Functional groups of ryanodine receptors in rat ventricular cells

doi:10.1113/jphysiol.2007.136549

CARDIOVASCULAR

Functional groups of ryanodine receptors in rat ventricular cells

V. Lukyanenko¹, A. Ziman¹, A. Lukyanenko¹, V. Salnikov¹ and W. J. Lederer¹

¹ Medical Biotechnology Center, University of Maryland Biotechnology Institute, Baltimore, MD 21201, USA

Abstract

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Abstract
Introduction
Methods
Results
Discussion
References

Ryanodine receptors (RyR2s) are ion channels in the sarcoplasmicreticulum (SR) that are responsible for Ca²⁺ release in ratventricular myocytes. Localization of RyR2s is therefore crucialfor our understanding of contraction and other Ca²⁺-dependentintracellular processes. Recent results (e.g. circular wavesand Ca²⁺ sparks in perinuclear area) raised questions aboutthe classical views of RyR2 distribution and organization withinventricular cells. A Ca²⁺ spark is a fluorescent signal reflectingthe activation of a small group of RyR2s. Frequency and spatio-temporalcharacteristics of Ca²⁺ sparks depend on the state of cytoplasmicand intraluminal macromolecular complexes regulating cardiacRyR2 function. We employed electron microscopy, confocal imagingof spontaneous Ca²⁺ sparks and immunofluorescence to visualizethe distribution of RyR2s in ventricular myocytes and to evaluatethe local involvement of the macromolecular complexes in regulationof functional activity of the RyR2 group. An electron microscopystudy revealed that the axial tubules of the transverse–axialtubular system probably do not have junctions with the networkSR (nSR). The nSR was found to be wrapped around intermyofibrillarmitochondria and contained structures similar to feet of thejunctional cleft. Treatment of ventricular myocytes with antibodiesagainst RyR2 showed that in addition to the junctional SR, asmall number of RyR2s can be localized at the middle of thesarcomere and in the zone of perinuclear mitochondria. Recordingsof spontaneous Ca²⁺ sparks showed the existence of functionalgroups of RyR2s in these intracellular compartments. We foundthat within the sarcomere about 20% of Ca²⁺ sparks were notcolocalized with the zone of the junctional or corbular SR (Z-linezone). The spatio-temporal characteristics of sparks found inthe Z-line and A-band zones were very similar, whereas sparksfrom the zone of the perinuclear mitochondria were about 25%longer. Analysis of the initiation sites of Ca²⁺ sparks withinthe same junctional SR cluster suggested that 18–25 RyR2sare in the functional group producing a spark. Because of thesimilarity of the spatio-temporal characteristics of sarcomericsparks and ultrastructural characteristics of nSR, we suggestthat the functional groups of RyR2s in the middle of the sarcomereare macromolecular complexes of $~$ 20 RyR2s with regulatory proteins.Our data allowed us to conclude that a significant number offunctional RyR2s is located in the middle of the sarcomere andin the zone of perinuclear mitochondria. These RyR2s could contributeto excitation–contraction coupling, mitochondrial andnuclear signalling, and Ca²⁺-dependent gene regulation, buttheir existence raises many additional questions.

(Received 15 May 2007; accepted after revision 15 June 2007; first published online 12 July 2007)
Corresponding author V. Lukyanenko: Medical Biotechnology Center, University of Maryland Biotechnology Institute, 725 W. Lombard St, Room S213, Baltimore, MD 21201, USA. Email: lukyanen{at}umbi.umd.edu

Introduction

Top
Abstract
Introduction
Methods
Results
Discussion
References

Ryanodine receptors (RyR2s) are Ca²⁺-permeable ion channelsin the membrane of the sarcoplasmic reticulum (SR). In ventricularcardiomyocytes, RyR2s are responsible for local Ca²⁺-inducedCa²⁺ release (CICR) from the SR (Fabiato, 1985; Inui et al. 1987;Lai et al. 1988). Ca²⁺ released from the SR activates contractionand affects other Ca²⁺-dependent intracellular processes. Thus,the spatial distribution and organization of RyR2s is importantto our understanding of cardiac cell physiology.

RyR2s are largely localized to the junctional SR (jSR) thatapposes the T-tubules of the transverse–axial tubularsystem (TATS) and spans the junctional cleft between the T-tubuleand jSR (Franzini-Armstrong, 1973; Jorgensen et al. 1993; Carl et al. 1995).In rat ventricular cells, RyR2s are grouped in clusters (Franzini-Armstrong et al. 1999).The distance between the membranes of the jSR and T-tubule isabout 12 nm (Brochet et al. 2005). This small space allows effectiveactivation of the jSR RyR2s by Ca²⁺ influx through T-tubuleL-type Ca²⁺ channels during excitation–contraction coupling(Bers, 2001). Besides the jSR, RyR2s were also found to be localizedin the corbular SR (cSR). The cSR is located in close proximityto Z-lines but much further from the TATS membranes than thejSR. The role of the cSR in cardiac cell physiology remainsuncertain (Dolber & Sommer, 1984; Jorgensen & McGuffee, 1987;Jorgensen et al. 1993). The network SR (nSR) in ventricularmyocytes has been reported to be nearly free of RyR2s (Jorgensen et al. 1993).

At least three types of recent results raise questions aboutthis classic view of RyR2 distribution and organization. (1)Subramanian et al. (2001) explained the phenomenon of similarvelocity of propagation of Ca²⁺ waves in transverse and longitudinaldirections by hypothesizing that a significant fraction of Ca²⁺-releaseunits should exist between Z-lines. (2) Chen-Izu et al. (2006)described intercalated RyR2 clusters in cardiac cells that areinterspersed between Z-lines on the cell periphery. (3) Ryanodine-sensitiveCa²⁺-release events were recently described for regions locatedclose to the nucleus in rat ventricular cells (Yang & Steele, 2005, 2007).

While this array of observations is provocative, each of themassumes a distinct non-classical distribution of RyR2s in ventricularcells. We employed confocal imaging of spontaneous Ca²⁺ sparksand immunofluorescence to re-examine the distribution of RyR2s.A ‘typical’ Ca²⁺ spark is a bright and short fluorescentsignal corresponding to a transient ( $~$ 30 ms) and local ( $~$ 10 fl)elevation of [Ca²⁺] that reflects the activation of a groupof 10 or more RyR2s and serves as an elementary event of SRCa²⁺ release (Cheng et al. 1993; Lopez-Lopez et al. 1995; Györke et al. 1997;Lukyanenko et al. 2000; Sobie et al. 2002). In adult mammalianventricular myocytes, SR Ca²⁺ release depends on the functionalstate of the RyR2s (i.e. from state of cytoplasmic and intraluminalmacromolecular complexes regulating cardiac ryanodine receptorfunction; Bers, 2004; Györke et al. 2004; Wehrens et al. 2005).These changes in the functional activity of the RyR2s couldbe recorded as changes in the frequency and spatio-temporalcharacteristics of Ca²⁺ sparks. For example, unbinding of FKBP12.6(calstabin-2) from RyR2s lengthens the duration of Ca²⁺ sparks(Xiao et al. 1997; Marx et al. 2000; Bers, 2004), and bindingof calsequestrin significantly reduces the amplitude and frequencyof Ca²⁺ sparks (Viatchenko-Karpinski et al. 2004; Györke et al. 2004).Thus, under other similar conditions, the similarity in frequencyand spatio-temporal characteristics of Ca²⁺ sparks suggestssimilarity in the ultrastructural organization of spark-producinggroups of RyR2s.

Immunofluorescence is a contemporary method to demonstrate localizationof proteins within permeabilized cells. We followed two immunofluorescenceprotocols to determine the location of RyR2s. To reduce inputfrom out-of-focus signal and improve localization of antigenswe employed deconvolution of confocal images (Sedarat et al. 2004;Scriven et al. 2005). The multidisciplinary nature of this workallowed distinct and independent methods to complement eachother.

