tsutsui H, Takahashi M, Ishibashi Y, Tagawa H, Imanaka-Yoshida K, Saeki Y, Takeshita A. Role of microtubules in the viscoelastic properties of isolated cardiac muscle. J Mol Cell Cardiol. 1998; 30: 1841–1853.CrossrefMedlineGoogle Scholar20 Lin DH, Yin FC. A multiaxial constitutive law for mammalian left ventricular myocardium in steady-state barium contracture or tetanus. J Biomech Eng. 1998; 120: 504–517.CrossrefMedlineGoogle Scholar21 Gopalan SM, Flaim C, Bhatia S, Hoshijima M, Knöll R, Chien KR, Omens JH, McCulloch AD. Anisotropic stretch-induced hypertrophy in neonatal ventricular myocytes micropatterned on deformable elastomers. Biotechnol Bioeng. 2003; 81: 578–587.CrossrefMedlineGoogle Scholar22 Lammerding J, Huang H, So PT, Kamm RD, Lee RT. Quantitative measurements of active and passive mechanical properties of adult cardiac myocytes. IEEE Eng Med Biol Mag. 2003; 22: 124–127.CrossrefMedlineGoogle Scholar23 Waldman LK, Fung YC, Covell JW. Transmural myocardial deformation in the canine left ventricle: normal in vivo three-dimensional finite strains. Circ Res. 1985; 57: 152–163.CrossrefMedlineGoogle Scholar24 Tagawa H, Wang N, Narishige T, Ingber DE, Zile MR, Cooper G 4th. Cytoskeletal mechanics in pressure-overload cardiac hypertrophy. Circ Res. 1997; 80: 281–289.CrossrefMedlineGoogle Scholar25 Nishimura S, Nagai S, Katoh M, Yamashita H, Saeki Y, Okada JI, Hisada T, Nagai R, Sugiura S. Microtubules modulate the stiffness of cardiomyocytes against shear stress. Circ Res. 2006; 98: 81–87.LinkGoogle Scholar26 Ingber DE. Tensegrity: The architectural basis of cellular mechanotransduction. Ann Rev Physiol. 1997; 59: 575–599.CrossrefMedlineGoogle Scholar27 Omens JH, May KD, McCulloch AD. Transmural distribution of three-dimensional strain in the isolated arrested canine left ventricle. Am J Physiol. 1991; 261: H918–H928.MedlineGoogle Scholar28 Beyar R, Sideman S. The dynamic twisting of the left ventricle: a computer study. Ann Biomed Eng. 1986; 14: 547–562.CrossrefMedlineGoogle Scholar29 Tibayan FA, Rodriguez F, Langer F, Zasio MK, Bailey L, Liang D, Daughters GT, Ingels NB, Jr., Miller DC Alterations in left ventricular torsion and diastolic recoil after myocardial infarction with and without chronic ischemic mitral regurgitation. Circulation. 2004; 110: II109–II114.LinkGoogle Scholar30 LeGrice IJ, Takayama Y, Covell JW. Transverse shear along myocardial cleavage planes provides a mechanism for normal systolic wall thickening. Circ Res. 1995; 77: 182–193.CrossrefMedlineGoogle Scholar31 Ashikaga H, Criscione JC, Omens JH, Covell JW, Ingels NB Jr. Transmural mechanics underlying left ventricular torsional recoil during isovolumic relaxation. Am J Physiol Heart Circ Physiol. 2004; 286: H640–H647.CrossrefMedlineGoogle Scholar32 Waldman LK, Covell JW. Effects of ventricular pacing on finite deformation in canine left ventricles. Am J Physiol. 1987; 252: H1023–H1030.MedlineGoogle Scholar33 Prinzen FW, Cheriex EC, Delhaas T, van Oosterhout MF, Arts T, Wellens HJ, Reneman RS. Asymmetric thickness of the left ventricular wall resulting from asynchronous electric activation: a study in dogs with ventricular pacing and in patients with left bundle branch block. Am Heart J. 1995; 130: 1045–1053.CrossrefMedlineGoogle Scholar34 Kass DA Ventricular resynchronization: pathophysiology and identification of responders. Rev Cardiovasc Med. 2003; 4 (Suppl 2): S3–S13.MedlineGoogle Scholar35 Spotnitz HM, Sonnenblick EH. Structural conditions in the hypertrophied and failing heart. Am J Cardiol. 