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Editorial Giant Molecule Titin and Myocardial Stiffness Stefan Hein, MD; William H. Gaasch, MD; Jutta Schaper, MD T sarcomeres.4 Titin provides elasticity to the sarcomere and permits elastic recoil. Titin’s function is adapted by different isoforms (alternative splicing) to the specific needs of striated muscle. The most variable regions of the whole molecule represent the molecular spring of the sarcomere localized in the I-band. In cardiomyocytes, 2 titin isoforms, N2B and N2BA, are coexpressed in each sarcomere in a speciesspecific ratio. For example, N2B, the smaller and stiffer isoform, has been shown to be exclusively expressed in rat and mouse ventricles, whereas N2BA is the dominating titin found in bovine atria. Most species, however, possess a mixture of both isoforms.5 In addition to the titin-based regulation of myocardial stiffness that is important at low to intermediate sarcomere lengths, collagen-based stiffness plays a major role at sarcomere elongation. The fibrillar collagen network consists mainly of collagens I and III, which are coexpressed in a constant ratio. It is important to the mechanical properties of tissue because it builds a scaffold to keep the different cellular and noncellular compartments in order. Under certain physiological conditions, the collagens contribute to a small extent to the regulation of diastolic stiffness and sarcomere length (running as wavy chords, they prevent sarcomere lengths over 2.3 m), but they provide myocyte lateral alignment.6 Cardiac pathology is usually concerned with an increased content, ie, fibrosis, or an inappropriate degradation of collagen. This will influence left ventricular (LV) function in a variety of fields, including diastolic stiffness, nutrition, impulse propagation, arrhythmia, and dilatation resulting finally in depressed systolic function. It is important to note that quantitative changes in collagen expression are usually accompanied by a switch in collagen type and arrangement; this should be taken into consideration when describing function-structure relationships. Increased collagen will lead to an increased passive tension and myocardial stiffness.7 he beauty of the new titin hypothesis is that the heart is able to change its resting length-tension relationship under chronic stress conditions by isoform switching, thereby rehabilitating the old clinical paradigm of “diastolic tone.” The path from hypothesis to reality is rocky, however, as the articles by Wu and Neagoe in this issue of Circulation show.1,2 See pp 1333 and 1384 Wu et al found that the titin isoforms N2BA/N2B ratio was decreased from a normal ratio of 1.0 to 0.8 in the paced dog heart. Because N2B represents the isoform with stiffer elastic properties, this resulted in an increased passive stiffness in isolated muscle strips. The authors suggest that this “titin-based” stiffness is acting in concert with “collagenbased” stiffness and that it may counteract ventricular dilatation in canine hearts failing because of chronic pacing. The results are somewhat in contrast with an earlier study by the same group in which a switch to the more extensible isoform N2BA was shown to occur in the subendocardium of canine hearts after 2 weeks of pacing. This seemingly contradictory result might reflect a different time course of titin isoform expression.3 Neagoe et al2 report a titin isoform shift from 30:70 (ratio 0.42) of N2BA/N2B in normal human myocardium to 47:53 (ratio 0.89) in nonischemic regions from human hearts transplanted because of coronary artery disease (CAD). Total passive tension was reduced in CAD compared with control, indicating a more compliant behavior of the myocardium. The authors, referring to the well-known increase in cardiac stiffness due to collagen in chronic heart failure, hypothesize that this isoform shift occurs to counteract the global stiffening caused by chronic preload elevation in CAD patients. 