Shortening the thick filament by partial deletion of titin's C-zone alters cardiac function by reducing the operating sarcomere length range

Titin’s C-zone is the inextensible part of titin that binds along the thick filament at its cMyBP-C -containing region. Previously it was shown that deletion of titin’s super-repeats C1 and C2 ( Ttn ΔC1-2 mouse model) results in shorter thick filaments and contractile dysfunction, but LV chamber stiffness is normal. Here we studied the contraction-relaxation kinetics from the time-varying elastance of the left ventricle (LV) and from cellular work loops of intact loaded cardiac myocytes. Ca 2+ transients were also measured as well as crossbridge cycling kinetics and Ca 2+ sensitivity of force. It was found that intact cardiomyocytes of Ttn ΔC1-2 mice exhibit systolic dysfunction and impaired relaxation. The time-varying elastance of the LV chamber showed that the kinetics of LV activation are normal but that relaxation is slower in Ttn ΔC1-2 mice. The slowed relaxation was, in part, attributable to an increased myofilament Ca 2+ sensitivity and slower early Ca 2+ reuptake. Dynamic stiffness at the myofilament level showed that cross-bridge kinetics are normal, but that the number of force-generating cross-bridges is reduced. In vivo sarcomere length (SL) measurements in the mid-wall region of the LV revealed that the operating SL range is shifted in Ttn ΔC1-2 mice towards shorter lengths. This normalizes the apparent cell and LV chamber stiffness but reduces the number of force generating cross-bridges due to suboptimal thin and thick filament overlap. Thus the contractile dysfunction in Ttn ΔC1-2 mice is not only due to shorter thick filaments but also to a reduced operating sarcomere length range. Overall these results reveal that for normal cardiac function, thick filament length regulation by titin’s C-zone is critical.

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Psoas Muscle Architectural Design, In Vivo Sarcomere Length Range, and Passive Tensile Properties Support Its Role as a Lumbar Spine Stabilizer

Spine ◽

10.1097/brs.0b013e31821847b3 ◽

2011 ◽

Vol 36 (26) ◽

pp. E1666-E1674 ◽

Cited By ~ 24

Author(s):

Gilad J. Regev ◽

Choll W. Kim ◽

Akihito Tomiya ◽

Yu Po Lee ◽

Hossein Ghofrani ◽

...

Keyword(s):

Lumbar Spine ◽

Tensile Properties ◽

Architectural Design ◽

Sarcomere Length ◽

Psoas Muscle ◽

Length Range

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What makes skeletal muscle striated? Discoveries in the endosarcomeric and exosarcomeric cytoskeleton

AJP Advances in Physiology Education ◽

10.1152/advan.00152.2018 ◽

2018 ◽

Vol 42 (4) ◽

pp. 672-684 ◽

Cited By ~ 4

Author(s):

Jack A. Rall

Keyword(s):

Skeletal Muscle ◽

Muscle Fiber ◽

Intermediate Filament ◽

Sarcomere Length ◽

Thick Filament ◽

Skeletal Muscle Fiber ◽

Elastic Behavior ◽

Filament Length ◽

Iconic Images ◽

Elastic Protein

One of the most iconic images in biology is the cross-striated appearance of a skeletal muscle fiber. The repeating band pattern shows that all of the sarcomeres are the same length. All of the A bands are the same length and are located in the middle of the sarcomeres. Furthermore, all of the myofibrils are transversely aligned across the muscle fiber. It has been known for 300 yr that skeletal muscle is striated, but only in the last 40 yr has a molecular understanding of the striations emerged. In the 1950s it was discovered that the extraction of myosin from myofibrils abolished the A bands, and the myofibrils were no longer striated. With the further extraction of actin, only the Z disks remained. Strangely, the sarcomere length did not change, and these “ghost” myofibrils still exhibited elastic behavior. The breakthrough came in the 1970s with the discovery of the gigantic protein titin. Titin, an elastic protein ~1 µm in length, runs from the Z disk to the middle of the A band and ensures that each sarcomere is the same length. Titin anchors the A band in the middle of the sarcomere and may determine thick-filament length and thus A-band length. In the 1970s it was proposed that the intermediate filament desmin, which surrounds the Z disks, connects adjacent myofibrils, resulting in the striated appearance of a skeletal muscle fiber.