The aim of the work presented here was to determine the locationof functional groups of RyR2s in adult rat ventricular cells.Multiple complementary methods were employed to examine thelocation and function of the SR Ca²⁺ release channels, RyR2s.Here, we demonstrate that a significant number of functionalgroups of RyR2s are located at sites away from the Z-line. Possibleorganization and roles of these non-junctional groups of RyR2sare discussed.

Methods

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Abstract
Introduction
Methods
Results
Discussion
References

Cell isolation

Single ventricular myocytes were obtained from adult male Sprague–Dawleyrat hearts by enzymatic dissociation as previously described(DuBell et al. 2000). The animals were killed by lethal injectionof Nembutal (100 mg kg^–1 I.P.). The aorta was cannulatedfor Langendorff perfusion, and ventricular myocytes were isolatedby a standard enzymatic technique using a Hepes-buffered solutioncontaining (mM): NaCl 130, KCl 5.4, lactic acid 1, pyruvic acid3, Hepes 25, NaH₂PO₄ 0.33, MgCl₂ 1.0 and glucose 20; pH wasadjusted to 7.4 with NaOH.

The coronary arteries were perfused with the above solutioncontaining 50 mg collagenase Type II (Worthington Biochemical),1 mg protease type XIV and 50 µM CaCl₂. After 10 min ofperfusion, the ventricles were excised, minced and then gentlyagitated for 4 min in a digestion buffer containing 0.1 mM CaCl₂and 1.0% bovine serum albumin (BSA). The cells were filteredthrough a 200 µm nylon mesh and then washed and resuspendedin an enzyme-free buffer containing 1% BSA. After the finalwash, the cells were resuspended at room temperature (21–23°C)in a Hepes-buffered Dulbecco's modified Eagle's medium with10% fetal calf serum.

Unless specified otherwise, all chemicals were from Sigma.

Experimental solutions for permeabilized myocytes

Isolated ventricular cells were permeabilized by exposure to0.01% saponin for 0.5 min as previously described (Lukyanenko & Györke, 1999).Tyrode solution contained (mM): NaCl 140, KCl 5.4, MgCl₂ 0.5,CaCl₂ 1, Hepes 10, NaH₂PO₄ 0.25 and glucose 5.6; pH 7.3. Thepermeabilization solution contained (mM): potassium aspartate100, KCl 20, MgATP 3, MgCl₂ 0.81 ([Mg²⁺]_free = $~$ 1mM), EGTA 0.5, CaCl₂ 0.114 mM ([Ca²⁺]_free = $~$ 90 nM),Hepes 20, glutamic acid 3 and malic acid 3, and 1% polyvinylpyrrolidone(PVP); pH 7.2. The control experimental solution contained (mM):potassium aspartate 100, KCl 20, MgATP 3, MgCl₂ 0.81 ([Mg²⁺]_free = $~$ 1mM), EGTA 0.5, CaCl₂ 0.114 ([Ca²⁺]_free = $~$ 90 nM),Hepes 20, glutamic acid 3, malic acid 3, phosphocreatine 10,and 5 U ml^–1 creatine phosphokinase and 1% PVP; pH 7.2.The free [Ca²⁺]_free and [Mg²⁺]_free at the given total calcium,magnesium, ATP and EGTA concentrations were calculated usingWinMAXC32 2.5 (Stanford University, CA, USA). Measurements witha spectrofluorometer D-Scan (PTI, Monmouth Junction, NJ, USA)and the Ca²⁺ indicator fura-2 (TefLabs, Austin, TX, USA) showedthat real [Ca²⁺]_free in the experimental solution was $~$ 100 nM.

Electron microscopy

Tissue. Pieces of rat heart were fixed in 0.5% glutaraldehyde, 2% paraformaldehydeand 0.025% CaCl₂ in 0.05 M sodium cacodylate buffer (pH 7.4),then exposed to a microwave oven (Laboratory Microwave Processor,Model 3440 PELCOTM, Ted Pella, Inc., Redding, CA, USA) for 15–20s. After primary irradiation, tissue samples were kept in thesame fixative solution for 5 min at 4°C, then rinsed inbuffer, transferred into 0.5% OsO₄ in 0.05 M sodium cacodylatebuffer (pH 7.4), and re-exposed to microwave radiation. Aftersecondary microwave irradiation, the tissue was kept in thesame fixative solution for 1 h at 4°C.

Cells. To get longitudinal sections, isolated rat ventricular cellswere allowed to attach to coverslips covered with laminin inTyrode solution for 10 min before fixation. The Tyrode solutionwas then replaced by 0.1 M sodium cacodylate buffer (pH 7.4)containing 6% glutaraldehyde and 2% paraformaldehyde for 1 or20 min at room temperature. After fixation, the cells were rinsedtwice with 0.2 m sucrose buffer and postfixed with 1% osmiumin s-Colloidine buffer (Electron Microscopic Science, Hatfield,PA, USA) for 1 h at 4°C. Then samples were stained en bloc(2% uranyl acetate in 50% ethanol) for 1 h.

After dehydration in an alcohol series, the samples (both tissueand cells) were embedded in LR White resin (Ted Pella, Inc.).Polymerization took 12 h at 60°C. Ultrathin sections ( $~$ 80nm) were obtained with a LKB III microtome (LKB, Uppsala, Sweden),collected on Formvar-coated nickel grids, and stained for 15min with 2% aqueous uranyl acetate and then for 2 min with leadcitrate at room temperature. Sections were examined at 60 kVwith a Zeiss electron microscope EM 10C/EM 10 CR (Zeiss, Goettingen,Germany).

Localization of Ca²⁺ sparks

Permeabilized ventricular myocytes were incubated for at least5 min with 25 µM fluo-3 (pentapotassium salt; Biotium,Inc., Hayward, CA, USA), and 0.1 µM BODIPY TR-X ryanodine(BTR) (Molecular Probes Inc., Eugene, OR, USA). These fluorescentdyes were excited by argon (488 nm; fluo-3) or HeNe (543 nm;BTR) laser illumination. Fluorescence signals were recordedwith a Laser Scanning Confocal System (LSM 510, Carl Zeiss,Germany) equipped with a C-Apochromat 63 x/1.2 W corr objective.Fluorescence was measured at wavelengths of > 505 nm (fluo-3)and > 560 nm (BTR). All measurements were done from opticalslices < 1 µm with a laser beam power of $~$ 0.08 mW. Notethat BTR itself produced no fluorescence at the used concentrations(0.1 µM), when excited at 488 nm. In our preliminary experimentswe used a 100 times higher concentration of BTR (10 µM);however, the signal recorded with ‘spark parameters’(i.e. absorbtion/emission, 488/505 nm; optical slice, < 1µm; maximal gain) was not different from noise of thesystem.

For x–y images, every line was scanned for 15.4 ms (meanof n = 8 scans) with a pixel size of 0.03 µm x 0.03µm (at zoom = 10). Under these recording conditions, sparkscould be seen on the images as 2 pixel-wide lines. To localizesparks found with fluo-3 (argon laser), the locations of theirgeometrical centres were marked with circles on correspondingBTR x–y images (HeNe laser).

