Clara Franzini-Armstrong

The brain ryanodine receptor: a caffeine-sensitive calcium release channel.

The release of stored Ca2+ from intracellular pools triggers a variety of important neuronal processes. Physiological and pharmacological evidence has indicated the presence of caffeine-sensitive intracellular pools that are distinct from the well-characterized inositol 1,4,5,-trisphosphate (IP3)-gated pools. Here we report that the brain ryanodine receptor functions as a caffeine- and ryanodine-sensitive Ca2+ release channel that is distinct from the brain IP3 receptor. The brain ryanodine receptor has been purified 6700-fold with no change in [3H]ryanodine binding affinity and shown to be a homotetramer composed of an approximately 500 kd protein subunit, which is identified by anti-peptide antibodies against the skeletal and cardiac muscle ryanodine receptors. Our results demonstrate that the brain ryanodine receptor functions as a caffeine-sensitive Ca2+ release channel and thus is the likely gating mechanism for intracellular caffeine-sensitive Ca2+ pools in neurons.

Casq2 deletion causes sarcoplasmic reticulum volume increase, premature Ca2+ release, and catecholaminergic polymorphic ventricular tachycardia

Cardiac calsequestrin (Casq2) is thought to be the key sarcoplasmic reticulum (SR) Ca2+ storage protein essential for SR Ca2+ release in mammalian heart. Human CASQ2 mutations are associated with catecholaminergic ventricular tachycardia. However, homozygous mutation carriers presumably lacking functional Casq2 display surprisingly normal cardiac contractility. Here we show that Casq2-null mice are viable and display normal SR Ca2+ release and contractile function under basal conditions. The mice exhibited striking increases in SR volume and near absence of the Casq2-binding proteins triadin-1 and junctin; upregulation of other Ca2+ -binding proteins was not apparent. Exposure to catecholamines in Casq2-null myocytes caused increased diastolic SR Ca2+ leak, resulting in premature spontaneous SR Ca2+ releases and triggered beats. In vivo, Casq2-null mice phenocopied the human arrhythmias. Thus, while the unique molecular and anatomic adaptive response to Casq2 deletion maintains functional SR Ca2+ storage, lack of Casq2 also causes increased diastolic SR Ca2+ leak, rendering Casq2-null mice susceptible to catecholaminergic ventricular arrhythmias.

Localization of Calcium-Accumulating Structures in Striated Muscle Fibers

When frog muscle fibers from which the sarcolemma had been dissected away were perfused with a calcium solution and then treated with oxalate, electron-opaque material, probably calcium oxalate, accumulated in the terminal sacs of the sarcoplasmic reticulum. These regions of calcium accumulation were identified with the intracellular calcium sink that controls the relaxation phase of the contraction-relaxation cycle; their proximity to tubules implicated in intracellular stimulus conduction suggests that they might also be regions from which calcium is released to trigger contraction.

The relative contributions of the folds and caveolae to the surface membrane of frog skeletal muscle fibres at different sarcomere lengths.

The plasmalemmal area of striated muscle fibres is greater than the apparent surface area (A = circumference x length) because of variable folds and the invaginations of the caveolae and T‐tubules. Freeze‐fracture replicas of the surface membrane of sartorius and semitendinosus muscles from Rana pipiens have been used to determine the numbers and distribution of folds and caveolae at different sarcomere lengths. (1) The plasmalemma folds are variable in size and shape, but are always oriented perpendicular to the long axis of the fibre. The folds vary with stretch, being more prominent at short sarcomere lengths. The caveolae are elliptical invaginations of the plasmalemma which open to the outside by a narrow “neck” of approximately 20 nm. The caveolar lumen has an average long dimension of 81.6 +/‐ 11.7 nm and an average short dimension of 66.9 +/− 7.9 nm. The caveolar “necks” only can be seen in freeze‐fracture replicas and these are distributed in two circumferential bands on either side of the Z‐line, and in longitudinal bands separated by distances of 1‐5 mum. In the sartorius muscle, at a sarcomere length of 2.8 mum, there is an average number of thirty‐seven caveolae per square micrometer of fibre surface. (2) During passive stretch the opening of folds provides membrane for the necessary increase in surface area up to a sarcomere length of about 3.0 mum. This length is defined as the critical sarcomere length (Sc). The number of caveolae remains constant at all sarcomere lengths less than Sc and thus their “necks” have been used as membrane markers to determine the amount of folding at different sarcomere lengths. The membrane area contained in folds and caveolae is expressed as a fraction of the apparent surface area (A). For example, in the sartorius muscle, at a sarcomere length of 2.4 mum, the membrane area, excluding the T‐tubules, is: A + 0.1A (folding) + 0.7A (caveolae) = 1.8A. (3) For stretch beyond Sc membrane is provided by the opening of caveolae. At a sarcomere length of about 8 mum all the caveolae are open and the fibres rupture with further stretch. (4) The relative contributions of folds and caveolae vary with sarcomere length in a way that is consistent with assumptions of constant volume and plasmalemma area. The maintenance of constant plasmalemma area, even after excessive stretch, suggests that the plasmalemma is relatively inelastic in this situation.

