MOLECULAR PHYSIOLOGY

Muscular contraction

Tapasya Srivastava and Kunzang Chosdol Department of Biochemistry

All India Institute of Medical Sciences Ansari Nagar

New Delhi – 110 029

11-Jan-2007

CONTENTS

Introduction to muscles and its functions Types of muscles

Skeletal muscle Smooth muscles Cardiac muscle

Proteins that make up a skeletal muscle fibre Mechanism of muscle contractions

Metabolism of the muscle contraction

Disorders of skeletal muscle and smooth muscle Disease of neuromuscular junction

Keywords

Skeletal muscle; Smooth muscle; Cardiac muscle; Actin; Myosin; Tropomyosin; Troponin; Nebulin; Tinin;

Muscle contraction; Calcium; Sliding filament theory; Neuromuscular junction; Red muscle fibre; White muscle fibre; Creatine phosphate; ATP utilization; Disorder of muscle

Introduction to muscles and its functions

Muscles make up the bulk of the body and account for about one-third of its weight. Muscle tissue comprises of units of the muscle cell working in co-ordination with blood vessels, nerves and connective tissue to form the muscular system. There are around 640 named muscles in the human body - in addition to thousands of smaller (un-named) muscles.

Approximately 40 to 50 percent of the mass of the human body is composed of muscle tissue. The muscular system is composed of specialized cells called muscle fibers. Muscle fibers are contractile cells and their ability to contract not only provides a mechanism for movement of the internal organs and locomotion of the entire organism but also provides the force that pushes substances, such as blood and food, through the body. All movements of the body are a function of the muscular system.

The integrated action of joints, bones, and skeletal muscles produces obvious movements such as walking and running. Skeletal muscles also produce more subtle movements that result in various facial expressions, eye movements, and respiration. In addition to movement, muscle contraction also fulfills some other important functions in the body, such as posture, joint stability, and heat production. Posture, such as sitting and standing, is maintained as a result of muscle contraction. The skeletal muscles are continually making fine adjustments that hold the body in stationary positions. The tendons of many muscles extend over joints and in this way contribute to joint stability. This is particularly evident in the knee and shoulder joints, where muscle tendons are a major factor in stabilizing the joint.

Heat production, to maintain body temperature, is an important by-product of muscle metabolism. Nearly 85 percent of the heat produced in the body is the result of muscle contraction.

Types of muscles found in the body

There are three types of muscle tissue or muscles: skeletal, smooth, and cardiac. Each type has a different structure and plays a different role in the body.

Skeletal muscle

Function: Skeletal muscles are responsible for voluntary (conscious) movement. Skeletal muscles are generally attached to bones and are responsible for moving parts of the body, such as the limbs, trunk, and face. Most skeletal muscles are consciously controlled by the nervous system. These muscles usually contract voluntarily, meaning that you think about contracting them and your nervous system tells them to do so. They can do a short, single contraction (twitch) or a long, sustained contraction (tetanus). The mechanism of movement of these muscles will be explained in greater detail in this chapter.

Structure and organisation: Skeletal muscle consists of very long tubular cells (also called muscle fibres). The average length of skeletal muscle cells in humans is about 3 cm (sartorius muscle extends upto 30 cm and in contrast, stapedius muscle is only about 1 mm). Their diameters vary from 10 to 100 µm. Skeletal muscle fibres show characteristic cross-striations and therefore they are also called striated muscle. Skeletal muscle is innervated by the somatic nervous system. Skeletal muscle makes up the voluntary muscle. Fig. 1 shows the skeletal muscle of human tongue (H&E stain).

Fig. 1: Skeletal muscle of human tongue (H&E stain). Skeletal muscle in the tongue is arranged in bundles, which typically run at right angles to each other. Both longitudinally and transversely cut skeletal muscle fibres are present. In both section

planes the nuclei are located in the periphery of the muscle fibre and striations are visible in longitudinally cut fibres

Skeletal muscle fibres contain many peripherally placed nuclei. Up to several hundred rather small nuclei with 1 or 2 nucleoli are located just beneath the plasma membrane. These long and slender muscle fibres or cells vary in length from 1mm to 30 to 60 cm. Skeletal muscle fibers are grouped into dense bundles called fascicles, which make up the muscle. Varying movements require contraction of variable numbers of muscles fibers in a muscle. Muscle fibers work by an electrical stimulus initiated by the nervous system and to prevent the stimulus uncontrollably passing from one muscle fibre to another requires an insulation between adjoining muscle cells. This insulation is provided by a connective tissue. The muscle is surrounded by a layer of connective tissue - the epimysium, which is continuous with the muscle fascia. The epimysium is well vascularized and helps to bring blood vessels to all the muscle fibers of the muscle. This helps in providing a constant supply of oxygen.

