Morphology of isolated triads.

Mitchell, Ryan D.; Saito, A; Palade, Philip; Fleischer, Sidney

doi:10.1083/jcb.96.4.1017

Cited by 54 publications

(19 citation statements)

References 49 publications

(43 reference statements)

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“…The JFM as isolated has a number of features that distinguish it from the calcium pump membrane. Morphologically, the membrane has characteristic feet structures oriented asymmetrically, and uniformly spaced, comparable to their arrangement in situ (14,29,33). Our standard preparation of JFM-CC (using 0.5% Triton and 1 mM CaC12) and JFM have a phospholipid content of 0.11 lamol P/mg protein and 0.16 gmol/mg protein, respectively (Table I).…”

Section: 2f*mentioning

confidence: 97%

Characterization of the junctional face membrane from terminal cisternae of sarcoplasmic reticulum.

Costello¹,

Chadwick²,

Saito³

et al. 1986

The Journal of Cell Biology

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112

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Abstract. We have recently described a preparation of junctional terminal cisternae (JTC) from fast skeletal muscle of rabbit hind leg. The fraction differs from other heavy sarcoplasmic reticulum (SR) fractions in that it contains a substantial amount of junctional face membrane (JFM) (15-20% of the membrane) with morphologically well-defined junctional feet structures. In common with other heavy SR preparations, it contains predominantly the calcium pump membrane (80-85 % of the membrane) and compartmental contents (CC), consisting mainly of calcium-binding protein (calsequestrin). In this study, a modified procedure for the preparation of JTC from frozen rabbit back muscle is described. The yield is substantially greater (threefold per weight of muscle), yet retaining characteristics similar to JTC from fresh hind leg muscles.Methodology has been developed for the disassembly of the JTC. This is achieved by selectively extracting the calcium pump membrane with 0.5 % Triton X-100 in the presence of 1 mM CaCI2 to yield a complex of JFM with CC. The CC are then solubilized in the presence of EDTA to yield JFM. This fraction contains unidirectionally aligned junctional feet structures protruding from the cytoplasmic face of the membrane with repeat spacings comparable to that observed in JTC. The JFM contains 0.16 lxmol phosphorus (lipid) per milligram protein. Characteristic proteins include 340 and 79-kD bands, a doublet at 28 kD, and a component that migrates somewhat slower than or equivalent to the calcium pump protein. Approximately 10% of the calcium-binding protein remains bound to the JFM after EDTA extraction, indicating the presence of a specific binding component in the JFM. The JFM, which is involved in junctional association with transverse tubule and likely in the Ca 2÷ release process in excitation-contraction coupling, is now available in the test tube.

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Section: 2f*mentioning

confidence: 97%

Characterization of the junctional face membrane from terminal cisternae of sarcoplasmic reticulum.

Costello¹,

Chadwick²,

Saito³

et al. 1986

The Journal of Cell Biology

Self Cite

112

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“…This treatment helps to separate T tubules from SR (26), but under prolonged use it results in the disappearance of feet (13). It was shown that the degradation of bridging structures is progressive (8), and by using a brief KCI treatment we preserved feet on our heavy SR vesicles, even though some were lost. We also obtained heavy SR vesicles from guinea pig muscle without using any KCI treatment, and in this preparation the feet had the same shape as in KCI washed vesicles, but were more numerous and more frequently maintained the original alignment in long rows.…”

Section: General Remarksmentioning

confidence: 99%

“…The "heavy" SR fraction contains vesicles whose origin from the lateral sacs of the triad (terminal cisternae) is deduced on the basis of electron-dense contents with CaE+-binding properties (12). Under the appropriate isolation conditions, heavy SR vesicles retain structures identifiable as feet on the portion of their surface (junctional SR) which was originally participating in triadic junctions (8,13,14). We have developed a procedure for exposing surface details in isolated membrane vesicles that faithfully preserves three-dimensional relationships.…”

mentioning

confidence: 99%

Subunit structure of junctional feet in triads of skeletal muscle: a freeze-drying, rotary-shadowing study.

Ferguson¹,

Schwartz²,

Franzini-Armstrong³

1984

The Journal of Cell Biology

150

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Isolated heavy sarcoplasmic reticulum vesicles retain junctional specializations (feet) on their outer surface. We have obtained en face three-dimensional views of the feet by shadowing and replicating the surfaces of freeze-dried isolated vesicles. Feet are clearly visible as large structures located on raised platforms. New details of foot structure include a four subunit structure and the fact that adjacent feet do not abut directly corner to corner but are offset by half a subunit. Feet aligned within rows were observed to be rotated at a slight angle off the long axis of the row creating a center-to-center spacing (32.5 nm) slightly less than the average diagonal of the feet (35.3 nm). Comparison with previous information from thin sections and freeze-fracture showed that this approach to the study of membranes faithfully preserves structure and allows better visualization of surface details than either thinsectioning or negative-staining.

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“…Depolarization of the plasma membrane of skeletal muscle leads to release of Ca 2+ from the SR resulting in muscle contraction, by a process known as excitation–contraction coupling (Schneider & Chandler, 1972; Melzer et al 1995; Berchtold et al 2000). Excitation–contraction coupling (EC coupling) occurs at the triad, a structure composed of the two membrane compartments, transverse tubules containing the voltage sensing dihydropyridine receptor (DHPR, an L‐type Ca 2+ channel) and terminal cisternae on which ryanodine receptor (RyR) Ca 2+ release channels are localized (Mitchell et al 1983; Rios & Pizarro, 1991). The disposition of DHPRs and RyRs on their respective membranes is highly ordered and each DHPR faces alternate rows of RyR tetramers (Fig.…”

Section: Calcium Homeostasis In Striated Musclesmentioning

confidence: 99%

Minor sarcoplasmic reticulum membrane components that modulate excitation–contraction coupling in striated muscles

Treves

Vukcevic

Maj

et al. 2009

The Journal of Physiology

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In striated muscle, activation of contraction is initiated by membrane depolarisation caused by an action potential, which triggers the release of Ca 2+ stored in the sarcoplasmic reticulum by a process called excitation-contraction coupling. Excitation-contraction coupling occurs via a highly sophisticated supramolecular signalling complex at the junction between the sarcoplasmic reticulum and the transverse tubules. It is generally accepted that the core components of the excitation-contraction coupling machinery are the dihydropyridine receptors, ryanodine receptors and calsequestrin, which serve as voltage sensor, Ca 2+ release channel, and Ca 2+ storage protein, respectively. Nevertheless, a number of additional proteins have been shown to be essential both for the structural formation of the machinery involved in excitation-contraction coupling and for its fine tuning. In this review we discuss the functional role of minor sarcoplasmic reticulum protein components. The definition of their roles in excitation-contraction coupling is important in order to understand how mutations in genes involved in Ca 2+ signalling cause neuromuscular disorders.

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Morphology of isolated triads.

Cited by 54 publications

References 49 publications

Characterization of the junctional face membrane from terminal cisternae of sarcoplasmic reticulum.

Characterization of the junctional face membrane from terminal cisternae of sarcoplasmic reticulum.

Subunit structure of junctional feet in triads of skeletal muscle: a freeze-drying, rotary-shadowing study.

Minor sarcoplasmic reticulum membrane components that modulate excitation–contraction coupling in striated muscles

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