Separation of detubulation and vacuolation phenomena in amphibian skeletal muscle

Sarah J Cooper; Sangeeta Chawla; James A Fraser; Jeremy N Skepper; Christopher L H Huang

Separation of detubulation and vacuolation phenomena in amphibian skeletal muscle

Sarah J Cooper, Sangeeta Chawla, James A Fraser, Jeremy N Skepper, Christopher L H Huang

Biology

Research output: Contribution to journal › Article › peer-review

Abstract

Sartorius muscle fibres from cold-adapted Rana temporaria were exposed to variants of an established detubulation procedure (Koutsis et al. (1995) J Muscle Res Cell Motil 16, 519-528) to test the extent to which detubulation and tubular vacuolation phenomena could be separated using different conditions of osmotic shock. A control procedure was optimised to a 28-min exposure to 400 mM glycerol-Ringer. This was followed by a recovery step involving its replacement by a Ca2+/Mg(2+)-Ringer solution and steady cooling over 30 min from room temperature (approximately 18 degress C) to approximately 10 degress C, followed by the restoration of the normal Ringer solution. This procedure successfully abolished the action potential after-depolarisation component, reflecting a loss of tubular conduction ('detubulation') in 74.3 +/- 5.9% of the fibres studied. Omitting the cooling during the recovery step sharply reduced the incidence of detubulation. So did omitting either the high-[Ca2+] and/or [Mg2+] in the recovery solutions in test procedures, but to significantly different extents (P <5%). Yet trapping of fluorescent Sulfhorhodamine B dye in 'closed' vacuoles persisted albeit with reduced proportions of fibre volume occupied by vacuoles. Furthermore, the variations in recovery conditions produced similar levels of vacuolation despite smaller vacuole sizes in the cooled fibres (P <0.05). These findings demonstrate that fibre vacuolation and detubulation are phenomena that are potentially separable through varying the conditions of osmotic shock, with detubulation requiring significantly more stringent conditions than vacuolation.

Original language	English
Pages (from-to)	327-33
Number of pages	7
Journal	Journal of muscle research and cell motility
Volume	23
Issue number	4
Publication status	Published - 2002

Keywords

Action Potentials
Animals
Body Temperature
Calcium
Calcium Signaling
Fluorescent Dyes
Ion Channels
Isotonic Solutions
Magnesium
Microtubules
Muscle Contraction
Muscle Fibers, Skeletal
Muscle, Skeletal
Osmotic Pressure
Rana temporaria
Sarcolemma
Vacuoles

Cite this

@article{d2f43f8b61594d5e893cd057bf49a4c6,

title = "Separation of detubulation and vacuolation phenomena in amphibian skeletal muscle",

abstract = "Sartorius muscle fibres from cold-adapted Rana temporaria were exposed to variants of an established detubulation procedure (Koutsis et al. (1995) J Muscle Res Cell Motil 16, 519-528) to test the extent to which detubulation and tubular vacuolation phenomena could be separated using different conditions of osmotic shock. A control procedure was optimised to a 28-min exposure to 400 mM glycerol-Ringer. This was followed by a recovery step involving its replacement by a Ca2+/Mg(2+)-Ringer solution and steady cooling over 30 min from room temperature (approximately 18 degress C) to approximately 10 degress C, followed by the restoration of the normal Ringer solution. This procedure successfully abolished the action potential after-depolarisation component, reflecting a loss of tubular conduction ('detubulation') in 74.3 +/- 5.9% of the fibres studied. Omitting the cooling during the recovery step sharply reduced the incidence of detubulation. So did omitting either the high-[Ca2+] and/or [Mg2+] in the recovery solutions in test procedures, but to significantly different extents (P <5%). Yet trapping of fluorescent Sulfhorhodamine B dye in 'closed' vacuoles persisted albeit with reduced proportions of fibre volume occupied by vacuoles. Furthermore, the variations in recovery conditions produced similar levels of vacuolation despite smaller vacuole sizes in the cooled fibres (P <0.05). These findings demonstrate that fibre vacuolation and detubulation are phenomena that are potentially separable through varying the conditions of osmotic shock, with detubulation requiring significantly more stringent conditions than vacuolation.",

keywords = "Action Potentials, Animals, Body Temperature, Calcium, Calcium Signaling, Fluorescent Dyes, Ion Channels, Isotonic Solutions, Magnesium, Microtubules, Muscle Contraction, Muscle Fibers, Skeletal, Muscle, Skeletal, Osmotic Pressure, Rana temporaria, Sarcolemma, Vacuoles",

author = "Cooper, {Sarah J} and Sangeeta Chawla and Fraser, {James A} and Skepper, {Jeremy N} and Huang, {Christopher L H}",

year = "2002",

language = "English",

volume = "23",

pages = "327--33",

journal = "Journal of muscle research and cell motility",

issn = "0142-4319",

publisher = "Springer",

number = "4",

}

TY - JOUR

T1 - Separation of detubulation and vacuolation phenomena in amphibian skeletal muscle

