Sequence mutations in teleost cardiac troponin C that are permissive of high Ca<sup>2+</sup> affinity of site II

Gillis, Todd E.; Cd, Moyes; Tibbits, Glen F.

doi:10.1152/ajpcell.00339.2002

Cited by 31 publications

(42 citation statements)

References 38 publications

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“…Scatchard plots of these data were used to determine K′ Ca . At 7°C, pH 7.0 the K′ Ca of the EGTA was 1.01 × 10 6 while at 30°C, pH 7.0 this value was 2.20 × 10 6 .…”

Section: Methodsmentioning

confidence: 93%

“…Position y still has a hydrophobic residue, but negative residues before (Asp 30) and after (Glu 32) may provide alternative binding, in an unusual EF-hand conformation. Titration of a number of F27W ScNTnC mutants while monitoring fluorescence has demonstrated that both Gln 29 and Asp 30 are required for F27W ScNTnC to maintain its high affinity for Ca 2+ (6). This result suggests that both of these residues are involved in conferring ScNTnC its unique Ca 2+ binding abilities.…”

Section: Discussionmentioning

confidence: 99%

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Effect of Temperature and the F27W Mutation on the Ca²⁺ Activated Structural Transition of Trout Cardiac Troponin C

et al. 2003

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The Ca 2+ sensitivity of cardiac contractile element is reduced at lower temperatures, in contrast to that in fast skeletal muscle. Cardiac troponin C (cTnC) replacement in mammalian skinned fibers showed that TnC plays a critical role in this phenomenon (Harrison and Bers, (1990), Am. J. Physiol. 258, C282-8). Understanding the differences in affinity and structure between cTnCs from cold-adapted ectothermic species and mammals may bring new insights into how the different isoforms provide different resistances to cold. We followed the Ca 2+ titration to the regulatory domain of rainbow trout cTnC by NMR (wild type at 7 and 30°C and F27W mutant at 30°C) and fluorescence (F27W mutant, at 7 and 30°C) spectroscopies. Using NMR spectroscopy, we detected Ca 2+ binding to site I of trout cTnC at high concentrations. This places trout cTnC between mammalian cTnC, in which site I is completely inactive, and skeletal TnC, in which site I binds Ca 2+ during muscle activation, and which is not as much affected by lower temperatures. This binding was seen both at 7 and at 30°C. Despite the low Ca 2+ affinity, trout TnC site I may increase the likelihood of an opening of the regulatory domain, thus increasing the affinity for TnI. This way, it may be responsible for trout cTnC's capacity to function at lower temperatures.Functional comparison of mammalian cardiac myofibrils with those isolated from trout reveal that trout cardiac myofibrils were more sensitive to Ca 2+ as reflected in their ability to generate half-maximal tension at lower [Ca 2+ ] (1). To identify the mechanisms responsible for the high sensitivity of trout cardiac myofibrils, we have cloned and sequenced cardiac troponin C (cTnC) 1 from the trout heart (ScTnC) (2). The amino acid sequence of this protein is 93% identical to mammalian (human/bovine/porcine isoform) cTnC (McTnC) (2). Using F27W mutants in fluorescence studies, we have demonstrated that site II of ScTnC has twice the Ca 2+ affinity of McTnC (3). We believe, therefore, that the higher Ca 2+ sensitivity of the trout cardiac myofilaments is a consequence of the high Ca 2+ affinity of ScTnC as it is the binding of Ca 2+ to cTnC that initiates the contractile reaction and regulates myocyte contractility.When activated by Ca 2+

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“…Scatchard plots of these data were used to determine K′ Ca . At 7°C, pH 7.0 the K′ Ca of the EGTA was 1.01 × 10 6 while at 30°C, pH 7.0 this value was 2.20 × 10 6 .…”

Section: Methodsmentioning

confidence: 93%

Section: Discussionmentioning

confidence: 99%

Effect of Temperature and the F27W Mutation on the Ca²⁺ Activated Structural Transition of Trout Cardiac Troponin C

et al. 2003

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“…Early studies revealed myofibrils from fish (Churcott et al, 1994) and frog (Harrison and Bers, 1990) heart have a greater Ca 2+ sensitivity than those from the mammalian heart. This response, at least in fish, involves greater Ca 2+ sensitivity of the fish isoform of TnC (Gillis et al, 2003). Unfortunately the length-dependent change in myofilament Ca 2+ sensitivity has not been investigated in fish.…”

Section: Troponinsmentioning

confidence: 99%

The Frank–Starling mechanism in vertebrate cardiac myocytes

Shiels

White

2008

Journal of Experimental Biology

157

107

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SUMMARY The Frank–Starling law of the heart applies to all classes of vertebrates. It describes how stretch of cardiac muscle, up to an optimum length, increases contractility thereby linking cardiac ejection to cardiac filling. The cellular mechanisms underlying the Frank–Starling response include an increase in myofilament sensitivity for Ca2+, decreased myofilament lattice spacing and increased thin filament cooperativity. Stretching of mammalian, amphibian and fish cardiac myocytes reveal that the functional peak of the sarcomere length (SL)–tension relationship occurs at longer SL in the non-mammalian classes. These findings correlate with in vivo cardiac function as non-mammalian vertebrates, such as fish,vary stroke volume to a relatively larger extent than mammals. Thus, it seems the length-dependent properties of individual myocytes are modified to accommodate differences in organ function, and the high extensibility of certain hearts is matched by the extensibility of their myocytes. Reasons for the differences between classes are still to be elucidated, however, the structure of mammalian ventricular myocytes, with larger widths and higher levels of passive stiffness than those from other vertebrate classes may be implicated.