Transport of Ca2+ from Sarcoplasmic Reticulum to Mitochondria in Rat Ventricular Myocytes

Studies with electron microscopy have shown that sarcoplasmic reticulum (SR) andmitochondria locate close to each other in cardiac muscle cells. We investigated the hypothesis thatthis proximity results in a transient exposure of mitochondrial Ca2+ uniporter (CaUP) to highconcentrations of Ca2+ following Ca2+ release from the SR and thus an influx of Ca2+into mitochondria. Single ventricular myocytes of rat were skinned by exposing them to aphysiological solution containing saponin (0.2 mg/ml). Cytosolic Ca2+ concentration ([Ca2+]c)and mitochondrial Ca2+ concentration ([Ca2+]m) were measured with fura-2 and rhod2,respectively. Application of caffeine (10 mM) induced a concomitant increase in[Ca2+]c and [Ca2+]m.Ruthenium red, at concentrations that block CaUP but not SR release, diminished thecaffeine-induced increase in [Ca2+]m but not[Ca2+]c. In the presence of 1 mM BAPTA, a Ca2+ chelator,the caffeine-induced increase in [Ca2+]m was reduced substantially less than [Ca2+]c. Moreover,inhibition of SR Ca2+ pump with two different concentrations of thapsigargin caused anincrease in [Ca2+]m, which was related to the rate of [Ca2+]c increase. Finally, electronmicroscopy showed that sites of junctions between SR and T tubules from which Ca2+ is released,or Ca2+ release units, CRUs, are preferentially located in close proximity to mitochondria.The distance between individual SR Ca2+ release channels (feet or ryanodine receptors) isvery short, ranging between approximately 37 and 270 nm. These results are consistent withthe idea that there is a preferential coupling of Ca2+ transport from SR to mitochondria incardiac muscle cells, because of their structural proximity.

Tomographic 3D Reconstruction of Quick-Frozen, Ca2+-Activated Contracting Insect Flight Muscle

Motor actions of myosin were directly visualized by electron tomography of insect flight muscle quick-frozen during contraction. In 3D images, active cross-bridges are usually single myosin heads, bound preferentially to actin target zones sited midway between troponins. Active attached bridges (approximately 30% of all heads) depart markedly in axial and azimuthal angles from Rayments rigor acto-S1 model, one-third requiring motor domain (MD) tilting on actin, and two-thirds keeping rigor contact with actin while the light chain domain (LCD) tilts axially from approximately 105 degrees to approximately 70 degrees. The results suggest the MD tilts and slews on actin from weak to strong binding, followed by swinging of the LCD through an approximately 35 degrees axial angle, giving an approximately 13 nm interaction distance and an approximately 4-6 nm working stroke.

Junctional feet and particles in the triads of a fast-twitch muscle fibre

SummaryStructural details of junctional feet in triads of fish muscle are described. These feet have a less dense central core and contact both sarcoplasmic reticulum and T-tubule membranes at tetragonally disposed sites. The distribution of intramembraneous particles differs at the junctional T-membrane, and the junction is asymmetric.

Further characterization of light and heavy sarcoplasmic reticulum vesicles. Identification of the ‘sarcoplasmic reticulum feet’ associated with heavy sarcoplasmic reticulum vesicles

