Mechanism of Calcium Release from Skeletal Muscle Sarcoplasmic Reticulum

Buck, Edmond

01 January 1993

The sarcoplasmic reticulum (SR) is an intracellular membrane system dedicated to the active regulation of cytosolic calcium in muscle. The opening of Ca²⁺ channels in the SR results in a rapid increase in the myoplasmic Ca²⁺ concentration and the initiation of contraction. Closure of these channels allows the SR to re-accumulate the released Ca²⁺ which results in muscle relaxation. While it is known that a muscle fiber is stimulated to contract by the depolarization of the sarcolemma, it is not understood how this signal is communicated to the SR. The focus of this dissertation is twofold. The first objective is to gain an understanding of the mechanism of Ca²⁺ release from the SR. To this end, three studies have been performed which indicate that Ca²⁺ release is mediated by an oxidation reaction. The second goal is to gain insight into the function of the Ca²⁺ release channel. This is addressed by a fourth study which characterizes the effect of the plant alkaloid, ryanodine on channel operation. The anthraquinones mitoxantrone , doxorubicin, daunorubicin, and rubidazone are shown to be potent stimulators of Ca²⁺ release from SR vesicles. Anthraquinoneinduced Ca²⁺ release is shown to be via a specific interaction with the Ca²⁺ release system of the SR. In addition, a strong interaction between anthraquinone and caffeine binding sites on the Ca²⁺ release channel is observed when monitoring Ca²⁺ fluxes across the SR. It is shown that Ca²⁺ release stimulated by anthraquinones is inhibited by preincubating the quinone with dithionite, a strong reducing agent. Spectrophotometric measurements show that the dithionite treated quinone is in a reduced state. Previous work in this lab has shown that the photooxidizing xanthene dye rose bengal stimulates rapid Ca²⁺ release from skeletal muscle SR vesicles. In this thesis, it is shown that following fusion of vesicles to a bilayer lipid membrane (BLM), Ca²⁺ channel activity is stimulated by nanomolar concentrations of rose bengal in the presence of a broad-spectrum light source. This stimulation is shown to be independent of the Ca²⁺ concentration but is inhibited by μM ruthenium red. The photooxidation of rose bengal is shown to not affect either the K+ or Cl- channels which are present in the SR. Exposure of the Ca²⁺ release channel to 500 nM rose bengal in the presence of light is shown to reverse the modification to the channel induced by μM ryanodine. This apparent displacement of bound ryanodine by nanomolar concentrations of rose bengal is directly observed upon measurement of [³H]ryanodine binding to TSR vesicles. Evidence is presented which suggests that Ca²⁺ release is mediated by singlet oxygen. Micromolar concentrations of the porphyrin meso-Tetra(4-N-methylpyridyl)porphine tetraiodide (TMPyP) is shown to induce the rapid release of Ca²⁺ from skeletal muscle SR vesicles. Porphyrin-induced Ca²⁺ release is stimulated by adenine nucleotides and μM Ca²⁺, and is inhibited by mM Mg²⁺ and μM ruthenium red. High-affinity [³H]ryanodine binding is also enhanced in the presence of the porphyrin. The presence of 1 mM Mg²⁺ in the assay medium sensitizes ryanodine binding to activation by ca²⁺. Porphyrin stimulated single channel activity is also sensitized to activation by Ca²⁺ in the presence of Mg²⁺. Reduction of the porphyrin by dithionite, a strong reducing agent, prior to exposure to the Ca²⁺ release channel inhibited the ability of TMPyP to stimulate Ca²⁺ release. These observations indicate that anthraquinones, rose bengal , and porphyrins induce a stimulation of the Ca²⁺ release protein from skeletal muscle SR by interacting with the ryanodine binding site. In addition, the mechanism of interaction for these compounds appears to be via an oxidation reaction. Nanomolar to micromolar concentrations of ryanodine are shown to alter the gating kinetics of the Ca²⁺ release channel from skeletal muscle SR fused with bilayer lipid membranes. In the presence of asymmetric CsCl, 5 to 40 nM concentrations of ryanodine are shown to activate the channel by increasing the open probability (P₀) without changing the conductance. Statistical analysis of gating kinetics reveal that the open and closed dwell times exhibit bi-exponential distributions that are significantly modified by nM ryanodine. The altered channel gating kinetics seen with low nM ryanodine is reversible and is shown to correlate with the binding kinetics of [³H]ryanodine with its highest affinity site under identical ionic conditions. Ryanodine concentrations between 20 and 50 nM are observed to induce occasional 1/2 conductance fluctuations while ryanodine concentrations greater than 50 nM stabilize the channel into a ½ conductance state which is not reversible. These results are shown to correlate with [³H]ryanodine binding to a second site having lower affinity than the first site. Ryanodine at concentrations greater than 70 μM from the 1/2 to a 1/4 conductance fluctuation , whereas ryanodine concentrations greater than 200 μM cause complete closure of the channel. The concentration of ryanodine required to stabilize either the 1/4 conductance transitions or channel closure do not directly correlate with the measured [³H]ryanodine equilibrium binding constants. However, these results can be explained by considering the association kinetics of ryanodine concentrations greater than 200 nM in the presence of 500 mM CsCl. These results indicate that ryanodine stabilizes four discrete states of the SR release channel and supports the existence of multiple interacting ryanodine binding sites on the channel protein.

