X-ray diffraction from flight muscle with a headless myosin mutation: implications for interpreting reflection patterns.

Fruit fly (Drosophila melanogaster) is one of the most useful animal models to study the causes and effects of hereditary diseases because of its rich genetic resources. It is especially suitable for studying myopathies caused by myosin mutations, because specific mutations can be induced to the flight muscle-specific myosin isoform, while leaving other isoforms intact. Here we describe an X-ray-diffraction-based method to evaluate the structural effects of mutations in contractile proteins in Drosophila indirect flight muscle. Specifically, we describe the effect of the headless myosin mutation, Mhc (10) -Y97, in which the motor domain of the myosin head is deleted, on the X-ray diffraction pattern. The loss of general integrity of the filament lattice is evident from the pattern. A striking observation, however, is the prominent meridional reflection at d = 14.5 nm, a hallmark for the regularity of the myosin-containing thick filament. This reflection has long been considered to arise mainly from the myosin head, but taking the 6th actin layer line reflection as an internal control, the 14.5-nm reflection is even stronger than that of wild-type muscle. We confirmed these results via electron microscopy, wherein image analysis revealed structures with a similar periodicity. These observations have major implications on the interpretation of myosin-based reflections.

Cellular and molecular mechanisms of systolic and diastolic dysfunction in an avian model of dilated cardiomyopathy.

We investigated the cellular and molecular mechanisms of systolic and diastolic dysfunction in a furazolidone (Fz)-induced model of dilated cardiomyopathy (DCM) in turkey poults. Serial echocardiograms disclosed marked systolic dysfunction in the Fz-treated poults, and ventricular weight and left ventricular (LV)/body weight ratio were significantly increased. Isolated heart experiments were performed to determine LV pressure-volume (P-V) relationships. In addition, LV sarcomere lengths (SLs) were measured after hearts had been fixed, and wall stress (sigma)-SL relationships were determined. When compared to control hearts, LV chamber volume in DCM hearts was approximately 3-fold increased, the active or developed LV P-V relationship was markedly depressed, the passive or diastolic P-V relationship was steeper, and SLs were significantly shorter. However, the developed sigma-SL relationships of DCM and control hearts were not different indicating that intrinsic myocardial capacity to generate active force is unaffected in this model of DCM. In contrast, passive sigma, and passive tension in trabecular muscle preparations increased much more steeply with SL in DCM than normal hearts. Trabecular muscle experiments disclosed that the increase in passive myocardial stiffness was primarily collagen based. Titin, the giant sarcomeric molecule, which is an important determinant of passive myocyte properties in normal myocardium, did not contribute significantly to increased passive myocardial stiffness in DCM. We conclude that increased collagen-based passive myocardial stiffness is the major cause of the steeper passive or diastolic P-V relationship in DCM. Further, altered passive myocardial properties and ventricular geometry in DCM play a critical role to reduce ventricular systolic function by limiting SL extension during diastole, thereby limiting the use of the myocardial length-tension relationship.

Changes in titin isoform expression in pacing-induced cardiac failure give rise to increased passive muscle stiffness.

BACKGROUND: Titin contains a molecular spring segment that underlies passive myocardial stiffness. Myocardium coexpresses titin isoforms with molecular spring length variants and, consequently, distinct stiffness characteristics: the stiff N2B isoform (short spring) and more compliant N2BA isoform (long spring). We tested whether changes in titin isoform expression occur in the diastolic dysfunction that accompanies heart failure. METHODS AND RESULTS: We used the tachycardia-induced dilated cardiomyopathy canine model (4-week pacing) and found that control myocardium coexpresses the N2B and N2BA isoforms at similar levels, whereas in dilated cardiomyopathy the expression ratio had shifted, without affecting the amount of total titin, toward more prominent N2B expression. This shift was accompanied by elevated titin-based passive muscle stiffness. Pacing also resulted in significant upregulation of obscurin, an approximately 800-kDa elastic protein with several signaling domains. CONCLUSIONS: Coexpression of titin isoforms with distinct mechanical properties allows modulation of passive stiffness via adjustment of the isoform expression ratio. The canine pacing-induced heart failure model uses this mechanism to increase myocardial stiffness. Thus, changes in titin isoform expression may play a role in diastolic dysfunction in heart failure.

Mutations of TTN, encoding the giant muscle filament titin, cause familial dilated cardiomyopathy.

Congestive heart failure (CHF) can result from various disease states with inadequate cardiac output. CHF due to dilated cardiomyopathy (DCM) is a familial disease in 20-30% of cases and is associated with mutations in genes encoding cytoskeletal, contractile or inner-nuclear membrane proteins. We show that mutations in the gene encoding giant-muscle filament titin (TTN) cause autosomal dominant DCM linked to chromosome 2q31 (CMD1G; MIM 604145). Titin molecules extend from sarcomeric Z-discs to M-lines, provide an extensible scaffold for the contractile machinery and are crucial for myofibrillar elasticity and integrity. In a large DCM kindred, a segregating 2-bp insertion mutation in TTN exon 326 causes a frameshift, truncating A-band titin. The truncated protein of approximately 2 mD is expressed in skeletal muscle, but western blot studies with epitope-specific anti-titin antibodies suggest that the mutant protein is truncated to a 1.14-mD subfragment by site-specific cleavage. In another large family with DCM linked to CMD1G, a TTN missense mutation (Trp930Arg) is predicted to disrupt a highly conserved hydrophobic core sequence of an immunoglobulin fold located in the Z-disc-I-band transition zone. The identification of TTN mutations in individuals with CMD1G should provide further insights into the pathogenesis of familial forms of CHF and myofibrillar titin turnover.