AU - Cooper, Sarah J

AU - Chawla, Sangeeta

AU - Fraser, James A

AU - Skepper, Jeremy N

AU - Huang, Christopher L H

PY - 2002

Y1 - 2002

N2 - Sartorius muscle fibres from cold-adapted Rana temporaria were exposed to variants of an established detubulation procedure (Koutsis et al. (1995) J Muscle Res Cell Motil 16, 519-528) to test the extent to which detubulation and tubular vacuolation phenomena could be separated using different conditions of osmotic shock. A control procedure was optimised to a 28-min exposure to 400 mM glycerol-Ringer. This was followed by a recovery step involving its replacement by a Ca2+/Mg(2+)-Ringer solution and steady cooling over 30 min from room temperature (approximately 18 degress C) to approximately 10 degress C, followed by the restoration of the normal Ringer solution. This procedure successfully abolished the action potential after-depolarisation component, reflecting a loss of tubular conduction ('detubulation') in 74.3 +/- 5.9% of the fibres studied. Omitting the cooling during the recovery step sharply reduced the incidence of detubulation. So did omitting either the high-[Ca2+] and/or [Mg2+] in the recovery solutions in test procedures, but to significantly different extents (P <5%). Yet trapping of fluorescent Sulfhorhodamine B dye in 'closed' vacuoles persisted albeit with reduced proportions of fibre volume occupied by vacuoles. Furthermore, the variations in recovery conditions produced similar levels of vacuolation despite smaller vacuole sizes in the cooled fibres (P <0.05). These findings demonstrate that fibre vacuolation and detubulation are phenomena that are potentially separable through varying the conditions of osmotic shock, with detubulation requiring significantly more stringent conditions than vacuolation.

AB - Sartorius muscle fibres from cold-adapted Rana temporaria were exposed to variants of an established detubulation procedure (Koutsis et al. (1995) J Muscle Res Cell Motil 16, 519-528) to test the extent to which detubulation and tubular vacuolation phenomena could be separated using different conditions of osmotic shock. A control procedure was optimised to a 28-min exposure to 400 mM glycerol-Ringer. This was followed by a recovery step involving its replacement by a Ca2+/Mg(2+)-Ringer solution and steady cooling over 30 min from room temperature (approximately 18 degress C) to approximately 10 degress C, followed by the restoration of the normal Ringer solution. This procedure successfully abolished the action potential after-depolarisation component, reflecting a loss of tubular conduction ('detubulation') in 74.3 +/- 5.9% of the fibres studied. Omitting the cooling during the recovery step sharply reduced the incidence of detubulation. So did omitting either the high-[Ca2+] and/or [Mg2+] in the recovery solutions in test procedures, but to significantly different extents (P <5%). Yet trapping of fluorescent Sulfhorhodamine B dye in 'closed' vacuoles persisted albeit with reduced proportions of fibre volume occupied by vacuoles. Furthermore, the variations in recovery conditions produced similar levels of vacuolation despite smaller vacuole sizes in the cooled fibres (P <0.05). These findings demonstrate that fibre vacuolation and detubulation are phenomena that are potentially separable through varying the conditions of osmotic shock, with detubulation requiring significantly more stringent conditions than vacuolation.

KW - Action Potentials

KW - Animals

KW - Body Temperature

KW - Calcium

KW - Calcium Signaling

KW - Fluorescent Dyes

KW - Ion Channels

KW - Isotonic Solutions

KW - Magnesium

KW - Microtubules

KW - Muscle Contraction

KW - Muscle Fibers, Skeletal

KW - Muscle, Skeletal

KW - Osmotic Pressure

KW - Rana temporaria

KW - Sarcolemma

KW - Vacuoles

M3 - Article

C2 - 12630707

VL - 23

SP - 327

EP - 333

JO - Journal of muscle research and cell motility

JF - Journal of muscle research and cell motility

SN - 0142-4319

IS - 4

ER -