Calcium channels

Sarcoplasmic reticulum

Calcium in the body

Chemical Modification of Skeletal Muscle Sarcoplasmic Reticulum Vesicles: A Study of Calcium Permeability

Stuart, Janice F.

01 January 1989

Skeletal muscle contains an internal membrane system called the sarcoplasmic reticulum (SR) whose function is to regulate the Ca2+ concentration of the myoplasm. Ca2+ is transported into the SR from the myoplasm via a Ca2+ dependent ATPase thus lowering the myoplasmic Ca2+ concentration. Ca2+ exits from the SR via a Ca2+ releqse pathway resultingin the increase of myoplasmic Ca2+. Muscles contract when the myoplasmic Ca2+ concentration is > 5 uM and relax when the Ca2+ concentration is lowered below 1 uM. The Ca2+ dependent ATPase has been extensively studied but the Ca2+ release system is less well understood. SR vesicles release their internal Ca2+ when a reactive thiol group is oxidized (oxidation-induced Ca2+ release). It is shown in this dissertation that oxidation-induced Ca2+ release is stimulated by adenine nucleotides with an order of effectiveness of: ATP > AMP-PCP > cAMP > AMP > adenine. The stimulatory effect is not dependent upon phosphorylation of a protein because AMP-PCP, a nonhydrolyzable analogue of ATP, is almost as effective as ATP in stimulating oxidation-induced Ca2+ release. It is also shown in this dissertation that photooxidation of histidyl residues results in an increase Ca2+ permeability of the SR. Unlike oxidation-induced Ca2+ release, photooxidation-induced Ca2+ release is Mg2+ independent, not inhibited by ruthenium red and inhibited by adenine nucleotides. Covalent modification of histidyl residues with ethoxyformic anhydride results in the increased permeability of SR vesicles. Similar to photooxidation-induced Ca2+ efflux, EFA-induced Ca2+ efflux is Mg2+ independent and is inhibited by ATP. The AMP-PCP protection of SR proteins from modification with EFA is similar to non-competitive inhibition with a KI = 50 uM. The photooxidation effect is not on membrane lipids but on a protein component which may be an ion transport system, other than the Ca2+ release protein, altered in such a way that it now transports Ca2+.

Sarcoplasmic reticulum

Calcium in the body

Environmental Chemistry

Effects of sodium chloride supplementation on urinary calcium, other urine and blood electrolytes and parathyroid hormone levels in postmenopausal women

Zarkadas, Marion

January 1988

No description available.

Sodium in the body.

Calcium in the body.

Menopause.

Women -- Nutrition.

Calcium and phosphorus excretions of nine college women consuming normal food and semisynthetic diets /

Marshall, Nancy Jane

January 1961

No description available.

Home Economics

Calcium in the body

Phosphorus in the body

Calcium intake, physical activity, and bone mineral status in children and youth aged ten to fifteen years

Hall, Matthew Charles, 1960-

January 1988

This study was conducted to determine if either calcium intake or physical activity is related to bone mineral status in children and youth aged 10 to 15 years. Subjects (n = 30) with high, medium, and low bone mineral status were selected based on radius bone mineral index measurements from a sample of 108 subjects measured 9 to 12 months previously. Calcium intake was estimated from two 24-hour recalls and a food frequency questionnaire. Assessment of activity level was conducted by questionnaire. Single photon absorptiometry was used to obtain bone mineral content (g/cm) and bone mineral index (g/cm²) measurements for the radius and ulna at the midshaft and distal sites. Calcium intake and activity level were found to be similar among the bone mineral index groups. Using regression analysis, however, calcium intake was shown to be significantly related to midshaft ulna bone mineral index and activity level (sports participation) was found to be significantly related to distal ulna bone mineral index.

Bone densitometry.

Exercise -- Physiological aspects.

Calcium in the body.

Biomineralization.

