Biochemical properties of membranes isolated from calcium-depleted rabbit hearts.

Lamers, Jos M. J.; Stinis, J.T.; Ruigrok, T. J. C.

doi:10.1161/01.res.54.3.217

Cited by 36 publications

(3 citation statements)

References 49 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It should be noted that Ca 2+ permeability of sarcolemmal fragments isolated from hearts subjected to the calcium paradox is not increased. 17 The present findings support our earlier hypothesis, 5 and those of Ganote et al, 7 Ashraf et al, 6 and Vander Heide et al 9 concerning the series of events leading to the final manifestation of damage associated with the Ca 2+ paradox (Table 1). Initially, on Ca 2+ repletion, cytosolic Ca 2+ increases, presumably because of a relatively small entry of Ca 2+ , probably through physiologic pathways.…”

Section: Discussionsupporting

confidence: 91%

Contracture and the calcium paradox in the rat heart.

Daly

Elz

Nayler

1987

Circulation Research

View full text Add to dashboard Cite

The role of contracture in the manifestation of calcium paradox-induced damage was examined using 2,3-butanedione monoxime (BDM) to inhibit myofibrillar activity. Calcium and sodium gain, loss of intracellular components, and changes in structure were monitored. If 30 mM BDM was added at the time of calcium repletion after 10 minutes of calcium-free perfusion, some protection was afforded, particularly at the early stages of calcium repletion. However, much greater protection was obtained if BDM was present during the final 2 minutes of calcium-free perfusion and throughout repletion. Sodium gain and loss of intracellular components were markedly attenuated, as was the incidence of severely contracted cells. Calcium gain, although significantly reduced during the period of repletion, was not abolished. After 10 minutes of repletion, a calcium content of 11.44 ± 1.57 /imol/g dry wt was observed. This suggests that other noncontracture related routes of calcium entry are involved. If BDM is removed after 5 minutes of calcium repletion and perfusion is continued with BDM-free perfusate, there is a rapid gain of sodium, further gain of calcium, loss of intracellular components and the cells contract severely, tearing away from neighboring cells. It is evident, therefore, that returning calcium to hearts after a period of calcium-free perfusion under conditions that significantly reduce the typical calcium paradox-associated damage does not necessarily repair the underlying defect. These results support the hypothesis that contracture-induced sarcolemmal disruption may be responsible for the terminal manifestation of the calcium paradox. age. More recently, Vander Heide et al 9 have produced damage similar to that of the Ca 2+ paradox using caffeine-induced contracture of Ca 2+ -free perfused hearts and have suggested that contracture is the primary mediator of sarcolemmal membrane injury in hearts with intercalated disks weakened by Ca 2+ -free perfusion. The present studies were undertaken to investigate the role of contracture in the development and expression of damage induced by the calcium paradox. 2,3-Butanedione monoxime (BDM) was used to modulate myofibrillar activity. 10BDM has a negative inotropic effect on both intact and chemically skinned cardiac muscle. 10 It has no major effect on either the electrical activity of the heart or the release of Ca 2+ from the sarcoplasmic reticulum.10 " BDM reduces the sensitivity of the myofibrils to Ca 2+ , shifting the Ca 2+ sensitivity curve to the right.l0 It also inhibits cross-bridge formation. "' 2The myofibrils, therefore, are probably the major site of BDM action. The present study investigates the effect of BDM on the manifestation of the calcium paradox by using Ca 2+ and Na + gain, loss of intracellular components, and ultrastructural changes to monitor the response. The results provide new data relating to the role of contracture in the etiology of the calcium paradox. Materials and MethodsAdult female (180-250 g) Sprague-Dawley rats were used in these stud...

show abstract

Section: Discussionsupporting

confidence: 91%

Contracture and the calcium paradox in the rat heart.