Due to our approach combining the x–y and x–t modes,the Ca²⁺ spark found on the images could be both out-of-focusand out-of-line of scan (Pratusevich & Balke, 1996). Notethat a major task for this study was to localize a Ca²⁺ sparkalong a sarcomere (i.e. on the X axis). Because the same placewas scanned 16 times, we obtained complete information aboutthe width of the 30 ms Ca²⁺ event. It is known that the Ca²⁺–dyecomplex diffuses in ventricular cells with the same velocitylongitudinally and transversely (Subramanian et al. 2001). Therefore,the geometrical centre of the Ca²⁺ spark should correspond tothe X coordinate of the Ca²⁺ flux underlying the Ca²⁺ spark.Although the Y and Z coordinates could be ignored for this study,we took into account only the brightest 20% of all Ca²⁺ sparksrecorded from the smallest possible optical slice (see above).This allowed us to minimize input from out-of-line and out-of-focussparks. As a result, sparks were not recorded inside mitochondriaat a depth of more than 0.1 µm. In the middle of the sarcomerethis corresponds to error in the Y coordinate. If so, the Zerror in localization of the Ca²⁺ sparks for 20% brightest eventsmust be about half of error in Y direction (Pratusevich & Balke, 1996).Therefore, we can conclude that our approach allowed for thedetermination of the X coordinate of Ca²⁺ sparks; however, theCa²⁺ sparks could be $~$ 100 nm out of the line of scan and $~$ 50 nmout of the optical slice (this is smaller than the size of twoRyR2s).

Spatio-temporal characteristics of Ca²⁺ sparks

Ca²⁺ spark characteristics in permeabilized ventricular cellswere measured in x–t (line scan) mode as previously described(Lukyanenko et al. 2000). An analog recording of fluorescenceintensity during each scan was digitized into 512 pixels, givinga nominal pixel dimension of 0.29 µm. Line-scan images(x–t mode) were acquired at a rate of 520 Hz (1.92 msper line scan) and stored in tif-format. All line-scan imagesof sparks were obtained from the smallest possible optical slices(< 1 µm at laser beam power of $~$ 0.08 mW) by scanningthe cells longitudinally.

Immunofluorescence

Freshly isolated ventricular myocytes were fixed in 2% paraformaldehydefor 15 min. Following fixation, cells were washed 4 times for15 min with PBS. Cells were blocked and permeabilized in a solutionof 1% BSA, 1% NGS and 5 mg ml^–1 saponin in PBS for 1 h.Following blocking, primary antibodies (diluted 1: 100) in 1%BSA and 1% NGS in PBS were added to cells overnight at 4°C.After primary antibody incubation, cells were washed 4 timesfor 30 min with 1% BSA and 1% NGS in PBS. Goat anti-mouse orgoat anti-rabbit secondary antibodies conjugated to Alexa 488(diluted 1: 500) were applied to the cells for 2 h at room temperature.Following secondary antibody exposure, cells were washed 3 timesfor 30 min with 1% BSA and 1% NGS in PBS, then twice for 15min in PBS. Immunostained myocytes were then mounted on glassslides using Slow Fade Light. Negative controls were producedby using the same protocol without the use of a primary antibody.

Primary antibodies. We used monoclonal Anti-RyR2 MA3-916 (Affinity BioReagents Inc.,Golden, CO, USA); polyclonal anti-calsequestrin (Swant, Bellinzona,Switzerland); monoclonal anti- ${alpha}$ tubulin 12G10 (DevelopmentalStudies Hybridoma Bank, Iowa City, IA, USA) and polyclonal anti-junctophilin2(Invitrogen, Carlsbad, CA, USA).

Image collection and processing. Immunofluorescent images were collected using a Carl Zeiss LaserScanning Confocal System (LSM 510, equipped with a C-Apochromat63 x/1.2 W corr objective) with excitation at 488 nm and a long-passfilter of 505 nm. Deconvolution of immunofluorescence imageswas performed to clarify the distribution of the antibodies.High resolution z-stacks (stacks with a maximum pixel size of0.1 µm x 0.1 µm x 0.2 µm) were processed usingVolocity 3.5.1 (Improvision, Cambridge, MA, USA). Images werefirst passed through a fine (3 pixel x 3 pixel) Gaussian filterto remove scattered light. Then, images were deconvolved usingthe iterative restoration algorithm developed by ImprovisionInc. (Lexington, MA, USA) (based on published maximum entropytechniques) to increase resolution in X, Y and Z. Representativeimages (see Figs 4 and 5) show the typical fluorescent patternfor 50–100 cells.

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Figure 4. Distribution of RyR2s marked with MA3-916 (ABR) in permeabilized ventricular cells
A–D, immunofluorescence labelling. A and B, live cells were permeabilized with saponin in vitro. Then the cells were incubated for 30 min with (A) and without (B) primary antibody. After a 30 min washout, the cells were incubated for 30 min with secondary antibody conjugated to a fluorescent probe and again washed-out for 30 min. C and D, representative images of cells permeabilized with saponin after fixation in paraformaldehyde. The cells were incubated overnight with primary antibody. D, different region of the cell presented in C and with higher resolution. Images are deconvolved from 3-D stack. Thickness of the optical slices for C and D was $~$ 0.7 µm. Z-lines were marked on the images according to corresponding images in transmitted light. Z, Z-line; arrows show labelling in M band (between Z-lines); PNM, perinuclear mitochondria; N, nucleus.

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Figure 5. Distribution of calsequestrin and ${alpha}$ -tubulin in ventricular cells
Immunofluorescence labelling. Representative images of cells permeabilized with saponin after fixation in paraformaldehyde. The cells were incubated overnight with primary polyclonal antibody against calsequestrin (A) or anti- ${alpha}$ -tubulin (clone 12G10, (C). The primary antibody was diluted 1: 100 and the secondary (goat anti-rabbit conjugated to Alexa 488) was diluted 1: 500 (A–C). A, image is deconvolved from a 3-D stack. B, only secondary antibody was added to cells. Secondary antibody was diluted 1: 200. Z, Z-line; PNM, zone of perinuclear mitochondria; N, nucleus.

Experiments were performed at room temperature. Data were expressedas means ± S.E.M. Comparisons were performed usingStudent's t test, and differences were considered significantwhen P < 0.05.

Results

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Abstract
Introduction
Methods
Results
Discussion
References

The aim of the work presented here was to determine the locationof functional groups of RyR2s in adult rat heart cells. Multiplecomplementary methods were employed to examine the locationand function of the SR Ca²⁺ release channels, RyR2s.

Revealing the ultrastructure features of the SR with electron microscopy

In ventricular cells, the SR is located between mitochondriaand myofibrils or T-tubules (Sommer & Johnson, 1968; Fawcett & McNutt, 1969;Dolber & Sommer, 1984; Frank, 1990). Recently, we confirmedthe existence of connecting pillars between the jSR and mitochondrialouter membrane by adding 3 nm particles before preparation ofventricular cells for electron microscopy (i.e. in vivo; Parfenov et al. 2006;Salnikov et al. 2007). This allowed us to suggest that the SRcould be attached to mitochondria as to most stable structureswithin the contracting cells at least near the Z-line. To clarifydistribution of the SR around mitochondria, we employed embeddingin LR White resin.

Although conventional electron microscopy fixation followedby Epon embedding is best for preserving and imaging intracellularstructures (Fawcett & McNutt, 1969; Maunsbach & Afzelius, 1999;Brochet et al. 2005), in comparison to water-soluble resinsit significantly restricts penetration of contrasting agentsinto the body of the slice (Shalla et al. 1964; Peters et al. 1971).Therefore, to better visualize the SR, we used conventionalfixation followed by embedding in water-soluble LR White resin(Newman & Hobot, 1993; Parfenov et al. 2006; Salnikov et al. 2007).

Despite the expected reduction in structure quality producedby LR White (Maunsbach & Afzelius, 1999), this kind of embeddingallowed the visualization of ventricular cell ultrastructure.Figure 1A shows intermyofibrillar mitochondria (IMFMs), nSRand jSR, TATS, Z-lines, M-lines, and I- and A-bands of the sarcomere.The contrasting of the entire thickness of the slice allowedus to see overlapping nSR and mitochondrial cristae or nSR andmyofibrils (Fig. 1B).