Effects of the Cardioprotective Drugs Dexrazoxane and ADR-925 on Doxorubicin Induced Ca2+ Release from the Sarcoplasmic Reticulum

Herzinger, Thomas Andreas

08 November 1996

The sarcoplasmic reticulum is the intramuscular organelle responsible for the regulation of cytoplasmic calcium levels in muscle. This thesis investigates the effects of the cardioprotective drug, dexrazoxane, and its metabolite ADR-925 on doxorubicin induced calcium release from skeletal sarcoplasmic reticulum. Doxorubicin is a widely used antineoplastic agent. One of the major side effects of doxorubicin usage is chronic cardiotoxicity. Doxorubicin is a potent activator of the calcium release mechanism from the SR. The interaction between doxorubicin and the calcium release channel has been proposed as the possible underlying mechanism behind cardiotoxicity. A short overview of different hypotheses describing doxorubicin induced cardiotoxicity and proposed mechanisms of cardioprotection by dexrazoxane are presented. While dexrazoxane did not appear to affect the calcium permeability of the SR, its metabolite, ADR-925, modulates the ryanodine receptor complex. ADR-925 inhibits high affinity ryanodine binding to the ryanodine receptor/calcium release channel complex by decreasing the sensitivity of the receptor for stimulation by calcium. ADR-925's ability to inhibit doxorubicin stimulated ryanodine binding is independent of the doxorubicin concentration. These results demonstrate that ADR-925 directly affects the ryanodine receptor complex of the SR by desensitizing the receptor to activation by calcium. Furthermore, ADR-925 reduces the inhibitory effect of hydrogen peroxide on the ryanodine receptor/ calcium release channel. This suggests that ADR-925 may protect the SR from oxidative effects of free radicals. It has been somewhat controversial whether doxorubicin induced cardiotoxicity is due to a specific interaction with the calcium release mechanism of SR. The findings presented in this thesis which demonstrate that the cardioprotectant ADR-925 interacts directly with the ryanodine receptor from SR, further support the hypothesis that the ryanodine receptor is a primary target of doxorubicin's action.

Doxorubicin

Calcium channels

Sarcoplasmic reticulum

Calcium in the body

Physics

Calcium study : pregnant care coordination clients

Parks, Sally A.

January 1998

There is no abstract available for this thesis. / Department of Family and Consumer Sciences

Calcium in human nutrition.

Calcium in the body.

Pregnancy -- Nutritional aspects.

Mothers -- Education.

Rapid effects of estrogen on intracellular calcium levels in adult GnRH neurons

Romano, Nicola, n/a

January 2009

The gonadotropin-releasing hormone (GnRH) neurons of the hypothalamus are the principal regulators of reproductive function and are strongly modulated by estrogen (E₂). Several studies indicate that E₂ is able to influence GnRH neurons, both with "classical" long-term transcriptional effects, and with rapid non-transcriptional effects. One most interesting action of E₂ is that of modulating intracellular calcium concentration [Ca�⁺]I: this has been shown to happen in many different cell types, including embryonic models of GnRH neurons. The aim of this project was to evaluate if these rapid effects of E₂ on [Ca�⁺]I also happen at the level of adult GnRH neurons. In order to study the acute effects of E₂ on calcium dynamics, a novel transgenic mouse line was generated, that allows real-time measurement of [Ca�⁺]I selectively in GnRH neurons in an acute brain slice preparation. Using this mouse line, our group has previously shown that these cells show spontaneous activity in the form of Ca�⁺ transients. A first set of experiments was designed to define the effects of E₂ on spontaneous activity. E₂ was found to modulate [Ca�⁺]I in a activity-dependent manner: it increased the frequency of [Ca�⁺]I transients in about 50% of GnRH neurons with low spontaneous activity, whereas it decreased the frequency of the transients in more than 80% spontaneously active GnRH neurons. Different experiments were then performed in order to determine the molecular pathways that generates these opposite effects. The inhibitory effect was reproduced by the membrane-impermeable compound E2-6-BSA, indicating that it happens through a membrane receptor. The E₂ isomer l7α-estradiol was also able to reproduce the inhibitory effect of E₂, suggesting the involvement of some non-classical receptor. This is also confirmed by the presence of this effect in estrogen-receptor β (ER-β) knock-out mice, which exclude the involvement of this receptor. The stimulatory effect was found to be generated through a novel, indirect mechanism. It cannot be reproduced by E2-6-BSA nor by l7α-estradiol, and it is still present in the ER-β knock-out mice. The stimulation, though, can be reproduced in about 50% of cells with an ER-α selective agonist. As this receptor is not present in GnRH neurons, an indirect mechanism must be generating the stimulatory effect. Blockage of action potential mediated synaptic transmission with tetrodotoxin (TTX) did not block E₂ effects, but blockage of non-action potential mediated GABAergic transmission using the GABA[A] selective blocker gabazine completely abolished them. Our hypothesis is therefore that E₂ stimulates the generation of [Ca�⁺]I transients through estrogen-receptor a (ER-α) located in the terminals of GABAergic afferents. This modulation, in turn, is able to determine release of Ca�⁺ from IP₃-sensitive intracellular stores. To confirm this, we applied exogenous GABA to the neurons and found that it was able to initiate [Ca�⁺]I transients. Furthermore, removal of tonic GABAergic tone with gabazine was able to block spontaneous activity. To further analyse the effects of E₂, Ca�⁺ imaging experiments were performed together with cell-attached patch clamp electrophysiological recordings in order to correlate the electrical activity with the calcium activity. Simultaneous recordings revealed a strong correlation between [Ca�⁺]I transients and bursts of action currents in adult GnRH neurons. E₂ was able to increase the electrical activity of GnRH neurons with low spontaneous activity, and inhibit that of highly active ones. Application of GABA to GnRH neurons resulted in increased firing, accompanied by an increase in [Ca�⁺]I. These observations provide evidence for a complex mechanism of E₂ action on adult GnRH neurons, that may be important for the generation of the pulsatile release of this hormone.

