Brunel University London - Introduction to Medical Sciences 1 - Sarcomeres and Sliding Filament Theory Part 1 PDF

Summary

This document is lecture notes from Brunel University London on cell signaling and movement, specifically focusing on sarcomeres and sliding filament theory. Part 1 details the anatomy and organization of skeletal muscle.

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Introduction to Medical Sciences 1

Cell Signalling and Movement
Sarcomeres and Sliding Filament Theory Part 1
Copyright © Brunel University London v.3 2024. All rights reserved.
Cell Signalling and Movement

Dr Julianna Gal

Version 3

2024

Copyright © Brunel University London v.3 2024. All rights reserved.
Cell Signalling and Movement

Sarcomeres and Sliding Filament Theory Part 1

Copyright © Brunel University London v.3 2024. All rights reserved.
Sarcomeres and Sliding Filament Theory

Part 1: Skeletal muscle organisation and structure of sarcomeres
Part 2: Skeletal muscle contraction and the sliding filament theory
Part 3: Control of skeletal muscle force and role of calcium

Copyright © Brunel University London v.3 2024. All rights reserved.
Sarcomeres and Sliding Filament Theory

Part 1: Skeletal muscle organisation and structure of sarcomeres

Overview
Anatomic organisation of skeletal muscle
Fine ultrastructure of skeletal muscle
Focus on the sarcomere, key biomolecules and their organisation

Copyright © Brunel University London v.3 2024. All rights reserved.
 Skeletal muscles come in a wide variety of shapes and sizes

Iliopsoas
Tensor
fasciae
latae
Adductor
longus

Sartorius

Biceps brachii- Biceps brachia- Latissimus dorsi
short head long head
Vastus
medialis
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All skeletal muscles have: Tendon of origin
Muscle belly
Tendon of insertion

Skeletal muscles typically connect one bone to another, crossing at least
one joint
Muscle belly is the site of active force production
When stimulated by central nervous system, muscle belly generates
contractile or pulling-type force
Contractile force pulls equally on tendon of insertion and tendon of origin
What we see as the outcome of a skeletal muscle contraction depends
upon the NET effect of all forces at each end of the muscle

How does skeletal muscle actively generate force?
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Organisation of
skeletal muscle

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 Scanning electron
micrograph showing the tiny
collagen fibres of the
endomysium that bind
skeletal muscle cells
together (x 200)

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Active force production occurs within the muscle cell

Muscle cells (muscle fibres) are packed with:

Myofibrils (force)
Nuclei (repair, adaptation)
Mitochondria (energy)

How is the muscle cell organised to produce force?

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 Light micrograph of part
of skeletal muscle fibre Cross striation
pattern is clear.
Elongated nuclei
are located in the
peripheral areas
Electron of cell. 1200 x
micrograph
of part of
skeletal A A-band
muscle I I-band
Mi mitochondrion
fibre N nucleus
Z Z-line

Dark and light bands are arranged in series along length of muscle fibre
and show lateral registration with adjacent myofibrils. 3000 x
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Electron micrograph of a relaxed sarcomere
in longitudinal section 14,000 x
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 Microscopy and myosin
biochemistry give (contractile)
evidence for a complex
arrangement of proteins
within each sarcomere

actin, troponin, tropomyosin
(regulatory)

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Proteins which play a supportive role within
skeletal muscle, e.g., nebulin and titin
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Myosin heads forming cross bridges that generate muscular contractile force.
Part of a sarcomere is seen in a transmission electron micrograph (277,000 X)

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Summary
Skeletal muscle contains significant amount of connective tissue:
endomysium, perimysium and epimysium
A skeletal muscle fibre IS a skeletal muscle cell
The sarcomere is the site of force production
Sarcomeres contain important molecules including myosin, actin,
troponin, tropomyosin, nebulin and titin

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Slide figures adapted from the following sources

Slide 6
Gosling, J.A. Human Anatomy, Color Atlas and Textbook, Chapter 3,
71-133. Copyright 2017, Elsevier Ltd.
Gosling, J.A. Human Anatomy, Color Atlas and Textbook, Chapter 6,
253-319. Copyright 2017, Elsevier Ltd.
Gosling, J.A. Human Anatomy, Color Atlas and Textbook, Chapter 3,
71-133. Copyright 2017 Elsevier Ltd.
Slide 7
Kierszenbaum, Abraham L. Histology and Cell Biology: An
Introduction to Pathology, 7, 237-260. Copyright 2020, Elsevier, Inc.

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Slide 8
Borg, T.K., and Caulfield J.B. Morphology of connective tissue in
skeletal muscle. Tissue and Cell, Vol. 12, pp. 197-207. Copyright
1980, Longman Group, Ltd.
Slide 10
Ovalle, William K. Netter's Essential Histology, 4, 77-107. Copyright
2021, Elsevier, Inc.
Slide 11
Ovalle, William K. Netter's Essential Histology, 4, 77-107. Copyright
2021, Elsevier, Inc.
Slide 12
Moczydlowski, Edward G. Boron and Boulapaep Concise Medical
Physiology, Chapter 9, 100-114. Copyright 2021, Elsevier, Inc.

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Slide 13
Kierszenbaum, Abraham L. Histology and Cell Biology: An
Introduction to Pathology, 7, 237-260. Copyright 2020, Elsevier,
Inc.
Slide 14
Marieb, E.N. and Hoehn, K. Human Anatomy & Physiology Ninth
Edition. p. 284. Copyright 2013, Pearson Education, Inc.

Copyright © Brunel University London v.3 2024. All rights reserved.
Dr Julianna Gal

Copyright © Brunel University London v.3 2024. All rights reserved.