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Figure 1. Sarcoplasmic reticulum in rat ventricular cells
The electron micrographs (longitudinal ultrathin section) show ventricular cell ultrastructure using conventional fixation and polymerization in acrylic LR White Resin. A, oblique section in tissue samples shows localization of junctional SR (jSR) and network SR (nSR) in relation to T-tubules and mitochondria (M). B–D, nSR. Isolated cells. B, in the centre of the micrograph nSR is seen together with mitochondrial cristae or with contractile elements. C, junctions of branches of the nSR create platforms that could carry small group of RyR2s. D, an nSR fills mitochondrial invaginations. E, oblique section through three mitochondria shows nSR wrapping around them. jSR, junctional SR; nSR, network SR; M, mitochondrion; T, T-tubule of TATS; Z, Z-line.

The most important finding here is the platforms created byjunctions of nSR branches (Fig. 1C). If RyR2s in the clusterare organized in a checkerboard order (Yin et al. 2005; Parfenov et al. 2006),such platforms could carry group of $~$ 20 RyR2s. We found suchplatforms mainly in the middle of the sarcomere (M line). Becauseof multiple junctions, the nSR at the level of the M line wasnamed M-rete (Dolber & Sommer, 1984). It is interestingthat in our LR White electron microscopy images, M-rete oftenfilled mitochondrial invaginations as shown for two mitochondriain Fig. 1D. This demonstrates that the nSR has tight connectionswith the mitochondrial outer membrane. This connection couldhave a biological relevance because mitochondria are relativelystable structures in the contracting cells. However, if theSR has connections to mitochondria both near the Z-line (jSR)and the M line (nSR) it has to wrap around them. Figure 1E showsan oblique section through three mitochondria. The nSR is seenas rays around them. This supports the hypothesis that the nSRwraps around mitochondria rather than the myofilament bundle,as can be seen in classical schematic representations (Fawcett & McNutt, 1969).Thus, mitochondria could be the best reference structure tolocalize functional groups of RyR2s independently of their locationin the SR network.

If RyR2s are located in the middle of a sarcomere, they couldbe visualized after conventional fixation followed by Epon embedding(Brochet et al. 2005; Parfenov et al. 2006). This embeddingallows the ultrastructure to be seen much better than followingembedding in the LR White resin (Maunsbach & Afzelius, 1999;Parfenov et al. 2006). We expected to find structures similarto feet (structures which were identified as RyR2s by Franzini-Armstrong (1973)to be free of contacts, as shown for corbular SR (Dolber & Sommer, 1984),or between SR and longitudinal tubules of TATS (i.e. the jSRin the middle of the sarcomere). In other words, we were lookingfor structures similar to cSR or jSR in the middle of a sarcomere.Figure 2A shows part of the nSR containing structures that couldbe considered as RyR2s (inset; arrowheads) due to the clearcheckerboard pattern. They are located within the edges of thenSR and are similar in size to feet in the junctional cleft(Fig. 2B; arrowheads). Although similar structures could sometimesbe seen outside the nSR, there are two reasons why we providethe image showing them inside the nSR. First, they keep thecheckerboard order, while curvature of SR tubes has to maskthe pattern and such structures outside nSR could be mistakenfor similarly sized glycogen granules or ribosomes (Fawcett & McNutt, 1969).Second, even embedding in Epon sometimes shows an overlay ofstructures within the slice due to the penetration of contrastingagents (Shalla et al. 1964; Peters et al. 1971). Thus, the particlescould be located outside the SR tubule and be seen togetherwith the SR. However, in this case they can be located betweennSR and axial tubule of TATS.

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Figure 2. Distribution of possible RyR2s in rat ventricular cells
The electron micrographs (longitudinal ultrathin section) show ventricular cell ultrastructure using conventional fixation and polymerization in Epon. Slightly oblique longitudinal ultrathin section, 2.5% glutaraldehyde for 3 h. Isolated intact cell. A and B, these electron micrographs show possible RyR2s that can be attributed to network (A) or junctional (B) SR. Inset at higher magnification shows the area marked with the dashed line. T, T-tubules; nSR, network sarcoplasmic reticulum; jSR, junctional SR; M, mitochondrion; Z, Z-line; arrowheads, possible RyR2s.

To better visualize connections between the SR and TATS membranes,we studied TATS contacts on images after Epon embedding. Westudied 738 electron micrographs of ventricular cells (x 60000–100 000) where the jSR around T-tubules was clearlyseen; however, we found only eight micrographs clearly showingaxial TATS tubules entering T-tubules and they did not havecontacts with the SR. It is interesting that we did not findaxial tubules of TATS within the same ultrathin section betweentwo T-tubules, unless the section was about 30 deg oblique.This was confirmed by contrasting of TATS membranes with tannicacid (10 cells; data not shown). These images demonstrated multiplecuts through the axial TATS tubules around IMFMs at the levelof the A-band.

A representative electron micrograph (Fig. 3) shows the ultrastructureof an axial TATS tubule from an intact ventricular cell. ThejSR on the micrograph could be seen only at the level of theZ-line (thick black arrows) while near the middle part of theA-band it has a connection to the outer mitochondrial membranerather than to the SR (see inset; black arrows).

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Figure 3. Axial tubule of the transverse–axial tubular system (TATS)
Slightly oblique longitudinal ultrathin section, 2.5% glutaraldehyde for 3 h, Epon embedding. Isolated intact cell. This electron micrograph shows an axial tubule of TATS. Arrows show bridges between the tubule membrane and jSR (thick arrows) and outer mitochondrial membrane (marked area). Inset at higher magnification shows the area marked with dashed line. Arrows show possible contacts between axial tubule of TATS and mitochondrion. T, T-tubules; nSR, network sarcoplasmic reticulum; jSR, junctional SR; M, mitochondrion; Z, Z-line; L, lipid droplet.

Our images showed only two structures similar to jSR in themiddle of the sarcomere and no jSR between perinuclear mitochondria.Therefore, we conclude that jSR is absent from both the perinuclearzone and the A-band of the sarcomere.

Localization of RyR2s with immunofluorescence

To localize RyR2s within ventricular cells, we employed twokinds of immunofluorescence imaging methods using primary antibodiesABR MA3-916 and secondary antibodies conjugated to Alexa 488.Figure 4 shows representative images from cells permeabilizedin vivo (n = 3 experiments; 30 cells) in the presence(Fig. 4A) and absence (Fig. 4B) of the primary antibody. Thepermeabilization was confirmed with fluo-3 as previously described(Lukyanenko & Györke, 1999). Because the cells were‘alive’ during these experiments, we restrictedthe time of exposure and washout for each antibody to 30 min.To facilitate penetration of antibody into the cell, we increasedthe time for permeabilization by a factor of two. As can beseen in Fig. 4A and B, the fluorescence from cells with primaryantibodies was much higher. Figure 4A shows transverse brightstripes (identified by the letter ‘Z’ marking theZ-line) and less-bright marks between them (arrows). Arrowspoint to the immunofluorescence of RyR2s in the centre regionof A-band (Fig. 4A). This suggests that RyR2s can be colocalizedwith nSR.

To allow the antibodies to penetrate deeper into the cell, weperformed experiments with cells fixed in paraformaldehyde (Fig. 4C and D).The cells were permeabilized with saponin and left overnightwith primary antibodies against RyR2 (MA3-916; n = 3 experiments;30 cells each). The images were obtained following deconvolution,a method that involves the gathering of high resolution z-stacks(0.2 µm step) and using that image stack along with thepoint spread function (PSF) of the lens to computationally removeout-of-focus light (see Methods). The resulting images demonstratedthe distribution of antibodies primarily along Z-lines; however,some longitudinal lines of fluorescence were also clearly seen(Fig. 4D; arrows).