Daly

Elz

Nayler

1987

Circulation Research

View full text Add to dashboard Cite

show abstract

“…The possible routes of the initial gain in calcium include the glyocalyx, the slow channels, the Na+-Ca 2 § exchange mechanism, passive diffusion, and abnormal sites of calcium entry (7). In addition to an increased influx of calcium, a loss in the ability of the sarcolemma to remove calcium from the cells may contribute to the net gain of calcium (11). The raised cytosolic calcium may trigger a number of events leading to damage of the intercalated discs and sarcolemma, and uncontrolled influx of calcium and massive release of enzymes and other intracellular proteins (12).…”

Section: Resultsmentioning

confidence: 99%

The effect of hypothermia during the period of calcium repletion on the calcium paradox

Ruigrok¹,

Moes²,

Meer³

1986

Basic Res Cardiol

View full text Add to dashboard Cite

Reperfusion of an isolated heart with a calcium-containing solution after a short calcium-free perfusion may result in irreversible cell damage: the calcium paradox. In this investigation the effect of hypothermia during reperfusion with calcium-containing solution on the calcium paradox damage in the isolated rat heart was studied. In addition, the effect of pre-cooling the heart during the calcium-free period was investigated. Creatine kinase release was used to define cell damage. Normothermic (37 degrees C) calcium-free perfusion followed by normothermic reperfusion with calcium-containing solution resulted in a massive release of CK. When the normothermic calcium-free perfusion was followed by hypothermic (10 degrees C) calcium-containing reperfusion, CK release was reduced by 20% (P less than 0.005). This CK release during reperfusion was further reduced by 55% and 80% when the normothermic calcium-free perfusion was followed by 5 or 10 min respectively of hypothermic calcium-free perfusion prior to the hypothermic calcium-containing reperfusion. The results show that hypothermia during the period of calcium repletion retards the sequence of events which ultimately results in release of large amounts of intracellular components.

show abstract

“…Small amounts of polyamines synthesized by Ca2 -activated ODC within seconds after readmission of calcium would cause a rapid massive entry of extracellular Ca2 . In addition, an impaired capacity of calcium-depleted cells to regulate internal Ca2+ by sequestration in the sarcoplasmic reticulum (42,43) and extrusion across the sarcolemma (43,44) via their respective Ca2+ -ATPase pumps has been implicated in the phenomenon of Ca2+-intolerance, and polyamines could contribute to this mechanism. The resulting rise in free myoplasmic and intramitochondrial Ca2+ concentration would cause (a) a loss of contraction, contracture, and cellular ATP depletion resulting from Ca2+ activation ofmyosin ATPase, and (b) uncoupling of mitochondrial oxidative phosphorylation and consequent failure ofATP generation (6,45).…”

Section: Discussionmentioning

confidence: 99%

Polyamines mediate uncontrolled calcium entry and cell damage in rat heart in the calcium paradox.

Koenig

Goldstone²,

Trout³

et al. 1987

J. Clin. Invest.

View full text Add to dashboard Cite

Brief perfusion of heart with calcium-free medium renders myocardial cells calcium-sensitive so that readmission of calcium results in uncontrolled Ca2+ entry and acute massive cell injury (calcium paradox). We investigated the hypothesis that polyamines may be involved in the mediation of abnormal Ca2+ influx and cell damage in the calcium paradox. The isolated perfused rat heart was used for these studies. Calcium-free perfusion promptly (< 5 min) decreased the levels of polyamines and the activity of their rate-regulating synthetic enzyme, ornithine decarboxylase (ODC), and calcium reperfusion abruptly (< 15-180 s) increased these components. a-Difluoromethylornithine (DFMO), a specific suicide inhibitor of ODC, suppressed the calcium reperfusion-induced increase in polyamines and the concomitant increase in myocardial cellular 4"Ca influx, loss of contractility, release of cytosolic enzymes, myoglobin, and protein, and structural lesions. Putrescine, the product of ODC activity, nullified DFMO inhibition and restored the calcium reperfusion-induced increment in polyamines and the full expression of the calcium paradox. Putrescine itself enhanced the reperfusion-evoked release of myoglobin and protein in the absence of DFMO. Hypothermia blocked the changes in heart ODC and polyamines induced-by calcium-free perfusion and calcium reperfusion and prevented the calcium paradox. These results indicate that rapid Ca2+-directed changes in ODC activity and polyamine levels are essential for triggering excessive transsarcolemmal transport of Ca2" and explosive myocardial cell injury in the calcium paradox.

show abstract

Biochemical properties of membranes isolated from calcium-depleted rabbit hearts.

Cited by 36 publications

References 49 publications

Contracture and the calcium paradox in the rat heart.

Contracture and the calcium paradox in the rat heart.

The effect of hypothermia during the period of calcium repletion on the calcium paradox

Polyamines mediate uncontrolled calcium entry and cell damage in rat heart in the calcium paradox.

Contact Info

Product

Resources

About