And within the muscle, the bundles of muscle fibers called muscle fascicles are further bundled up by connective tissue extending from the epimysium, this connective tissue which extends into the muscle to surround individual fascicles is called perimysium. From the perimysium, another delicate network of reticular fibres surrounds each individual muscle fibre known as endomysium (Fig. 2). The connective tissue in a muscle, thus, transduces the force generated by the muscle fibres to the tendons. The collagen fibers of the endomysium and perimysium are interwoven and blend into one another. At each end of the muscle, the collagen fibers of the epimysium, perimysium, and endomysium come together to form a bundle known as a tendon or a broad sheet called an aponeurosis. Tendons and aponeuroses usually attach skeletal muscles to bones. Where a tendon attaches to a bone, the tendon fibers extend into the bone matrix, providing a firm attachment. As a result, any contraction of the muscle will exert a pull on its tendon and thereby on the attached bone (or bones).

A typical muscle cell responsible for movement

A muscle fiber is a single, multinucleated muscle cell. A muscle may be made up of hundreds or even thousands of muscle fibers, depending on the muscles size. Although muscle fiber makes up most of the muscle tissue, a large amount of connective tissue, blood vessels, and nerves are also present. Connective tissue covers and supports each muscle fiber and

reinforces the muscle as a whole. The health of muscle depends on a sufficient nerve and blood supply. Each skeletal muscle has a nerve ending that controls its activity. Active muscles use a lot of energy and require a continuous supply of oxygen and nutrients, which are supplied by arteries. Muscles produce large amounts of metabolic waste that must be removed by veins. Muscle fibers consist of bundles of threadlike structures called myofibrils.

Each myofibril is made up of two types of protein filaments- thick ones and thin ones. The thick filaments are made up of a protein called myosin. The thin filaments are made of a protein called actin. Myosin and actin filaments are arranged to form overlapping patterns, which are responsible for the light and dark bands that can be seen in skeletal (striated appearance) muscle. Thin actin filaments are anchored at their midpoints to a structure called the z-line. The region from one z-line to the next is called a sarcomere the functional unit of muscle contractions.

Epimysium

Perimysium Endomysium

Muscle fibre Epimysium

Perimysium Endomysium

Muscle fibre

Fig. 2: Cross section of the muscle showing Epimysium, Perimysium, Endomysium and Muscle fibres

The Muscle fiber

Skeletal muscle is made up of thousands of cylindrical muscle fibers often running all the way from origin to insertion. The fibers are bound together by connective tissue through which run blood vessels and nerves. Each muscle fibre contains an array of myofibrils that are stacked lengthwise and run the entire length of the fiber, mitochondria, an extensive endoplasmic reticulum and many nuclei. The multiple nuclei arise from the fact that each muscle fiber develops from the fusion of many cells (called myoblasts). The number of fibers is probably fixed early in life. This is regulated by myostatin, a cytokine that is synthesized in muscle cells (and circulates as a hormone later in life). Myostatin suppresses skeletal muscle development. Cattle and mice with inactivating mutations in their myostatin genes develop much larger muscles. Some athletes and other remarkably strong people have been found to carry one mutant myostatin gene. These discoveries have already led to the growth of an illicit market in drugs supposedly able to suppress myostatin. Anything that lowers the level of myostatin also leads to an increase in fiber size. In adults, increased strength and muscle mass comes about through an increase in the thickness of the individual fibers and increase in the amount of connective tissue. In the mouse, at least, fibers increase in size by attracting more myoblasts to fuse with them.

Because a muscle fiber is not a single cell, its parts are often given special names such as sarcolemma for plasma membrane, sarcoplasmic reticulum for endoplasmic reticulum, sarcosome for mitochondrion, sarcoplasm for cytoplasm. However, inspite of the nomenclature there is an essential similarity in structure and function of these structures and those found in other cells. The nuclei and mitochondria are located just beneath the plasma membrane and the endoplasmic reticulum extends between the myofibrils.