To exclude any impact from non-specific labelling, we performedsimilar immunolabelling for a protein associated structurallyand functionally with RyR2s, calsequestrin (Jones et al. 1995;Sitsapesan & Williams, 1997; Györke et al. 2004). Figure 5Ashows both transverse and longitudinal labelling for calsequestrinafter deconvolution (n = 6). Control experiments werecarried out using only secondary antibody (Fig. 5B; n =6) and these revealed no signal. Other proteins unrelated toRyR2 (such as the cytoskeletal protein ${alpha}$ -tubulin) were distributedas expected and differently from calsequestrin or RyR2s (Fig. 5C;n = 6). These control experiments supported our hypothesisthat RyR2s can be colocalized with nSR.

Comparison of spontaneous Ca²⁺ sparks produced in different cellular subdomains

The A-band RyR2s (identified above by immunofluorescence) maybe organized into groups that can support an elementary Ca²⁺release (i.e. a Ca²⁺ spark) (Cheng et al. 1993; Bhat et al. 1999;Bridge et al. 1999; Lukyanenko et al. 2000; Sobie et al. 2002).Previously, we showed that groups of RyR2s that produce Ca²⁺sparks probably contain about 10–20 functional RyR2s (Lukyanenko et al. 2000).These groups are much smaller than rat jSR clusters (100–300RyR2s; Franzini-Armstrong et al. 1999; Chen-Izu et al. 2006;Soeller et al. 2006) and could be located on SR platforms inthe middle of a sarcomere (see above; Fig. 1C).

To localize Ca²⁺ sparks, the ventricular cells were loaded witha Ca²⁺-sensing fluorescent probe (as fluo-3) and a marker forreferral ultrastructure. We tested markers to two differentstructures, T-tubules, the periphery of which (Z-line zone)was shown to have abundant RyR2s, and mitochondria, which arewrapped by the SR (see above). We performed preliminary experimentsmarking both T-tubules and RyR2s. To mark the T-tubules, weused di-8-ANEPPS (absorbance/emission, 498/730 nm; n =3; data not shown). However, the complicated 3-D structure ofTATS (Soeller & Cannell, 1999) resulted in multiple falsereferral points, making data interpretation very difficult.

To mark RyR2s directly, we used two different fluorescent probes:(1) antibodies to RyR2s conjugated to Alexa Fluor 633 (secondarygoat anti-mouse antibody; absorbance/emission, 630/665 nm; n =4; data not shown); and (2) BTR (absorbance/emission, 545 nm/650nm). Exposure for 1 h to the antibody significantly reducedthe quality of Ca²⁺ sparks and provided us with insufficientdata to make any conclusions. The BTR was developed to markRyR2s directly and we expected (1) to see the BTR fluorescencealong Z-lines (concentrated around T-tubules), and (2) thatcentres of mass of Ca²⁺ sparks will always be colocalized withareas marked by BTR. Surprisingly, our preliminary experimentsshowed that BTR labels mitochondria rather than RyR2s. Figure 6Ashows that BTR (red) and antibodies to RyR2 (blue) marked differentintracellular structures. The antibody marked the Z-lines, whereasBTR marked mitochondria. Only increasing BTR concetration to10 µM allowed visualization of the Z-lines (data not shown).The addition of fluo-3 under these conditions (Fig. 6B) didnot reveal spontaneous Ca²⁺ sparks at this concentration ofBTR (n = 5 experiments). The inhibitory effect of 10 µMBTR on Ca²⁺ sparks suggests that molecules of BTR had also foundtheir targets, RyR2s.

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Figure 6. Spatial distribution of BODIPY TR-X ryanodine (BTR) in permeabilized ventricular cells
A, co-labelling with RyR2 antibody conjugated to Alexa Fluor 488 (blue) and 0.5 µM BTR (red). Excitation, 488 and 543 nm; emission, > 505 and > 560 nm, respectively. B, ventricular cell was pretreated for 10 min with 10 µM BTR and 5 min with 25 µM fluo-3 (pentapotassium salt). C–E, unique properties of BTR could be used to visualize Z-lines in negative relief. C, the cell was pretreated for 10 min with 5 µM BTR. D, the graph shows the average fluorescence (profile) for C. D, inverted image of distribution of BTR presented in C. Excitation/emission, 488/505 nm; optical slice < 1 µm. Z, Z-line; M, mitochondrion.

Within 10 min, the BTR filled the mitochondria entirely (Fig. 6C)and revealed Z-lines only in negative relief (Fig. 6D and E).This distribution of BTR could mean that BTR enters the mitochondrialintermembrane space. Based on our experiments with isolatedcardiac mitochondria and membrane-impermeant fluorescent probes,we suggest that the small molecular size of BTR allowed it topass through the mitochondrial voltage-dependent anion channel(VDAC) as we showed earlier for the salt form of fluo-3 (Chinopoulos et al. 2005).

To check this hypothesis, we performed similar experiments (Fig. 7)with a larger BTR analogue, BODIPY TR-X ivermectin (molecularweight, 1400). Ivermectin selectively binds to sarcolemmal glutamate-gatedCl^– channels in invertebrate muscle cells and with lowaffinity to neuronal acetylcholine, glutamate and GABA receptors,and to SERCA in rabbit skeletal muscle fibres (IC₅₀, 7 µM;Bilmen et al. 2002). Although we preincubated permeabilizedcells with 1 µM BODIPY TR-X ivermectin (Fig. 7A), it inducedonly minor fluorescence (at least five times less than 0.1 µMBTR; Fig. 7B and C). This supported our suggestion regardinga VDAC-dependent mechanism of BTR penetration into the mitochondria.

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Figure 7. Spatial distribution of BODIPY TR-X ivermectin in permeabilized ventricular cells
A and B, ventricular cell pretreated for 15 min with 1 µM BODIPY TR-X ivermectin before (A) and 15 min after (B) addition of 0.1 µM BTR to the bathing solution. Excitation/emission, 543/650 nm. C, the graph shows fluorescence profiles for A (black) and B (grey) taken as shown with dotted line in B.

We concluded that BTR cannot be used as a marker of RyR2s incardiac cells. However, BTR marked mitochondria much betterthan the mitotracker CellTrace BODIPY TR methyl ester (MolecularProbes Inc.; data not shown). Therefore, we used its uniquefluorescent properties only to mark mitochondria and to outlinethe Z-lines as shown above. To localize Ca²⁺ sparks, we pretreatedpermeabilized ventricular cells with 0.1 µM BTR (to preventthe inhibitory effect of BTR on RyR2s) and 25 µM fluo-3.The sparks could be seen on x–y confocal images as horizontalbright lines (Fig. 8A). It was shown that the Ca²⁺–dyecomplex diffused isotropically (Subramanian et al. 2001). Therefore,we used the geometric centre of the spark to find the coordinatesof its ‘site of origin’ on the corresponding imagewith BTR.

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Figure 8. Spatial distribution of spontaneous Ca²⁺ sparks in permeabilized ventricular cells
A, to localize Ca²⁺ sparks, the permeabilized cells were pretreated with 0.1 µM BTR and fluo-3 (pentapotassium salt). The same area of a ventricular cell was visualized with excitation/emission, 488/505 nm (upper panel) or 543/650 nm (lower panel). Centres of spark lines found with fluo-3 were marked with circles on corresponding images in BTR as shown on lower panel. Yellow circles represent sparks from the A-band. B, representative image of cell showing distribution of spontaneous sparks in the zone of perinuclear mitochondria. Optical slice, < 1 µm. Note, the thickness of the slide permits mitochondria to be seen together with the surrounding SR. N, nucleus. C, the graph shows histogram of spark distribution as spark number against the distance from nearest Z-line.

We located the positions of 430 spontaneous Ca²⁺ sparks. Thesparks were localized mainly in close proximity to mitochondriain the intermyofibrillar and perinuclear zones (Fig. 8B) andzones of subsarcolemmal mitochondria (SSM; data not shown).Area densities of grouped RyR2s producing Ca²⁺ sparks (so called‘hot spots’) in the zones were very similar (0.08± 0.02 and 0.08 ± 0.03 spots µm^–2for zones of perinuclear and subsarcolemmal mitochondria 0.06± 0.02 spots µm^–2 for IMFM zone; n =3–16).