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“…The effects of temperature acclimation on cardiac contractility in ectotherms are well documented (Keen et al, 1994;Shiels and Farrell, 1997;Aho and Vornanen, 1999) (for a review, see Driedzic and Gesser, 1994). More recent work has focused on elucidating adaptations in cardiac myocyte excitability Paajanen and Vornanen, 2004), cellular Ca 2+ cycling Harwood et al, 2000, Shiels et al, 2000Shiels et al, 2002a;Shiels et al, 2002b;Hove-Madsen et al, 2003) and protein structure (Yang et al, 2000;Gillis et al, 2000;Gillis et al, 2003) associated with maintained cardiac viability in the cold (for reviews, see Vornanen et al, 2002b;Gillis and Tibbits, 2002). Although some ectotherms cope with cold temperatures via cold-torpor and resultant reductions in metabolic rate and heart rate, there are several compensative changes often associated with ectotherms that remain active in the cold.…”

Section: Introductionmentioning

confidence: 99%

Sarcolemmal ion currents and sarcoplasmic reticulum Ca2+content in ventricular myocytes from the cold stenothermic fish, the burbot(Lota lota)

Shiels

Paajanen

Vornanen

2006

Journal of Experimental Biology

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SUMMARY The burbot (Lota lota) is a cold stenothermic fish species whose heart is adapted to function in the cold. In this study we use whole-cell voltage-clamp techniques to characterize the electrophysiological properties of burbot ventricular myocytes and to test the hypothesis that changes in membrane currents and intracellular Ca2+ cycling associated cold-acclimation in other fish species are routine for stenothermic cold-adapted species. Experiments were performed at 4°C, which is the body temperature of burbot for most of the year, and after myocytes were acutely warmed to 11°C, which is in the upper range of temperatures experienced by burbot in nature. Results on K+ channels support our hypothesis as the relative density of K-channel conductances in the burbot heart are similar to those found for cold-acclimated cold-active fish species. IK1 conductance was small (39.2±5.4 pS pF-1 at 4°C and 71.4±1.7 pS pF-1 at 11°C)and IKr was large (199±27 pS pF-1 at 4°C and 320.3±8 pS pF-1 at 11°C) in burbot ventricular myocytes. We found high Na+-Ca2+ exchange(NCX) activity (35.9±6.3 pS pF-1 at 4°C and 58.6±8.4 pS pF-1 at 11°C between -40 and 20 mV),suggesting that it may be the primary pathway for sarcolemmal (SL)Ca2+ influx in this species. In contrast, the density(ICa, 0.81±0.13 pA pF-1 at 4°C, and 1.35±0.18 pA pF-1 at 11°C) and the charge(QCa, 0.24±0.043 pC pF-1 at 4°C and 0.21±0.034 pC pF-1 at 11°C) carried by the l-type Ca2+ current was small. Our results on sarcolemmal ion currents in burbot ventricular myocytes suggest that cold stenothermy and compensative cold-acclimation involve many of the same subcellular adaptations that culminate in enhanced excitability in the cold.

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Sequence mutations in teleost cardiac troponin C that are permissive of high Ca²⁺ affinity of site II

Cited by 31 publications

References 38 publications

Effect of Temperature and the F27W Mutation on the Ca²⁺ Activated Structural Transition of Trout Cardiac Troponin C

Effect of Temperature and the F27W Mutation on the Ca²⁺ Activated Structural Transition of Trout Cardiac Troponin C

The Frank–Starling mechanism in vertebrate cardiac myocytes

Sarcolemmal ion currents and sarcoplasmic reticulum Ca2+content in ventricular myocytes from the cold stenothermic fish, the burbot(Lota lota)

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Sequence mutations in teleost cardiac troponin C that are permissive of high Ca2+ affinity of site II

Cited by 31 publications

References 38 publications

Effect of Temperature and the F27W Mutation on the Ca2+ Activated Structural Transition of Trout Cardiac Troponin C

Effect of Temperature and the F27W Mutation on the Ca2+ Activated Structural Transition of Trout Cardiac Troponin C

The Frank–Starling mechanism in vertebrate cardiac myocytes

Sarcolemmal ion currents and sarcoplasmic reticulum Ca2+content in ventricular myocytes from the cold stenothermic fish, the burbot(Lota lota)

Contact Info

Product

Resources

About

Sequence mutations in teleost cardiac troponin C that are permissive of high Ca²⁺ affinity of site II

Effect of Temperature and the F27W Mutation on the Ca²⁺ Activated Structural Transition of Trout Cardiac Troponin C

Effect of Temperature and the F27W Mutation on the Ca²⁺ Activated Structural Transition of Trout Cardiac Troponin C