Depending on the distribution and interconnection of myofilaments a number of "bands" and

"lines" can be distinguished in the sarcomeres. The essential features of the sarcomere which is the functional unit of a muscle (Fig. 3) are as follows:

Fig. 3: The sarcomere showing thick and thin filaments. The average length of a sarcomere is about 2.5 µm (contracted ~1.5 µm, stretched ~3 µm)

• Each myofibril is made up of arrays of parallel filaments. The thick filaments produce the A band and have a diameter of about 15 nm. They are composed of the protein myosin. The thin filaments form the light I band and have a diameter of about 5 nm.

• The striated appearance of the muscle fiber is created by this pattern of alternating dark A bands and light I bands.

• The A bands are bisected by the H zone and at this juncture the thick and thin filaments do not overlap. The I bands are bisected by the Z line. The entire array of thick and thin filaments between the Z lines is called a sarcomere.

• They are composed chiefly of the protein actin along with smaller amounts of two other proteins: troponin and tropomyosin. M-line - band of connections between myosin filaments (mediated by proteins, e.g. myomesin, M-protein).

• Shortening of the sarcomeres in a myofibril produces the shortening of the myofibril and, in turn, of the muscle fiber of which it is a part.

Smooth muscles

Smooth muscles are usually not under voluntary control. These spindle-shaped muscle cells are of variable size have a single centrally placed nucleus. The chromatin is finely granular and the nucleus contains 2-5 nucleoli. They are not striated and interlace to form sheets of smooth muscle tissue. Smooth muscle fibers are surrounded by connective tissue, but the connective tissue does not unite to form tendons as it does in skeletal muscles. Most smooth

muscle cells can contract without nervous stimulation. The innervation of smooth muscle is provided by the autonomic nervous system. Smooth muscle has the ability to stretch and maintain tension for long periods of time. Because most of its movements are not consciously controlled, smooth muscle is referred to as involuntary muscle. Smooth muscles are found in many internal organs, stomach, intestines, and in the walls of blood vessels. The contractions in smooth muscles move food through our digestive tract, control the way blood flows through the circulatory system, and increases the size of the pupils of our eyes in bright light. The largest smooth muscle cells occur in the uterus during pregnancy (12x600 µm).

The smallest are found around small arterioles (1x10 µm).

Structure of smooth muscle

In the cytoplasm, we find longitudinally oriented bundles of the myofilaments actin and myosin. Actin filaments insert into attachment plaques located on the cytoplasmic surface of the plasma membrane. From here, they extend into the cytoplasm and interact with myosin filaments. The myosin filaments interact with a second set of actin filaments, which insert into intracytoplasmatic dense bodies. From these dense bodies further actin filaments extend to interact with yet another set of myosin filaments. This sequence is repeated until the last actin filaments of the bundle again insert into attachment plaques.

In principle, this organisation of bundles of myofilaments, or myofibrils, into repeating units corresponds to that in other muscle types. The repeating units of different myofibrils are however not aligned with each other, and myofibrils do not run exactly longitudinally or parallel to each other through the smooth muscle cells. Striations, which reflect the alignment of myofibrils in other muscle types, are therefore not visible in smooth muscle.

Smooth endoplasmatic reticulum is found close to the cytoplasmatic surface of the plasma membrane. Most of the other organelles tend to accumulate in the cytoplasmic regions around the poles of the nucleus. The plasma membrane, cytoplasm and endoplasmatic reticulum of muscle cells are often referred to as sarcolemma, sarcoplasm, and sarcoplasmatic reticulum.

During contraction, the tensile force generated by individual muscle cells is conveyed to the surrounding connective tissue by the sheath of reticular fibres. These fibres are part of a basal lamina, which surrounds muscle cells of all muscle types. Smooth muscle cells can remain in a state of contraction for long periods. Contraction is usually slow and may take minutes to develop.

Origin of smooth muscle

Smooth muscle cells arise from undifferentiated mesenchymal cells. These cells differentiate first into mitotically active cells, myoblasts, which contain a few myofilaments. Myoblasts give rise to the cells, which will differentiate into mature smooth muscle cells.