1973; 32: 398–406.CrossrefMedlineGoogle Scholar36 Helm PA, Younes L, Beg M, Ennis DB, Leclercq C, Faris OP, McVeigh E, Kass DA, Miller MI, Winslow RL Evidence of Structural Remodeling in the Dyssynchronous Failing Heart. Circ Res. 2006; 98: 125–132.LinkGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited By Göktepe S, Acharya S, Wong J and Kuhl E (2010) Computational modeling of passive myocardium, International Journal for Numerical Methods in Biomedical Engineering, 10.1002/cnm.1402, 27:1, (1-12), Online publication date: 1-Jan-2011. Dyachenko V, Christ A, Gubanov R and Isenberg G (2008) Bending of z-lines by mechanical stimuli: An input signal for integrin dependent modulation of ion channels?, Progress in Biophysics and Molecular Biology, 10.1016/j.pbiomolbio.2008.02.007, 97:2-3, (196-216), Online publication date: 1-Jun-2008. Liang J, Wang J, Azfer A, Song W, Tromp G, Kolattukudy P and Fu M (2008) A Novel CCCH-Zinc Finger Protein Family Regulates Proinflammatory Activation of Macrophages, Journal of Biological Chemistry, 10.1074/jbc.M707861200, 283:10, (6337-6346), Online publication date: 1-Mar-2008. Langer F, Rodriguez F, Cheng A, Ortiz S, Harrington K, Zasio M, Daughters G, Criscione J, Ingels N and Miller D (2007) Alterations in Lateral Left Ventricular Wall Transmural Strains During Acute Circumflex and Anterior Descending Coronary Occlusion, The Annals of Thoracic Surgery, 10.1016/j.athoracsur.2007.03.041, 84:1, (51-60), Online publication date: 1-Jul-2007. Irwin D, Helm K, Campbell N, Imamura M, Fagan K, Harral J, Carr M, Young K, Klemm D, Gebb S, Dempsey E, West J and Majka S (2007) Neonatal lung side population cells demonstrate endothelial potential and are altered in response to hyperoxia-induced lung simplification, American Journal of Physiology-Lung Cellular and Molecular Physiology, 10.1152/ajplung.00054.2007, 293:4, (L941-L951), Online publication date: 1-Oct-2007. Erbs S, Linke A, Schuler G and Hambrecht R (2006) Intracoronary Administration of Circulating Blood-Derived Progenitor Cells After Recanalization of Chronic Coronary Artery Occlusion Improves Endothelial Function, Circulation Research, 98:5, (e48-e48), Online publication date: 17-Mar-2006. Sengupta P, Korinek J, Belohlavek M, Narula J, Vannan M, Jahangir A and Khandheria B (2006) Left Ventricular Structure and Function, Journal of the American College of Cardiology, 10.1016/j.jacc.2006.08.030, 48:10, (1988-2001), Online publication date: 1-Nov-2006. BELLASI A, KOOIENGA L and BLOCK G (2006) Phosphate binders: New products and challenges, Hemodialysis International, 10.1111/j.1542-4758.2006.00100.x, 10:3, (225-234), Online publication date: 1-Jul-2006. January 6, 2006Vol 98, Issue 1 Advertisement Article InformationMetrics https://doi.org/10.1161/01.RES.0000200395.82480.8dPMID: 16397149 Originally publishedJanuary 6, 2006 Keywordscytoskeletonmicrotubulesmyocardial sheetsshearmechanotransductionPDF download Advertisement