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IMMUNOHISTOCHEMICAL LOCALIZATION OF CONTRACTILE PROTEINS IN LIMULUS STRIATED MUSCLE

The Journal of Cell Biology ◽

10.1083/jcb.55.1.221 ◽

1972 ◽

Vol 55 (1) ◽

pp. 221-235 ◽

Cited By ~ 22

Author(s):

Rhea J. C. Levine ◽

Maynard M. Dewey ◽

George W. de Villafranca

Keyword(s):

Thin Filament ◽

Sarcomere Length ◽

Striated Muscle ◽

Fluorescent Antibody ◽

Thick Filament ◽

Immunohistochemical Localization ◽

Differential Staining ◽

Indirect Fluorescent Antibody ◽

The Core ◽

Lateral Margins

Limulus paramyosin and myosin were localized in the A bands of glycerinated Limulus striated muscle by the indirect horseradish peroxidase-labeled antibody and direct and indirect fluorescent antibody techniques. Localization of each protein in the A band varied with sarcomere length. Antiparamyosin was bound at the lateral margins of the A bands in long (∼ 10.0 µ) and intermediate (∼ 7.0 µ) length sarcomeres, and also in a thin line in the central A bands of sarcomeres, 7.0–∼6.0 µ. Antiparamyosin stained the entire A bands of short sarcomeres (<6.0). Conversely, antimyosin stained the entire A bands of long sarcomeres, showed decreased intensity of central A band staining except for a thin medial line in intermediate length sarcomeres, and was bound only in the lateral A bands of short sarcomeres. These results are consistent with a model in which paramyosin comprises the core of the thick filament and myosin forms a cortex. Differential staining observed using antiparamyosin and antimyosin at various sarcomere lengths and changes in A band lengths reflect the extent of thick-thin filament interaction and conformational change in the thick filament during sarcomeric shortening.

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ALTERED SARCOMERE LENGTH RANGE AFTER SURGICAL TENDON TRANSFER OF THE WRIST FLEXOR

Medicine & Science in Sports & Exercise ◽

10.1249/00005768-199505001-01265 ◽

1995 ◽

Vol 27 (Supplement) ◽

pp. S226

Author(s):

R. L. Lieber ◽

J. Fridén

Keyword(s):

Tendon Transfer ◽

Sarcomere Length ◽

Wrist Flexor ◽

Length Range

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Inotropic interventions do not change the resting state of myosin motors during cardiac diastole

The Journal of General Physiology ◽

10.1085/jgp.201812196 ◽

2018 ◽

Vol 151 (1) ◽

pp. 53-65 ◽

Cited By ~ 7

Author(s):

Marco Caremani ◽

Francesca Pinzauti ◽

Joseph D. Powers ◽

Serena Governali ◽

Theyencheri Narayanan ◽

...

Keyword(s):

Protein C ◽

Thin Filament ◽

Sarcomere Length ◽

Binding Protein ◽

Thick Filament ◽

Myosin Binding Protein ◽

Myosin Binding Protein C ◽

Filament Activation ◽

Myosin Binding ◽

Myosin Motors

When striated (skeletal and cardiac) muscle is in its relaxed state, myosin motors are packed in helical tracks on the surface of the thick filament, folded toward the center of the sarcomere, and unable to bind actin or hydrolyze ATP (OFF state). This raises the question of whatthe mechanism is that integrates the Ca2+-dependent thin filament activation, making myosin heads available for interaction with actin. Here we test the interdependency of the thin and thick filament regulatory mechanisms in intact trabeculae from the rat heart. We record the x-ray diffraction signals that mark the state of the thick filament during inotropic interventions (increase in sarcomere length from 1.95 to 2.25 µm and addition of 10−7 M isoprenaline), which potentiate the twitch force developed by an electrically paced trabecula by up to twofold. During diastole, none of the signals related to the OFF state of the thick filament are significantly affected by these interventions, except the intensity of both myosin-binding protein C– and troponin-related meridional reflections, which reduce by 20% in the presence of isoprenaline. These results indicate that recruitment of myosin motors from their OFF state occurs independently and downstream from thin filament activation. This is in agreement with the recently discovered mechanism based on thick filament mechanosensing in which the number of motors available for interaction with actin rapidly adapts to the stress on the thick filament and thus to the loading conditions of the contraction. The gain of this positive feedback may be modulated by both sarcomere length and the degree of phosphorylation of myosin-binding protein C.

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Passive Properties of the Isolated Mouse Heart: Titin, Collagen and the Working Sarcomere Length Range

Biophysical Journal ◽

10.1016/j.bpj.2010.12.2080 ◽

2011 ◽

Vol 100 (3) ◽

pp. 344a

Author(s):

Charles S. Chung ◽

Nathan E. Cromer ◽

Henk L. Granzier

Keyword(s):

Sarcomere Length ◽

Mouse Heart ◽

Length Range

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Myosin motors that cannot bind actin leave their folded OFF state on activation of skeletal muscle

The Journal of General Physiology ◽

10.1085/jgp.202112896 ◽

2021 ◽

Vol 153 (11) ◽

Author(s):

Massimo Reconditi ◽

Elisabetta Brunello ◽

Luca Fusi ◽

Marco Linari ◽

Vincenzo Lombardi ◽

...