estrogen

metabolism

calcium in the body

luteinizing hormone releasing hormone

Rapid effects of estrogen on intracellular calcium levels in adult GnRH neurons

Romano, Nicola, n/a

January 2009

The gonadotropin-releasing hormone (GnRH) neurons of the hypothalamus are the principal regulators of reproductive function and are strongly modulated by estrogen (E₂). Several studies indicate that E₂ is able to influence GnRH neurons, both with "classical" long-term transcriptional effects, and with rapid non-transcriptional effects. One most interesting action of E₂ is that of modulating intracellular calcium concentration [Ca�⁺]I: this has been shown to happen in many different cell types, including embryonic models of GnRH neurons. The aim of this project was to evaluate if these rapid effects of E₂ on [Ca�⁺]I also happen at the level of adult GnRH neurons. In order to study the acute effects of E₂ on calcium dynamics, a novel transgenic mouse line was generated, that allows real-time measurement of [Ca�⁺]I selectively in GnRH neurons in an acute brain slice preparation. Using this mouse line, our group has previously shown that these cells show spontaneous activity in the form of Ca�⁺ transients. A first set of experiments was designed to define the effects of E₂ on spontaneous activity. E₂ was found to modulate [Ca�⁺]I in a activity-dependent manner: it increased the frequency of [Ca�⁺]I transients in about 50% of GnRH neurons with low spontaneous activity, whereas it decreased the frequency of the transients in more than 80% spontaneously active GnRH neurons. Different experiments were then performed in order to determine the molecular pathways that generates these opposite effects. The inhibitory effect was reproduced by the membrane-impermeable compound E2-6-BSA, indicating that it happens through a membrane receptor. The E₂ isomer l7α-estradiol was also able to reproduce the inhibitory effect of E₂, suggesting the involvement of some non-classical receptor. This is also confirmed by the presence of this effect in estrogen-receptor β (ER-β) knock-out mice, which exclude the involvement of this receptor. The stimulatory effect was found to be generated through a novel, indirect mechanism. It cannot be reproduced by E2-6-BSA nor by l7α-estradiol, and it is still present in the ER-β knock-out mice. The stimulation, though, can be reproduced in about 50% of cells with an ER-α selective agonist. As this receptor is not present in GnRH neurons, an indirect mechanism must be generating the stimulatory effect. Blockage of action potential mediated synaptic transmission with tetrodotoxin (TTX) did not block E₂ effects, but blockage of non-action potential mediated GABAergic transmission using the GABA[A] selective blocker gabazine completely abolished them. Our hypothesis is therefore that E₂ stimulates the generation of [Ca�⁺]I transients through estrogen-receptor a (ER-α) located in the terminals of GABAergic afferents. This modulation, in turn, is able to determine release of Ca�⁺ from IP₃-sensitive intracellular stores. To confirm this, we applied exogenous GABA to the neurons and found that it was able to initiate [Ca�⁺]I transients. Furthermore, removal of tonic GABAergic tone with gabazine was able to block spontaneous activity. To further analyse the effects of E₂, Ca�⁺ imaging experiments were performed together with cell-attached patch clamp electrophysiological recordings in order to correlate the electrical activity with the calcium activity. Simultaneous recordings revealed a strong correlation between [Ca�⁺]I transients and bursts of action currents in adult GnRH neurons. E₂ was able to increase the electrical activity of GnRH neurons with low spontaneous activity, and inhibit that of highly active ones. Application of GABA to GnRH neurons resulted in increased firing, accompanied by an increase in [Ca�⁺]I. These observations provide evidence for a complex mechanism of E₂ action on adult GnRH neurons, that may be important for the generation of the pulsatile release of this hormone.

estrogen

metabolism

calcium in the body

luteinizing hormone releasing hormone

Modulation of odontoblast communication in vitro a thesis submitted in partial fulfillment ... for the degree of Masters [sic] Science in Endodontics ... /

Sachs, Ellen.

January 1993

Thesis (M.S.)--University of Michigan, 1993.