1 Downloaded from http://circ.ahajournals.org/ by guest on June 16, 2017 Titin and Collagen The giant molecule titin, the “third sarcomeric filament system,” is the third most abundant (10%) of the cardiac proteins, after myosin (40%) and actin (22%). Spanning as one molecule from the Z-line to the M-band, it is indispensable in the structural integrity of developing and mature LV Chamber Stiffness The pacing-induced tachycardia model of heart failure produces a dilated cardiomyopathy with little or no change in LV mass. Over a period of several weeks, the end-diastolic volume/mass (or radius/thickness) ratio increases, and despite substantial remodeling and enlargement of the ventricle, which might suggest a decrease in chamber stiffness, most studies indicate that the slope of the end-diastolic pressurevolume curve remains normal or near normal. The stiffness of a unit of the LV wall (defined by myocardial stress-strain relations) has been found to be normal by some investigators and increased by others. It is difficult to reconcile these disparate findings except to say that different experimental models and different periods of pacing might be responsible.8 –10 Unfortunately, Wu et al1 did not correlate their findings with measurements of ventricular volume, mass, The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association. From the Department of Thoracic and Cardiaovascular Surgery, Kerckhoff-Clinic, Bad Nauheim, Germany (S.H.); the Department of Cardiovascular Medicine, Lahey Clinic, Burlington, Mass (W.H.G.); and the Department of Experimental Cardiology, Max-Planck-Institute, Bad Nauheim, Germany (J.S.). Correspondence to Jutta Schaper, MD, Max-Planck-Institute, Department of Experimental Cardiology, Benekestr 2, D-61231 Bad Nauheim, Germany. E-mail [email protected] (Circulation. 2002;106:1302-1304.) © 2002 American Heart Association, Inc. Circulation is available at http://www.circulationaha.org DOI: 10.1161/01.CIR.0000031760.65615.3B 1302 Hein et al Downloaded from http://circ.ahajournals.org/ by guest on June 16, 2017 function, or structure in their pacing model. Changes in the stiffness of the ventricle and the myocardium are thought to be mediated largely by alterations in the collagenous matrix that surrounds the cardiomyocyte. Wu et al1 suggest that the large intrasarcomeric protein titin also plays a role in determining ventricular stiffness. It should be emphasized, however, that Wu et al1 stated that increased passive tension of the myocardium from failing hearts was the result of a “coordinated change in both collagen and titin, with titin dominating at short to intermediate sarcomere lengths and collagen at long sarcomere lengths.” Because end-diastolic sarcomere lengths in failing hearts are likely to be intermediate to long, LV size and geometry must be affected primarily by the collagenous matrix, with titin playing a lesser role. The results of any study of the physical properties of the ventricle are likely to be influenced by the nature of the experimental model of heart failure as well as the duration of the pathophysiological process. It is possible that the overall effect of many interdependent and interacting factors is to facilitate a dissolution of the extracellular matrix and allow an early chamber dilatation, which is similar to the result seen in mitral regurgitation.11 During this change in ventricular geometry, titin limits sarcomere overstretch. Later, a “coordinated change in both collagen and titin” might act to limit further ventricular dilatation. The study by Neagoe et al,2 though carried out in human hearts, is hampered by the fact that patients with CAD represent an extremely variable cohort. The fact that hemodynamic data were available from only 2 CAD patients makes it difficult to draw definitive conclusions as to changes of chamber stiffness. The authors tried to compensate for the lack of clinical information by providing data on cardiac troponin J modifications as an indicator of preload. This, however, is extremely artificial because this information was obtained from short-time ischemia experiments in Langendorff perfused isolated rat hearts, a situation far removed from that in ischemic human hearts. Nonischemic regions from CAD hearts were found to show decreased total muscle strip stiffness, which is proposed to counteract the global stiffening caused by chronic preload elevation. The functional consequences of an increased ventricular stiffness include a limitation in the degree of enlargement of the failing heart. This limitation protects the ventricle against serious