Structural differences between the organization of a smooth muscle (nonstriated) and the striated skeletal and cardiac muscles

Actin and myosin are present in all three muscle types. In skeletal and cardiac muscle cells, these proteins are organized in sarcomeres, with thin and thick filaments. The internal organization of a smooth muscle cell is very different:

• A smooth muscle fiber has no T tubules, and the sarcoplasmic reticulum forms a loose network throughout the sarcoplasm. Smooth muscle tissue has no myofibrils or sarcomeres. As a result, this tissue also has no striations and is called nonstriated muscle.

• Thick filaments are scattered throughout the sarcoplasm of a smooth muscle cell. The myosin proteins are organized differently than in skeletal or cardiac muscle cells, and smooth muscle cells have more cross-bridges per thick filament.

• The thin filaments in a smooth muscle cell are attached to dense bodies, structures distributed throughout the sarcoplasm in a network of intermediate filaments composed of the protein desmin. Some of the dense bodies are firmly attached to the sarcolemma. The dense bodies and intermediate filaments anchor the thin filaments such that, when sliding occurs between thin and thick filaments, the cell shortens.

Dense bodies are not arranged in straight lines, so when a contraction occurs, the muscle cell twists like a corkscrew.

• Adjacent smooth muscle cells are bound together at dense bodies, transmitting the contractile forces from cell to cell throughout the tissue.

• Although smooth muscle cells are surrounded by connective tissue, the collagen fibers never unite to form tendons or aponeuroses as they do in skeletal muscles.

Types of smooth muscle

Two broad types of smooth muscle can be distinguished on the basis of the type of stimulus, which results in contraction and the specificity with which individual smooth muscle cells react to the stimulus:

1. The multiunit type represents functionally independent smooth muscle cells which are often innervated by a single nerve terminal and which never contract spontaneously (e.g. smooth muscle in the walls of blood vessels).

2. The visceral type represents bundles of smooth muscle cells connected by GAP junctions, which contract spontaneously if stretched beyond a certain limit (e.g.

smooth muscle in the walls of the intestines, Fig. 4).

Fig. 4: Smooth muscle (Jejunum, human) H&E stain. The outer part of the tube forming the intestines consists of two layers of smooth muscle - one circular layer and

one longitudinal layer. Both longitudinally sectioned smooth muscle cells and transversely sectioned smooth muscle cells are seen. Occasionally small nerves between the two muscle layers are found which regulate the contraction of the muscle around the

gastrointestinal tract

Cardiac muscle

Cardiac muscles are involuntary muscles like the smooth muscle type but are striated muscles similar to skeletal muscles. These are highly specialized muscle cells and are only found in the heart. Cardiac muscles contract without direct stimulation by the nervous system. This is achieved with the help of A bundle of specialized muscle cells in the upper part of the heart which send electrical signals through cardiac muscle tissue, causing the heart to rhythmically contract and pump blood through the body. The basic cardiac Muscle Cell is about 10 - 15 µm wide and contains only ONE centrally placed Nucleus. Cardiac muscle is innervated by the autonomic nervous system and exhibits cross-striations between adjacent cells forming branching fibers that allow Nerve Impulses to pass from cell to cell. Cardiac muscle is for these reasons also called involuntary striated muscle.

Structure of cardiac muscle

The ultrastructure of the contractile apparatus and the mechanism of contraction largely correspond to that seen in skeletal muscle cells. Although equal in ultrastructure to skeletal muscle, the cross-striations in cardiac muscle are less distinct, in part because rows of mitochondria and many lipid and glycogen droplets are found between myofibrils.

In contrast to skeletal muscle cells, cardiac muscle cells often branch at acute angles and are connected to each other by extensions of the cell membrane called the intercalated discs.

Intercalated discs invariably occur at the ends of cardiac muscle cells in a region corresponding to the Z-line of the myofibrils (the last Z-line of the myofibril within the cell is

"replaced" by the intercalated disk of the cell membrane). In the longitudinal part of the cell membrane, between the "steps" typically formed by the intercalated disk, extensive GAP junctions are found. T-tubules are typically wider than in skeletal muscle, but there is only one T-tubule set for each sarcomere, which is located close to the Z-line. The associated sarcoplasmatic reticulum is organised somewhat simpler than in skeletal muscle. It does not form continuous cisternae but instead an irregular tubular network around the sarcomere with only small isolated dilations in association with the T-tubules. A brief Comparison of Skeletal, Cardiac and Smooth Muscle is shown in Table 1.