Keyword(s):

Skeletal Muscle ◽

Binding Sites ◽

Muscle Activation ◽

Sarcomere Length ◽

Rapid Change ◽

Thick Filament ◽

Actin Binding ◽

Thin Filaments ◽

Thick Filaments ◽

Myosin Motors

The myosin motors in resting skeletal muscle are folded back against their tails in the thick filament in a conformation that makes them unavailable for binding to actin. When muscles are activated, calcium binding to troponin leads to a rapid change in the structure of the actin-containing thin filaments that uncovers the myosin binding sites on actin. Almost as quickly, myosin motors leave the folded state and move away from the surface of the thick filament. To test whether motor unfolding is triggered by the availability of nearby actin binding sites, we measured changes in the x-ray reflections that report motor conformation when muscles are activated at longer sarcomere length, so that part of the thick filaments no longer overlaps with thin filaments. We found that the intensity of the M3 reflection from the axial repeat of the motors along the thick filaments declines almost linearly with increasing sarcomere length up to 2.8 µm, as expected if motors in the nonoverlap zone had left the folded state and become relatively disordered. In a recent article in JGP, Squire and Knupp challenged this interpretation of the data. We show here that their analysis is based on an incorrect assumption about how the interference subpeaks of the M3 reflection were reported in our previous paper. We extend previous models of mass distribution along the filaments to show that the sarcomere length dependence of the M3 reflection is consistent with <10% of no-overlap motors remaining in the folded conformation during active contraction, confirming our previous conclusion that unfolding of myosin motors on muscle activation is not due to the availability of local actin binding sites.

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Nature and origin of gap filaments in striated muscle

Journal of Cell Science ◽

10.1242/jcs.100.4.809 ◽

1991 ◽

Vol 100 (4) ◽

pp. 809-814 ◽

Cited By ~ 1

Author(s):

K. Trombitas ◽

P.H. Baatsen ◽

M.S. Kellermayer ◽

G.H. Pollack

Keyword(s):

Thin Filament ◽

Sarcomere Length ◽

Striated Muscle ◽

Thick Filament ◽

Abrupt Increase ◽

Semitendinosus Muscle ◽

Thin Filaments ◽

Filament System ◽

Anchor Points ◽

High Degree

Immunoelectron microscopy was used to study the nature and origin of ‘gap’ filaments in frog semitendinosus muscle. Gap filaments are fine longitudinal filaments observable only in sarcomeres stretched beyond thick/thin filament overlap: they occupy the gap between the tips of thick and thin filaments. To test whether the gap filaments are part of the titin-filament system, we employed monoclonal antibodies to titin (T-11, Sigma) and observed the location of the epitope at a series of sarcomere lengths. At resting sarcomere length, the epitope was positioned in the I-band approximately 50 nm beyond the apparent ends of the thick filament. The location did not change perceptibly with increasing sarcomere length up to 3.6 microns. Above 3.6 microns, the span between the epitope and the end of the A-band abruptly increased, and above 4 microns, the antibodies could be seen to decorate the gap filaments. Between 5 and 6 microns, the epitope remained approximately in the middle of the gap. Even with this high degree of stretch, the label remained more or less aligned across the myofibril. The abrupt increase of span beyond 3.6 microns implies that the A-band domain of titin is pulled free of its anchor points along the thick filament, and moves toward the gap. Although this domain is functionally inextensible at physiological sarcomere length, the epitope movement in extremely stretched muscle shows that it is intrinsically elastic. Thus, the evidence confirms that gap filaments are clearly part of the titin-filament system. They are derived not only from the I-band domain of titin, but also from its A-band domain.

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Decreased thin filament density and length in human atrophic soleus muscle fibers after spaceflight

Journal of Applied Physiology ◽

10.1152/jappl.2000.88.2.567 ◽

2000 ◽

Vol 88 (2) ◽

pp. 567-572 ◽

Cited By ~ 78

Author(s):

Danny A. Riley ◽

James L. W. Bain ◽

Joyce L. Thompson ◽

Robert H. Fitts ◽

Jeffrey J. Widrick ◽

...

Keyword(s):

Soleus Muscle ◽

Thin Filament ◽

Sarcomere Length ◽

Muscle Fibers ◽

Thick Filament ◽

Thin Filaments ◽

Contraction Velocity ◽

Cross Bridge ◽

Filament Spacing

Soleus muscle fibers were examined electron microscopically from pre- and postflight biopsies of four astronauts orbited for 17 days during the Life and Microgravity Sciences Spacelab Mission (June 1996). Myofilament density and spacing were normalized to a 2.4-μm sarcomere length. Thick filament density (∼1,062 filaments/μm2) and spacing (∼32.5 nm) were unchanged by spaceflight. Preflight thin filament density (2,976/μm2) decreased significantly ( P < 0.01) to 2,215/μm2 in the overlap A band region as a result of a 17% filament loss and a 9% increase in short filaments. Normal fibers had 13% short thin filaments. The 26% decrease in thin filaments is consistent with preliminary findings of a 14% increase in the myosin-to-actin ratio. Lower thin filament density was calculated to increase thick-to-thin filament spacing in vivo from 17 to 23 nm. Decreased density is postulated to promote earlier cross-bridge detachment and faster contraction velocity. Atrophic fibers may be more susceptible to sarcomere reloading damage, because force per thin filament is estimated to increase by 23%.

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