About 80% (of 320) spontaneous sparks from the zone of IMFMswere located primarily within the 500 nm band along the Z-lines.The graph presented on Fig. 8C shows the distribution of thesparks along half of the sarcomere length. Note that about 20%of sparks are almost homogeneously distributed in the middleof A-band (black dotted line represents half of the band). Similardata were recorded in three other experiments when we used CellTrace BODIPY or antibodies to RyR2 (data not shown) as intracellularmarkers of mitochondria or Z-lines.

Characteristics of spontaneous Ca²⁺ sparks from different cell subdomains

Spark spatio-temporal characteristics depend on multiple regulatoryproteins attached to RyR2s from both the sarcoplasmic and intraluminalsides (Marx et al. 2000; Bers, 2004; Györke et al. 2004;Wehrens et al. 2005). To find out whether groups of RyR2s areorganized differently in different regions of the cell, we derivedspatio-temporal characteristics of Ca²⁺ sparks from events recordedin x–t mode. For this, ventricular cells were pretreatedfor at least 5 min with 0.1 µM BTR and visualized in x–ymode (Fig. 9A; left panel). Then one line was picked up (Fig. 9A;left panel; marked with dots) for scanning (Fig. 9A; right panel).After recording of sparks, an additional 10 000 repetitive linescans were made to mark a scanned line and locate it on thex–y confocal image. During data analysis, recorded spontaneousCa²⁺ sparks were localized on the line as shown and sorted bydistance from the Z-line. We compared the spatio-temporal characteristicsof sparks in the zone of Z-line (500 nm from Z-line), A-bandzone (1 µm in the middle of the sarcomere), and the zoneof PNMs (Fig. 9B). To reduce the input from out-of-focus sparks,we used optical slices < 1 µm for spark recording.Before each experiment, every PNM zone was checked for thicknesswith 0.5 µm z-stack optical slices and the experimentwas done only if the thickness of the zone was 2 µm.

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Figure 9. Spontaneous Ca²⁺ sparks in different zones of permeabilized ventricular cells
A, an example of localization of Ca²⁺ sparks. Ventricular cells were pretreated for 5 min with 0.1 µM Bodipy-TR-X ryanodine and visualized as an optical slice < 1 µm with excitation/emission, 543/560 nm in x–y mode (left panel). Then one line was picked up on the image and scanned in x–t mode with 1 ms interval with excitation/emission, 488/505 nm (right panel). Additionally, 10 000 repetitive line scans were made to mark a scanned line and locate it on the x–y confocal image (dotted square on the left panel). During data analysis, recorded spontaneous Ca²⁺ sparks were localized on the line as shown and sorted according to distance from Z-line when its location was clearly seen. B, representative image of ventricular cell pretreated with 0.1 µM Bodipy-TR-X ryanodine and 25 µM fluo-3 (pentapotassium salt). Excitation/emission, 543/650 nm. C, Ca²⁺ sparks were collected in line-scan mode scanning lines as shown in B in perinuclear mitochondria (PNM) zone (blue line) and IMFM zone (yellow line). Representative spark images in C are shown with corresponding colour of frame. D, spatio-temporal characteristics of sparks located in T-tubule, A-band zone or in the zone of PNM. Duration and width of sparks were measured at half of amplitude. n = 9–67 as marked on bars. N, nucleus; PNM, perinuclear mitochondria; IMFM, intermyofibrillar mitochondrion.

Representative images in Fig. 9C show typical sparks from thePNM and IMFM zones (scans through lines marked in Fig. 9B).The sparking activity on the PNM zone was about 10 times less.However, based on our morphological data this can be attributedto a much lower density of RyR2s rather than to the macromolecularorganization of the groups of RyR2s producing Ca²⁺ sparks. Asshown in Fig. 9D, the spatio-temporal characteristics of Ca²⁺sparks (except duration) were not significantly different fromthose from Z-line or A-band zones, whereas sparks from the zoneof perinuclear mitochondria were about 25% longer. The similarityof the spatio-temporal characteristics of sparks from Z-lineor A-band zones of ventricular cells suggests a similarity inthe ultrastructural organization of macromolecular regulatorycomplexes of the groups of RyR2s producing sparks.

Organization of groups of RyR2s producing sparks

How RyR2s within a cluster are regulated is poorly understood.In principle, the individual RyR2 that is first activated ina cluster of up to 300 or more could influence the ‘centreof mass’ of the resulting Ca²⁺ spark. Paradoxically, itappears to activate only 10–20 RyR2s underlying the Ca²⁺spark (see Bers, 2001). To test whether this group is organizedspontaneously around the first opened RyR2 or whether it isa structurally discrete group, we recorded ‘repetitive’spontaneous sparks. If a single RyR2 spontaneously activatesa group of RyR2s within the junctional cluster, we should seean equal distribution of shortest distances between spontaneoussparks. If a single RyR2 activates a discrete group of RyR2s,the mean smallest distance will give us some understanding ofthe group size.

Only a few sparks arose exactly in the same location, whileother sparks that looked ‘repetitive’ were locatedas far as 0.2 µm from nearest spark (Fig. 10A). Figure 10Ashows one or two exceptionally active clusters of RyR2s (markedwith an oval). Note, although the same cluster produces multiplesparks, the place of spark origination varies. This shows thatthe Ca²⁺ spark could be produced by different groups of RyR2swithin the same cluster.

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Figure 10. Repetitive sparks in ventricular cells
A, disproportionate activity of RyR2 clusters in ventricular cells. Centers of recorded sparks are marked with circles. Ca²⁺ sparks were recorded after pretreatment of permeabilized ventricular cells with 0.1 µM Bodipy-TR-X ryanodine and 25 µM fluo-3 (pentapotassium salt). Excitation/emission, 488/505 nm. Optical slice < 1 µm. B, distribution of shortest distances between repetitive sparks (n = 53). C, the diagram shows distribution of putative functional groups of RyR2s within a RyR2 cluster depending on their shape, square (set of black boxes) or round (red ring). Centres of spark mass are shown with red circles. Blue and black arrows show two points of view in Z direction depending on orientation of the cluster. Blue and black lines show corresponding distances between centres of mass.

Figure 10B shows the distribution of the shortest distancesbetween sparks. The jSR can fully wrap around a T-tubule (Parfenov et al. 2006).If Ca²⁺ sparks belong to the same cluster, the distance betweenthem on the x–y image cannot readily exceed 400 nm (maximaldiameter of T-tubule plus two junctional cleft distances). Therefore,we measured all shortest distances between sparks that did notexceed 400 nm. On average, the shortest distance between sparkswas 162 ± 9 nm (n = 53). This is equal to the dimensionsof only three RyR2s ( $~$ 27 nm each) from a section of checkeredarray (Yin et al. 2005).

Note that in the case of expected squared groups of RyR2s, the3-D differences in spark locations could be ignored for measurementsof the group size. Previously we showed that isolated ventricularcells are flat and ultrathin sections through myocytes platedon coverslips usually are perpendicular to T-tubules (Parfenov et al. 2006).Therefore, optical slices in our experiments were also mainlyperpendicular to T-tubules (i.e. to jSR and junctional RyR2clusters). The diagram presented in Fig. 10C shows two possibleviews on the cluster in the Z-direction (blue and black arrows).It can be seen that, if RyR2s are combined in squared groups,the depth of origination of the spark can be ignored and thesize of the side of the group will be equal (‘blue’direction) or smaller (‘black’ direction) than thedistance between centres of spark masses. In this case the numberof sparks in the functional group could be $~$ 18. In the case ofa round group (red circles), the mean distance independent ofthe point of view will be equal to or smaller than the diameterof the group. For the case presented in Fig. 10C, the diameterof the group will be up to 212 nm (i.e. square root from 2x²)and the group will include $~$ 25 RyR2s. Thus, we suggest that thefunctional group of RyR2s might include 18–25 RyR2s.