Proteins which make up a skeletal muscle fibre Myosin/Actin

As has been described before, the myofibril was a long tube of cytoskeleton. The myofibril contains the cytoskeletal elements that allow the muscle to contract. For that reason you will also see the cytoskeletal elements called the contractile apparatus. The sarcomere is the functional unit of muscle contractions [resent in the myofibril. These specific type of cytoskeletal elements involved in the contractile apparatus are microfilaments.

Microfilaments are composed entirely of proteins and are flexible. There are two main microfilaments: actin and myosin. Actin microfilaments are composed of the actin protein, while myosin microfilaments are composed of myosin proteins. The protein structure allows them to have a 3-dimensional shape, and they take on a certain appearance and appear as light and dark bands. When muscle cells contract, the light and dark bands contained in muscle cells get closer together. This happens because when a muscle contracts and the myosin filaments and actin filaments interact to shorten the length of a sarcomere. Apart from these abundant proteins, there are a number of other proteins, which interact with the actin

and myosin molecule leading to muscle contraction. To understand how these microfilaments function we need to understand the arrangement of these proteins independently.

Table 1: Comparison of skeletal, cardiac and smooth muscle

Property Skeletal Muscle

Cardiac Muscle

Smooth Muscle

Striations? Yes Yes

Relative Speed of Contraction

Fast Intermediate Slow

Voluntary Control? Yes No No

Membrane Refractory Period

Short Long

Nuclei per Cell Many Single Single Control of

Contraction

Nerves Beats

spontaneously but

modulated by nerves

Nerves Hormones Stretch

Cells Connected by Intercalated Discs or Gap Junctions?

No Yes Yes

Actin

The individual actin protein is called a "globular" protein ("g-actin") because of its globular appearance. The actin microfilament is the result of a number of these globular proteins coming together to form a long chain (Fig. 5). Two of these chains of g-actin twisted up together, and the filamentous form is then called "f-actin." The actin microfilament, although a doublet, is actually rather thin for its length and hence the actin microfilament is also known as the thin filament. This actin microfilament is also associated with other molecules, called troponin and tropomyosin for active muscle contraction.

Fig. 5: The actin chains: Two microfilaments of g-actin forming the filamentous ‘f- actin’

Myosin

Myosin microfilaments, like actin microfilaments, are made up of many individual myosin protein molecules (Fig. 6). However, the myosin protein is not globular; instead, it has a head and a tail region. And each complete myosin molecule in muscle is actually composed of two of these head-and-tail molecules twisted around each other.The myosin filament is hence composed of doublet myosin molecules arranged together into large bundles. On comparison to the actin filament the myosin proteins appear to be more bulky and hence the name, thick filament. A single thick filament typically has over 200 myosin molecules in it.

The thick filament runs along the long axis of the myofibril.

Fig. 6: Myosin molecule showing head and tail part and the myosin filament formed by doublet myosin molecules arranged together into large bundles

Tropomyosin and Troponin

Two other proteins associate with actin to form the thin filaments. Tropomyosin is composed of two polypeptides (a- and b-tropomyosin). Together they make up from 5 to 8% of the myofibrillar protein. These polypeptides aggregate to form long filaments that fit within the grove formed by the two chains of actin (Fig. 7). Each molecule spans seven actin molecules and controls the activity of these actin molecules. Troponin is made up of three subunits.

Troponin C contains calcium binding domain. Troponin T interacts with tropomyosin and Tropinin I can block the actin binding site for myosin. One set of three troponin subunits is associated with each molecule of tropomyosin and is involved with the activity of the actin molecules it interacts with.

Fig. 7: Arrangement of tropomyosin and troponin in relation to the actin filaments

Nebulin

This protein is a relatively new discovery and not well documented in course books (Fig. 8).

Its exact location as well extent of activity during muscular contraction is still being researched. It is the biggest actin binding protein not just in its size (600-900kDa) but also its potential binding capacity of 200 actin monomers. Each monomer is bound by a 35 amino acid residue that may also bind calmodulin, tropomyosin and troponin and the N-terminal region binds tropomodulin. The interaction of nebulin with actin is Ca²⁺-calmodulin sensitive. Nebulin is proposed to form a "molecular ruler" controlling the length of the thin filament, as a difference in the length of expressed nebulin corresponds to the length of the sarcomere.