rises in systolic wall stresses and thereby attenuates the downward spiral of progressive afterload excess and systolic dysfunction. On the other hand, it should be recognized that chamber dilatation provides a mechanism for maintaining an adequate stroke volume in the presence of a low ejection fraction. This is in contrast to the “nonstructural dilatation,” which was described as the consequence of volume overload without renin-angiotensin-aldosterone system activation.8 Excessive stiffness may actually prevent dilatation and result in a decline in stroke volume. Thus, an early chamber enlargement may be a beneficial adaptation to depressed myocyte and ventricular contractile function. Later, a stiffening effect might prevent progressive ventricular dilatation, but excessive stiffening is maladaptive. Giant Molecule Titin and Myocardial Stiffness 1303 Pacing-Induced Failure The model of chronic high-rate pacing in dog or pig hearts seems to resemble the situation in failing human hearts, but its experimental period is short and the structural phenotype is most probably different. In failing human hearts with dilated cardiomyopathy, a considerable amount of fibrosis is present (up to 40% versus 10% in normal human hearts). Furthermore, myocyte degeneration with reduction of contractile material and titin occurs, and cell death and loss of myocytes are common.12 This may leave the titin/myosin heavy chain quotient seemingly unaltered, when in fact absolute values may be significantly reduced. In pacing-induced dilated cardiomyopathy with heart failure, the structural situation is not clear. One group reported massive loss of myocytes and significant replacement fibrosis,13 whereas others observed either a reduction of the collagen fraction14 or collagen nonuniformity.9 Weber et al8 concluded that ventricular dilatation and failure after pacing are on the basis of an architectural remodeling of the myocardium, termed “structural dilatation.” Wu et al1,15 did not report any changes in LV collagen content, which makes interpretation of their data difficult.15 They assume that only a slight increase in collagen occurs and that a change in the collagen type I/III ratio may explain increased collagen-based stiffness. Measurements of the absolute content of both collagen and titin will provide data useful for the estimation of LV total stiffness. This needs to be established in future studies. Studies in the Human Heart Neagoe et al2 present measurements in patients with normal hearts and in those with CAD. The tissue samples were from the midmyocardium, as in the study by Wu et al.1 The decrease of total muscle strip stiffness correlated with a shift toward more N2BA, a result opposite from that obtained by Wu et al.1 This result was confirmed in rat right ventricles with LV infarction. Collagen-based stiffness was not determined. On the other hand, they claimed that collagen was increased on the basis of immunofluorescent histological pictures that showed a very small area of myocardium rather than on quantitative evaluation. Because studies of the myocyte structure are lacking as well, it is difficult to put this work into perspective. Discrepancy of Results It is interesting to compare the conclusions of these 2 studies. Wu et al1 show a contribution to myocardial stiffness by an isoform shift toward N2B, and Neagoe et al2 propose the concept that the shift toward N2BA is an attempt to counteract the global stiffening induced by collagen/desmin accumulation. Why these 2 studies, carried out by researchers who used the same methods and who published together in previous years,16 present divergent results is difficult to explain. Discrepancies may have been caused by multiple factors, including appropriateness of the pacing model and of rat myocardial infarction, species differences, and heterogeneity of human pathology. 