Excitation-contraction coupling and mechano-sensitivity in denervated skeletal muscles

Francini, Fabio; Squecco, Roberta

doi:10.4081/ejtm.2010.1808

Cited by 3 publications

(2 citation statements)

References 70 publications

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“…This suggests a leaky sarcolemma and a reduced cytoskeleton expression/activity that, in turn, induces an increase of the intracellular Ca 2+ concentration, which was confirmed by the negative shift of the Ltype Ca 2+ current reversal potential. Moreover, the alteration of the cytoskeleton may not only increase the mechano-sensitivity of SACs but also that of L-type Ca 2+ channels [6]. The shift towards more positive potentials of L-type Ca 2+ current activation is directly involved in ECC and was formerly observed in the slow skeletal muscle fibres of the frog by using ryanodine or ruthenium red.…”

Section: Resultsmentioning

confidence: 99%

Cytoskeleton, L-type Ca2+ and stretch activated channels in injured skeletal muscle

Francini

Squecco

2013

Eur J Transl Myol

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The extra-sarcomeric cytoskeleton (actin microfilaments and anchoring proteins) is involved in maintaining the sarco-membrane stiffness and integrity and in turn the mechanical stability and function of the intra- and sub-sarcoplasmic proteins. Accordingly, it regulates Ca2+ entry through the L-type Ca2+ channels and the mechano-sensitivity of the stretch activated channels (SACs). Moreover, being intra-sarcomeric cytoskeleton bound to costameric proteins and other proteins of the sarcoplasma by intermediate filaments, as desmin, it integrates the properties of the sarcolemma with the skeletal muscle fibres contraction. The aim of this research was to compare the cytoskeleton, SACs and the ECC alterations in two different types of injured skeletal muscle fibres: by muscle denervation and mechanical overload (eccentric contraction). Experiments on denervation were made in isolated Soleus muscle of male Wistar rats; forced eccentric-contraction (EC) injury was achieved in Extensor Digitorum Longus muscles of Swiss mice. The method employed conventional intracellular recording with microelectrodes inserted in a single fibre of an isolated skeletal muscle bundle. The state of cytoskeleton was evaluated by recording SAC currents and by evaluating the resting membrane potential (RMP) value determined in current-clamp mode. The results demonstrated that in both injured skeletal muscle conditions the functionality of L-type Ca2+ current, ICa, was affected. In parallel, muscle fibres showed an increase of the resting membrane permeability and of the SAC current. These issues, together with a more depolarized RMP are an index of altered cytoskeleton. In conclusion, we found a symilar alteration of ICa, SAC and cytoskeleton in both injured skeletal muscle conditions

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Section: Resultsmentioning

confidence: 99%

Cytoskeleton, L-type Ca2+ and stretch activated channels in injured skeletal muscle

Francini

Squecco

2013

Eur J Transl Myol

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“…This suggests that the phenomenon reflects excitation–contraction coupling, and that the denervated cell membrane responds to stretch by depolarisation. There are known to be stretch-activated channels on the surface of muscle cells, which become more sensitive after denervation, although their role is unclear 10 …”

Section: Discussionmentioning

confidence: 99%

Facial muscle contraction in response to mechanical stretch after severe facial nerve injury: Clapham's sign

Clapham

Thomas²,

Allen³

et al. 2011

J. Laryngol. Otol.

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Following severe or complete denervation, contraction of the facial muscles following mechanical stretch provides evidence of preservation of activity in the facial muscle's excitation-contraction apparatus. Further research will investigate the clinical significance of this sign and whether it can be used as an early predicator of the development of synkinesis, as well as its relevance to facial nerve grafting and repair.

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Cytoskeleton, L-type Ca2+ and stretch activated channels in injured skeletal muscle

Francini

Squecco

2013

Eur J Transl Myol

Self Cite

View full text Add to dashboard Cite

The extra-sarcomeric cytoskeleton (actin microfilaments and anchoring proteins) is involved in maintaining the sarco-membrane stiffness and integrity and in turn the mechanical stability and function of the intra-and sub-sarcoplasmic proteins. Accordingly, it regulates Ca 2+ entry through the L-type Ca 2+ channels and the mechano-sensitivity of the stretch activated channels (SACs). Moreover, being intra-sarcomeric cytoskeleton bound to costameric proteins and other proteins of the sarcoplasma by intermediate filaments, as desmin, it integrates the properties of the sarcolemma with the skeletal muscle fibres contraction. The aim of this research was to compare the cytoskeleton, SACs and the ECC alterations in two different types of injured skeletal muscle fibres: by muscle denervation and mechanical overload (eccentric contraction). Experiments on denervation were made in isolated Soleus muscle of male Wistar rats; forced eccentric-contraction (EC) injury was achieved in Extensor Digitorum Longus muscles of Swiss mice. The method employed conventional intracellular recording with microelectrodes inserted in a single fibre of an isolated skeletal muscle bundle. The state of cytoskeleton was evaluated by recording SAC currents and by evaluating the resting membrane potential (RMP) value determined in current-clamp mode. The results demonstrated that in both injured skeletal muscle conditions the functionality of L-type Ca 2+ current, ICa, was affected. In parallel, muscle fibres showed an increase of the resting membrane permeability and of the SAC current. These issues, together with a more depolarized RMP are an index of altered cytoskeleton. In conclusion, we found a symilar alteration of ICa, SAC and cytoskeleton in both injured skeletal muscle conditions.

show abstract

Excitation-contraction coupling and mechano-sensitivity in denervated skeletal muscles

Cited by 3 publications

References 70 publications

Cytoskeleton, L-type Ca2+ and stretch activated channels in injured skeletal muscle

Cytoskeleton, L-type Ca2+ and stretch activated channels in injured skeletal muscle

Facial muscle contraction in response to mechanical stretch after severe facial nerve injury: Clapham's sign

Cytoskeleton, L-type Ca2+ and stretch activated channels in injured skeletal muscle

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