N C

The 7x35 repeats are repeated 22 times 35 amino acids are repeated 7 times

N C

The 7x35 repeats are repeated 22 times 35 amino acids are repeated 7 times

Fig. 8: Structure of Nebulin. 7 x 35 amino acid repeats form a unit that is repeated about 22 times. The N-terminal associates with tropomodulin and so the pointed end of

the thin filament, the C-terminus binds components of the Z-disc

Titin

Titin is the largest polypeptide yet discovered (~3.5 MDa) and a major constituent of the sarcomere in vertebrate striated muscle. It is a multidomain protein, which forms filaments approximately 1 micrometre in length spanning half a sarcomere. Single molecules span from the Z- to M-line Titin has a two major functions: the control of assembly of muscle thick filaments and a role in muscle elasticity by forming a connection between the ends of the thick filament ans the Z-line as shown in the diagram. Without this there would be force imbalances in the opposite halves of thick filaments during active contraction).

Alpha- actinin

A family of actin filament crosslinking and bundling protein which are typically calcium sensitive in non-muscle cells and calcium insensitive in muscle cells. α-actinin is composed

of two identical anti-parallel peptides, with the actin binding domain close to the N terminus, followed by 4 spectrin-like repeats and terminating with two EF-hands (calcium binding motifs) (Fig. 9). Caicium binding inhibits the cross-linking function of α-actinin. In calcium insensitive isoforms these EF-hands are not active. α-actinin is a homodimer of two 100 kDa subunits. Under an electron microscope, α-actinins are rod like molecules, 40-5- nm long and 4-5 nm in width.

N terminal Actin binding domain

Central part Overlapping homodimer

C terminal

EF/Ca2+ binding domain

N terminal Actin binding domain

Central part Overlapping homodimer

C terminal

EF/Ca2+ binding domain

Fig. 9: α-actinin is a homodimer of two 100 kDa subunits, rod like molecules with the actin binding domain close to the N terminus, followed by 4 spectrin-like repeats and

terminating with two EF-hands (calcium binding motifs)

Myomesin

Proteins, myomesin and M-protein are the main constituents of the role of M-band bridges, which connect the neighboring thick filaments. Both proteins consist of the unique head domain followed by a conserved sequence of immunoglobulin (Ig) and fibronectin type III (Fn) domains. Myomesin seems to be the essential M-band component and might works as a bi-directional spring, providing the elasticity for the M-bridges.

Mechanism of muscle contractions

Organisation of cytoskeletal proteins on the contracting muscle

The spatial relation between the filaments that make up the myofibrils within skeletal muscle fibres is highly regular. This regular organisation of the myofibrils gives rise to the cross- striation, which characterises skeletal and cardiac muscle. Sets of individual "stria" within a myofibril correspond to the smallest contractile units of skeletal muscle, the sarcomeres (Fig.

3).

Physiology of the contracting muscle

The sarcomere is the basic unit of contraction . when the muscle receives a signal from the nerves, the muscles contract. The muscular contraction and relaxation is a result of changes in the chemicals released at the neuromuscular junction.

Sliding filament theory: This is the accepted theory for the basic mechanism of muscle contraction. The theory was given by two groups in England: A.F. Huxley and Niedergerke in 1954, and H.E. Huxley and Hanson also in 1954. They conducted experiments on the changes in sarcomere length and in I band length during contraction of an electrically stimulated frog fiber. The length of the sarcomeres, A and I-bands were measured on densitometer tracings. The fiber was stimulated electrically and then allowed to shorten.

During the experiment, it was discovered that during contraction the length of the actin containing thin filaments and the length of the myosin containing thick filaments remained constant. Thus, during contraction the length of the sarcomere and I-band decrease, the overlap between thick and thin filaments increases but the length of the thick and thin filaments remains unchanged (Fig. 10). Consequently, the filaments must slide past each other. The physiological interpretation of the sliding filament theory was tested by measuring the tension of a single muscle fiber at different sarcomere length. Maximum tension was obtained at rest length, between 2.0-2.25 micron, when all crossbridges were in the overlap region between thick and thin filaments. When the muscle fiber was stretched so that the sarcomere length increased from 2.25 to 3.675 micron and consequently the number of crossbridges in the overlap region decreased from maximum to zero; the tension fell from 100% to 0. The crossbridges are uniformly distributed along the thick filaments with the exception of a short bare zone in the middle. The crossbridges seem to be identical and are the site of the interaction between thick and thin filaments. The tension is the algebraic sum of the tension produced at each individual site. At or above rest length the tension is directly proportional to the number of crossbridges in the overlap region between thick and thin filaments.