1304 Circulation September 10, 2002 The shift to the stiffer titin isoform N2B described by Wu et al1 may possibly be explained as a response to the sudden and significant up-regulation of heart rate by pacing. This may be similar to the situation in small rodents with a high beating frequency that show an almost exclusive N2B expression.5 Importance of the Present Studies and Perspectives Downloaded from http://circ.ahajournals.org/ by guest on June 16, 2017 The studies in the present issue by Wu et al1 and Neagoe et al2 are important because they show that an isoform shift of titin occurs under pathophysiological situations of cardiac overload. The authors of both studies are well-known pioneers and experts in the field of titin, having clarified most of the major issues about this interesting molecule, including complete sequencing and multiple functional properties.17,18 We hope that the discrepancies of results will soon be reconciled, and the relationship between disturbed (Wu et al1) or tentatively preserved (Neagoe et al2) diastolic function and isoform shifts of titin will be clarified. The results could bring an improved understanding of the mechanisms underlying systolic and diastolic heart failure in human beings. References 1. Wu Y, Bell SP, Trombitas K, et al. Changes in titin isoform expression in pacing-induced cardiac failure give rise to increased passive muscle stiffness. Circulation. 2002;106:1384 –1389. 2. Neagoe C, Kulke M, del Monte F, et al. Titin isoform switch in ischemic human heart disease. Circulation. 2002;106:1333–1341. 3. Bell SP, Nyland L, Tischler MD, et al. Alterations in the determinants of diastolic suction during pacing tachycardia. Circ Res. 2000;87:235–240. 4. Labeit S, Kolmerer B, Linke WA. The giant protein titin: emerging roles in physiology and pathophysiology. Circ Res. 1997;80:290 –294. 5. Cazorla O, Freiburg A, Helmes M, et al. Differential expression of cardiac titin isoforms and modulation of cellular stiffness. Circ Res. 2000;86:59 – 67. 6. Hanley PJ, Young AA, LeGrice IJ, et al. 3-Dimensional configuration of perimysial collagen fibres in rat cardiac muscle at resting and extended sarcomere lengths. J Physiol. 1999;517:831– 837. 7. Weber KT. Targeting pathological remodeling: concepts of cardioprotection and reparation. Circulation. 2000;102:1342–1345. 8. Weber KT, Pick R, Silver MA, et al. Fibrillar collagen and remodeling of dilated canine left ventricle. Circulation. 1990;82:1387–1401. 9. Neumann T, Vollmer A, Schaffner T, et al. Diastolic dysfunction and collagen structure in canine pacing-induced heart failure. J Mol Cell Cardiol. 1999;31:179 –192. 10. Solomon SB, Nikolic SD, Glantz SA, et al. Left-ventricular diastolic function of remodeled myocardium in dogs with pacing-induced heart failure. Am J Physiol. 1998;43:H945–H954. 11. Gaasch WH, Aurigemma GP. Inhibition of the renin-angiotensin system and the left ventricular adaptation to mitral regurgitation. J Am Coll Cardiol. 2002;39:1380 –1383. 12. Schaper J, Froede R, Hein S, et al. Impairment of the myocardial ultrastructure and changes of the cytoskeleton in dilated cardiomyopathy. Circulation. 1991;83:504 –514. 13. Kajstura J, Zhang X, Liu Y, et al. The cellular basis of pacing-induced dilated cardiomyopathy: myocyte cell loss and myocyte cellular reactive hypertrophy. Circulation. 1995;92:2306 –2317. 14. Spinale FG, Coker ML, Thomas CV, et al. Time-dependent changes in matrix metalloproteinase activity and expression during the progression of congestive heart failure: relation to ventricular and myocyte function. Circ Res. 1998;82:482– 495. 15. Wu Y, Cazorla O, Labeit D, et al. Changes in titin and collagen underlie diastolic stiffness diversity of cardiac muscle. J Mol Cell Cardiol. 2000; 32:2151–2162. 16. Linke WA, Granzier H. A spring tale: new facts on titin elasticity. Biophys J. 1998;75:2613–2614. 17. Labeit S, Kolmerer B. Titins: giant proteins in charge of muscle ultrastructure and elasticity. Science. 1995;270:293–296. 18. Yamasaki R, Wu Y, McNabb M, et al. Protein kinase A phosphorylates titin’s cardiac-specific N2B domain and reduces passive tension in rat cardiac myocytes. Circ Res. 2002;90:1181–1188. KEY WORDS: Editorials 䡲 proteins 䡲 myocardium Giant Molecule Titin and Myocardial Stiffness Stefan Hein, William H. Gaasch and Jutta Schaper Circulation. 2002;106:1302-1304 doi: 10.1161/01.CIR.0000031760.65615.3B Downloaded from http://circ.ahajournals.org/ by guest on June 16, 2017 Circulation is published by the American Heart Association, 7272 Greenville Avenue, Dallas, TX 75231 Copyright © 2002 American Heart Association, Inc. All rights reserved. Print ISSN: 0009-7322. 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