Discussion

Top
Abstract
Introduction
Methods
Results
Discussion
References

We investigated the distribution of RyR2s in rat ventricularmyocytes using electron microscopy and different immunofluorescencemethods. RyR2s are found abundantly at the Z-line as reportedwidely by others. It is important, however, that RyR2s werealso found in the A-band and in the perinuclear region. Furthermore,Ca²⁺ sparks were found at these regions as well, suggestingthat functional groups of RyR2s occur in the depth of the ventricularmyocyte at non-traditional locations. It is plausible that Z-lineCa²⁺ sparks arise from RyR2 clusters in the jSR whereas theperinuclear Ca²⁺ sparks or sparks in the middle of sarcomerearise from groups of RyR2s in these regions of the SR. LocalCa²⁺ signalling due to these RyR2 clusters is likely to influencemitochondrial and nuclear function in addition to the influenceexerted by both normal and pathological global Ca²⁺ signals.Some of the issues and controversies related to our findingsare discussed below.

Electron microscopy

Shacklock et al. (1995) showed that only 85% of the Ca²⁺ sparksevoked by electrical stimulation occurred within 0.5 µmof a T-tubule in rat ventricular cells. This is similar to the78% for the same region shown in our experiments for spontaneousCa²⁺ sparks (Fig. 8C). Although, these authors mentioned thepossibility of input from the cSR in their experiments (i.e.from voltage-independent sparks), the existence of 15% of sparksbetween Z-lines could also mean that groups of RyR2s, such asthose producing sparks in the jSR, also exist along axial tubulesof TATS. To find out whether A-band RyR2s are associated withthe jSR along these TATS tubules, we studied TATS contacts onimages after conventional fixation followed by Epon embedding.If longitudinal tubules of the TATS have junctions with SR similarto jSR, this should be seen in the middle of the sarcomere aswell as jSR around T-tubules. Nevertheless, we found only twostructures slightly similar to the jSR.

Although Epon embedding allowed excellent visualization of themost delicate intracellular membrane structures in the PNM zoneincluding the Golgi complex (data not shown), it did not revealstructures similar to RyR2 clusters within the zone of PNM andthe A-band zone. However, the feet (i.e. RyR2s; Franzini-Armstrong, 1973)could be seen much better in the junctional cleft due to thevery specific organization of RyR2s near the T-tubule membraneand from the penetration of the dye into the body of the section.Clusters of jSR RyR2s organized along the membrane would beeasily recognized without immunostaining because of the specificpattern. However, the clarity of their visualization definitelydepends on the angle of the cut. Figure 2B shows a slightlyoblique section through a T-tubule fully wrapped by the jSR.Note that only five to six out of the possible 17–18 RyR2sare seen around the T-tubule. Oblique sectioning definitelyreduces the visualization of other RyR2s. This could resultfrom mechanisms of stain penetration into the body of ultrathinsections. A stain penetrates into the sections primarily throughsites where the structure intersects the surface (Shalla et al. 1964).Although Epoxy resins bind more strongly to proteins, it ispossible that a network of dye channels could appear (as cracks)on the border between the resin and protein during polymeralization(Shalla et al. 1964; Peters et al. 1971). In other words, dueto structural coupling (Marx et al. 2001) every RyR2 could bemarked with the stain in the body of the section. In this case,the size of the ultrathin section will allow visualization ofthree layers of RyR2s. However, because of the checkered orderand the shadowgram nature of electron microscopy, they willbe seen as a chain of darker and lighter bodies, where the formerresults from sum of two RyR2 homotetramers, and the latter froma single RyR2 homotetramer. If this is true, the single RyR2homotetramer has to be relatively invisible on micrographs andthis explains the small number of structures similar to thefeet found in the middle of the sarcomere. Note that this numberis not proportional to $~$ 20% of Ca²⁺ sparks we found in this zone.

Sparks are produced by groups of at least 10 RyR2s (Lukyanenko et al. 2000).Therefore, it is very important that our electron microscopyapproach allowed us to reveal nSR platforms in the middle ofthe sarcomere, where groups of up to 20 RyR2s could be located(Fig. 1C). It is interesting that the middle of the sarcomereis a place where the nSR can be relatively stable in a contractingventricular cell. Figure 1D shows that some mitochondria havean invagination filled with nSR in the middle of the sarcomere.Independent of the nature of the invagination (this could bean artifact of the preparation for electron microscopy), thisdemonstrates that M-rete has intimate contact with mitochondria.

Localization of RyR2s with immunofluorescence

We used ventricular cells permeabilized with saponin beforeor after fixation. The labels were located not only along Z-lines,but also along the myofibrils and within the A-band (i.e. inthe nSR; Fig. 4A). Longitudinal bands between Z-lines may notrepresent portions of the axial T-tubules filled with secondaryantibodies because control experiments did not show any clearfluorescence from this region (Fig. 4B). Recently Chen-Izu et al. (2006)also showed the existence of RyR2s in the middle of the ventricularsarcomere but only in regions close to the outer membrane. Afterfixation and long-term delivery of antibodies we found a similardistribution of RyR2s in the whole cell (Fig. 4C and D). Deconvolvedimages from cells after fixation in paraformaldehyde (Fig. 4C and D)showed clear fluorescence from the A-band and the PNM zone.

Earlier a similar longitudinal distribution of fluorescent labellingwas shown only for SERCA (Jorgensen et al. 1982) and phospholamban(Jorgensen & Jones, 1987). Thus, to have additional evidencefor RyR2 location between the Z-lines, we performed immunostainingfor calsequestrin. Calsequestrin was shown to be associatedstructurally and functionally linked to RyR2s (Jones et al. 1995;Sitsapesan & Williams, 1997; Györke et al. 2004). Thedistribution of calsequestrin appears similar to the distributionof RyR2s in our experiments. Double labelling for RyR2s andcalsequestrin (two experiments; data not shown) also confirmedtheir colocalization.

Unfortunately, we cannot conclude anything about the proportionof Z-lines and A-band RyR2s because of significant restrictionsin the diffusion of antibodies to the junctional cleft and tothe middle of the sarcomere (Parfenov et al. 2006). In addition,weak longitudinal and strong transverse labelling of RyR2s couldresult from differences in longitudinal and transverse diffusionof IgGs. A similar distribution was shown earlier for particles $≥$ 6 nm within 10 min after entering a permeabilized ventricularcell (Parfenov et al. 2006), for glycogen granules in intactventricular cells (Fawcett & McNutt, 1969), and for enhancedgreen fluorescent protein expressed in isolated ventricularcells (Salnikov et al. 2007). However, our control experimentsshowed no signs of such grid labelling when only the secondaryantibody was used (Figs 4B and 5B) or revealed a totally differentpattern of labelling when we performed immunolabelling for thecytoskeletal protein ${alpha}$ -tubulin (Fig. 5C).

Thus, we conclude that our immunofluorescent data showed thatRyR2s are localized not only in the junctional cleft, but alsoin the nSR around IMFMs and around the PNMs.

Comparison of spontaneous Ca²⁺ sparks produced in different cellular subdomains

We imaged Ca²⁺ sparks to find out whether functional groupsof RyR2s existed in the middle of the A-band and in the perinuclearregion. Such sparks, if found, could have similar or differentproperties from jSR Ca²⁺ sparks. Without defining function,there is no reason to assume orthodox Ca²⁺ spark behaviour.There were, however, published results on prolonged perinuclearCa²⁺ signals originating from the Golgi apparatus (Yang &Steele, 2005, 2007) that suggested we would observe non-standardCa²⁺ sparks.