Abstract Light and heavy sarcoplasmic reticulum vesicles were isolated from rabbit leg muscle using a combination of differential centrifugation and isophycnic zonal ultracentrifugation. Light sarcoplasmic reticulum vesicles obtained from the 30–32.5% and heavy sarcoplasmic reticulum vesicles obtained from the 38.5–42% sucrose regions of the linear sucrose gradient were determined to be free of surface and mitochondrial membrane contamination by marker enzyme analysis and electron microscopy. Thin sections of the light vesicles revealed empty vesicles of various sizes and shapes. Freeze-fracture replicas of the light vesicles showed an asymmetric distribution of intramembranous particles with the same orientation and distribution as the longitudinal sarcoplasmic reticulum in vivo. Heavy vesicles appeared as rounded vesicles of uniform size filled with electron dense material, similar to that seen in the terminal cisternae of the sarcoplasmic reticulum. The cytoplasmic surface of the membrane was decorated by membrane projections, closely resembling the ‘feet’ which join the sarcoplasmic reticulum to the transverse tubules in the intact muscle fiber. Freeze-fracture replicas of the heavy vesicles revealed an asymmetric distribution of particles which in some areas of the vesicles surface are larger and less densely aggregated than those of the light vesicles. In the best quality replicas, some regions of the luminal leaflet were not smooth but showed evidence of pits. These structural details are characteristic of the area of sarcoplasmic reticulum membrane which is covered by the ‘feet’ in the intact muscle. Heavy vesicles contained greater than six times the calcium content of light vesicles, 54 vs. 9 nmol Ca2+/μl of water space. After KCl washing both contained less than 4 nmol Ca2+/μl of water space. Although they transported at the same rate and the same total amount of calcium, the rate of passive Ca2+ efflux from the heavy vesicles was double that of light vesicles. The higher rate of calcium efflux from the heavy vesicles was inhibited by dantrolene, an inhibitor of Ca2+ release. High resolution sodium dodecyl sulfate gel electrophoresis showed that the light vesicles contained predominantly Ca2+-ATPase along with several approx. 55 000-dalton proteins and a 5000-dalton proteolipid, while the heavy vesicles contained Ca2+-ATPase and calsequestrin along with several approx. 55 000-dalton proteins, extrinsic 34 000- and 38 000-dalton proteins, intrinsic 30 000- and 33 000-dalton proteins and two proteolipids of 5000 and 9000 daltons. KCl washing of the heavy vesicles removed both the approx. 34 000- and 38 000-dalton proteins, and the ‘sarcoplasmic reticulum feet’ were no longer seen on the heavy vesicles. The KCl supernatant was enriched in the 34 000- and 38 000-dalton proteins, indicating that these proteins are possible components of the sarcoplasmic reticulum feet. The biochemical and morphological data strongly support the view that the light vesicles are derived from the longitudinal sarcoplasmic reticulum and that the heavy vesicles are derived from the terminal cisternae containing junctional sarcoplasmic reticulum membrane with the intact ‘sarcoplasmic reticulum feet’.

Comparative ultrastructure of Ca2+ release units in skeletal and cardiac muscle.

ABSTRACT: The sarcoplasmic reticulum (SR) of striated muscle fibers interacts with exterior membranes (surface membrane and transverse tubules) to form junctions that are involved in the internal release of calcium during excitation‐contraction coupling. Release of calcium through the ryanodine receptors (RyRs) or calcium release channels of the SR is under the control of the L type calcium channels or dihydropyridine receptors (DHPRs) of exterior membranes. Interacting clusters of the two proteins constitute calcium release units. The cytoplasmic domains of RyRs are visible as large electron‐dense structures (the feet) with four identical subunits in the junctional gap separating SR from exterior membranes. In freeze‐fracture replicas of skeletal muscle, large intramembrane particles are grouped into clusters of tetrads in the exterior membranes, and the tetrads are located in correspondence of the four subunits of the feet. Lack of tetrads in dysgenic muscle fibers with a null mutation for DHPRs and appearance of the tetrads after transfection with cDNA for DHPR indicate identity of tetrads with four DHPRs. In cardiac muscle, DHPRs are located at the sites of SR‐surface junctions, but they are not grouped into tetrads. This is consistent with a possible direct DHPR‐RyR interaction in skeletal but not in cardiac muscle. The size and distribution of SR‐surface junctions in skeletal and cardiac muscles provide further clues to their function.

Junctate is a key element in calcium entry induced by activation of InsP3 receptors and/or calcium store depletion

In many cell types agonist-receptor activation leads to a rapid and transient release of Ca2+ from intracellular stores via activation of inositol 1,4,5 trisphosphate (InsP3) receptors (InsP3Rs). Stimulated cells activate store- or receptor-operated calcium channels localized in the plasma membrane, allowing entry of extracellular calcium into the cytoplasm, and thus replenishment of intracellular calcium stores. Calcium entry must be finely regulated in order to prevent an excessive intracellular calcium increase. Junctate, an integral calcium binding protein of endo(sarco)plasmic reticulum membrane, (a) induces and/or stabilizes peripheral couplings between the ER and the plasma membrane, and (b) forms a supramolecular complex with the InsP3R and the canonical transient receptor potential protein (TRPC) 3 calcium entry channel. The full-length protein modulates both agonist-induced and store depletion–induced calcium entry, whereas its NH2 terminus affects receptor-activated calcium entry. RNA interference to deplete cells of endogenous junctate, knocked down both agonist-activated calcium release from intracellular stores and calcium entry via TRPC3. These results demonstrate that junctate is a new protein involved in calcium homeostasis in eukaryotic cells.