Percent tension

100%

50%

70% 100% 130% 170%

Shortened muscle

Stretched muscle Resting

muscle length

A

B

C D

Percent tension

100%

50%

70% 100% 130% 170%

Shortened muscle

Stretched muscle Resting

muscle length

A

B

C D

Fig. 10: Sliding filament theory

The banding positions (A and I bands) of the thin (actin) and thick (myosin) filaments can be explained further with the following representations, which have originally been well documented by electron microscopy by many scientists:

• In the relaxed state (corresponding to Point C on the graph given in Fig. 10): The muscle is stretched to a point where there is very little overlap between actin and myosin. The isometric tension will be low (Fig. 11a)

• When muscle contracts the actin, filaments slide into the A band, overlapping with myosin. At point B on the graph of Fig. 10 there is considerable overlap between actin and myosin. There are many active crossbridges, so the isometric tension will be high (Fig. 11b). As a consequence of muscle contraction - the Z lines move closer together, the I band becomes shorter and the A band stays at the same length

• At point D (Fig. 10) there is a lot of overlap between actin and myosin, but the actin filaments are pushing on each other. This distorts the filaments, weakening the crossbridges (Fig. 11c).

Myosin

Z line

Sarcomere

Z line

relaxed

Actin Myosin

Z line

Sarcomere

Z line

relaxed

Actin

Fig. 11a: Muscle filaments in relaxed state

Myosin

Z line Z line

Sarcomere contracts

Actin Myosin

Z line Z line

Sarcomere contracts

Actin

Fig. 11b: Muscle filament during contraction

Myosin

Z line

Sarcomere

Z line

contracts to maximum

Actin Actin and myosin

overlap Myosin

Z line

Sarcomere

Z line

contracts to maximum

Actin Actin and myosin

overlap

Fig. 11c: Muscle filament during maximum contraction. The sarcomere is about 30%

Muscle contraction is a little like climbing a rope. The crossbridge cycle is: grab -> pull ->

release, repeated over and over. In the resting state, the actin and myosin (which have a

natural affinity for each other) are prevented from coming into contact. The presence of Ca⁺⁺

allows their interaction. So, the trigger for muscle contraction is a sudden inflow of Ca²⁺. In the resting state the protein tropomyosin winds around actin and covers the myosin binding sites. Troponin and tropomyosin, form a complex weave between the actin and myosin, and prevents their contaction the resting state. The Ca binds to troponin, and this action causes the tropomyosin to be pulled to the side, exposing the myosin binding sites and allows the interaction between actin and myosin. The presence of ATP instigates muscular contraction.

In muscle Ca²⁺ is stored in the sarcoplasmic reticulum (SR) (Fig. 12). The sarcolemma is the surface membrane of the entire fiber. It will have a single neuromuscular junction somewhere on its surface and it will not be electrically coupled to any of its neighbouring fibers. The T- tubular membranes are extensions of the sarcolemma. They contain extracellular fluid (high in Ca and Na ions). They are continuous tubes of sarcolemmal membrane that run through (transversely) the muscle fiber. In mammals the T-tubules lie at the boundary of the A and I bands (so there are 2 tubules per sarcomere). So, the t-tubule serves to propagate the sarcolemmal action potential deep into the fiber, bringing the excitation close to the SR membrane that surrounds each sarcomere. The sarcoplasmic reticlum (SR) is the Ca store. It is a diffuse membrane structure that surrounds the sarcomere and approaches closesly to the t-system where the SR structure chanes and is called terminal cisternae of the SR. Its membranes contain essentially 2 proteins: the Ca- ATPase (facing sarcomere) and the Ca- release channel (close to and facing the t-tubules). The calcium used to activate actin-myosin interaction is stored in and released from the SR.