Ca²⁺ sparks were observed in the A-band region and in the perinuclearregion. The sparks from these zones of the cell had a differentfrequency but generally similar characteristics (Fig. 9D) tonormal Ca²⁺ sparks. The frequency of PNM sparks was $~$ 2 timeslower than the frequency of sparks in the middle of the sarcomere,and 10 times lower than the frequency of sparks in the Z-linezone. However, the difference in spark frequency cannot be discussedwithout knowing the proportion of RyR2s in these zones, whichunfortunately remains unknown. The much smaller number of RyR2sfound within the zones in our immunofluorescence experimentscould explain the differences.

Similarity between spatio-temporal characteristics of spontaneousCa²⁺ sparks from jSR and non-junctional regions were recentlyshown for atrial cells (Sheehan et al. 2006), where input fromout-of-focus sparks should be the same for cell centre and periphery.Sparks from the PNM zone had a slightly longer duration in comparisonto sparks from Z-line and A-band zones. The $~$ 25% longer durationof PNM sparks could be explained by (1) input from out-of-focussparks, (2) by lower Ca²⁺ buffering as a result of the lackof troponin C in the PNM zone, (3) by the activation of additionalCa²⁺ release from mitochondria (Maack et al. 2006), and/or (4)by the RyR2s of the Golgi apparatus (Yang & Steele, 2005, 2007).Under our recording conditions, we did not see Ca²⁺ releaseevents with the spatio-temporal characteristics described byYang & Steele (2005, 2007) (width, $~$ 5 µm; duration, $~$ 1.8 s). This inconsistency in results could be ascribed to thesignificant difference in our experimental solutions.

That we observed normal appearing Ca²⁺ sparks in non-standardlocations suggests that a jSR-like organization might be foundat the spark site. However, Jorgensen and co-authors (Jorgensen & McGuffee, 1987;Jorgensen et al. 1993) showed the absence of calsequestrin innSR, and that only cSR and jSR contained both calsequestrinand RyR2s. The functional importance of calsequestrin to Ca²⁺release function was shown by Györke et al. (2004) whofound that the calsequestrin complex with triadin1 and junctinappears to play a role in the regulation of Ca²⁺ leak throughRyR2s in ventricular cells. Calsequestrin is thought to inhibitRyR2s by decreasing the amplitude and duration of sparks andthe combination of the calsequestrin–triadin–junctincomplex with RyR2s enables the RyR2 gating to be affected bychanges in [Ca²⁺] in the SR lumen, an important feature of normalCa²⁺ spark behaviour (Lukyanenko et al. 1996, 1998, 2000, 2001).In other words, without RyR2s bound to calsequestrin, Ca²⁺ sparksin the middle of the sarcomere must have higher amplitude andfrequency than sparks from the Z-line zone. Our finding of similaritybetween sarcomeric sparks tends to support the idea that calsequestrinand RyR2s are colocalized also in the middle of sarcomere.

The question remains what physical and functional structurescan account for our observations. Could nSR platforms in themiddle of sarcomere be responsible for the non-standard Ca²⁺sparks? While the cSR may not be in the middle of the A-band,a recent report suggests that the location of cSR is broaderthan previously thought (Franzini-Armstrong et al. 2005).

As discussed above, the nSR platforms could provide space fora group of about 20 RyR2s. Our analysis showed that a functionalgroup of RyR2s producing a spark could be approximately 18–25RyR2s. Originally Cheng et al. (1993) estimated that Ca²⁺ flowassociated with spark is $~$ 40 fC and proposed that it could beinduced by single RyR2 (4 pA during 10 ms). However, later itwas shown that under near-physiological ionic conditions theCa²⁺ current through the single RyR2 is less than 0.4 pA (Mejia-Alvarez et al. 1999;Kettlun et al. 2003). Reduction of time of underlying Ca²⁺ flowto 4 ms (Bers, 2001) increased number of channels contributingto the single spark to 20 RyR2s. Specific experiments (Lukyanenko et al. 2000)and calculations (Soeller & Cannell, 2002) performed tofind the number of RyR2s underlying Ca²⁺ sparks resulted insuggestions of 10–13 RyR2s. Thus, our numbers are in goodagreement with previous results and support the existence ofultrastructural RyR2 unit producing elementary Ca²⁺ release.The difference between the minimum number of RyR2s and our 18–25RyR2s suggests the possible existence of non-functional RyR2s.They could be located on the border of the group. Such RyR2scould be permanently in a blocked conformational state. In thiscase coupling between RyR2s could exist only within the bordersof the non-functional RyR2s. This could partially explain thefunctional integrity of the group.

Possible role for non-junctional clusters of RyR2s located around PNMs and IMFMs

Because of their Ca²⁺ sensitivity, non-junctional RyR2s shouldbe involved in excitation–contraction coupling throughCa²⁺-induced Ca²⁺ release under some conditions. They of coursewould not be triggered by L-type Ca²⁺ channels (DHPRs) unlessone (or more) is close enough. It should be remembered, however,that DHPRs could still be present in the axial tubules evenif we have not yet visualized them. If present and apposed tothe RyR2 clusters, DHPRs could trigger A-band Ca²⁺ sparks. Wehave found no evidence for or against this possibility. As forall Ca²⁺ spark sites, if the SR becomes overloaded with Ca²⁺,RyR2 instability could develop (Lukyanenko et al. 2001) andthese A-band RyR2 clusters could contribute to propagating CICR.

The data presented here support our mathematical model prediction(Subramanian et al. 2001) for the existence of functional Ca²⁺release sites between Z-lines in rat ventricular myocytes. Thismodel explored the mechanisms of circular Ca²⁺ wave propagationin ventricular cells. When it was based on the classical schemefor the distribution of Ca²⁺ release sites, it failed to reproducea circular wave. Only incorporation of 20% of the sites in themiddle of a sarcomere would allow the Ca²⁺ wave to spread withroughly the same velocity longitudinally and transversely, accordingto this model. The ‘Ca²⁺ release sites’ in the modelare not single RyR2s, but groups of RyR2s able to produce elementaryCa²⁺ release (i.e. a spark). The model suggests that about 20%of spontaneous sparks should arise from the middle of the sarcomere.In this manner, during Ca²⁺ overload, the Z band Ca²⁺-releasesites would contribute to arrhythmogenic CICR. Under normalconditions, however, these ‘non-orthodox’ Ca²⁺-releasesites could contribute to excitation–contraction coupling,to mitochondrial and nuclear signalling and to Ca²⁺-dependentgene regulation.

Trafficking. Trafficking of proteins in the heart is largely unexplored territory.We should consider the possibility that the perinuclear Ca²⁺sparks and RyR2s found there may reflect trafficking elementsthat have some function. Certainly the large size and organizationof the RyR2 at the jSR suggests that special issues regardingthe trafficking of these proteins may exist. The replacementof aged proteins in huge junctional clusters of RyR2s wouldbe clumsy if not impossible. Recently we showed (Parfenov et al. 2006)that the junctional cleft in permeabilized ventricular cellsis not available even for 3 nm particles. Meanwhile, each RyR2homotetramer itself has dimensions of about 28 nm x 28 nm x23 nm (Sharma et al. 1998) and some of the regulatory proteinsfor RyR2s may be as large as 10 nm in diameter (proteins withmolecular weights of 62–156 kDa were shown to have a radiusof 3.4–7.2 nm; Vandegriff et al. 1997). Therefore, itis possible (likely) that the complexes between RyR2s and regulatoryproteins are assembled outside of the junctional cleft.

References

Top
Abstract
Introduction
Methods
Results
Discussion
References

Bers DM (2001). Excitation-Contraction Coupling and Cardiac Contractile Force. Kluwer Academic Publishers, Dordrecht, The Netherlands.

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