Fig. 12: Above figure showing sarcolema with sarcoplasmic reticulum

Calcium release is stimulated by nerves, which contact muscle through a neuromuscular junction

The nerve releases acetylcholine and generates a muscle action potential. The action potential travels down the T-tubule and causes the sarcoplasmic reticulum (SR) to release Ca. After the contraction the Ca must be rapidly pumped back into the SR so the muscle can contract again.

The Neuromuscular Junction

Nerve impulses (action potentials) traveling down the motor neurons of the sensory-somatic branch of the nervous system cause the skeletal muscle fibers at which they terminate to contract. The junction between the terminal of a motor neuron and a muscle fiber is called the neuromuscular junction (Fig. 13a). The neuromuscular junction is also called the myoneural junction. The terminals of motor axons contain thousands of vesicles filled with acetylcholine (ACh). When an action potential reaches the axon terminal, hundreds of these vesicles discharge their ACh onto a specialized area of postsynaptic membrane on the fiber (Fig. 13b).

This area contains a cluster of transmembrane channels that are opened by ACh and let sodium ions (Na⁺) diffuse in.

(a)

Fused vesicles release Acetylcholine (Ach) Calcium channel

Ach

Ach breakdown

Choline recycled

Choline pump

A cholinesterase

Nerve impulse passes down the axon

Ach receptors

Muscle

Presynaptic membrane

Synaptic cleft

Postsynaptic membrane

Ca²⁺causes exocytosis of vesicles for Ach release

Fused vesicles release Acetylcholine (Ach) Calcium channel

Ach

Ach breakdown

Choline recycled

Choline pump

A cholinesterase

Nerve impulse passes down the axon

Ach receptors

Muscle

Presynaptic membrane

Synaptic cleft

Postsynaptic membrane

Ca²⁺causes exocytosis of vesicles for Ach release

(b)

Fig. 13: (a) Neuromuscular junction -The junction between the terminal of a motor neuron and a muscle fiber; (b) Release of acetylcholine when nerve impulse passes down

the axon and its consequences

When a single nerve enters a muscle it splits and makes neuromuscular junctions (NMJs) with several muscle cells. When the nerve fires the whole motor unit is stimulated and the

muscle cells contract together. Muscles with large motor units have coarse movements.

Muscles with small motor units give fine, graded movements.

Excitation and contraction of skeletal muscle

The area of contact between the end of a motor nerve and a skeletal muscle cell is called the motor end plate. Small branches of the motor nerve form contacts (boutons) with the muscle cell in a roughly eliptical area. The excitatory transmitter at the motor end plate is acetylcholine. The space between the boutons and the muscle fibre is called primary synaptic cleft. Numerous infoldings of the sarcolemma in the area of the motor end plate form secondary synaptic clefts. Motor end plates typically concentrate in a narrow zone close to the middle of the belly of a muscle. The excitable sarcolemma of skeletal muscle cells will allow the stimulus to spread, from this zone, over the entire muscle cell.

Cellular resting potential

If we remember that myofibers are basically water with some dissolved ions separated from the extracellular space, which is also mostly water with some dissolved ions, then the presence of a resting potential may make more sense. In much the same way as a battery creates an electrical potential difference by having different concentrations of ions at its two poles, so does a muscle cell generate a potential difference across its cell membrane. The ATP driven sodium-potassium pump maintains an artificially low concentration of sodium and high concentration of potassium in the intracellular space, which generates a resting potential difference on the order of -95 mV (Fig. 14a, b).

Depolarization

Depolarization is achieved by other transmembrane channel proteins. When the potential difference near these voltage sensitive proteins reaches a threshold level, the protein undergoes a magical conformational change that makes the membrane permeable to sodium.

Extracellular sodium immediately rushes in, drawn by both the charge difference and concentration gradient, and locally depolarizes the cell. Almost immediately, potassium also moves along in concentration gradient out of the cell and the membrane potential is restored.

As an interesting side note, this is the mechanism by which potassium chloride is used to induce cardiac arrest: by eliminating the potassium concentration gradient, the depolarized cardiac muscle cells are unable to repolarize for their next beat.

This depolarization is an extremely localized phenomenon, depending on diffusion over a few milliseconds. Some system is required to carry this signal to the myofibrils deep within the cell body. The sarcolemma, or cell membrane, invaginates to form a network of transverse (or T-) tubules that span the cross section of each fiber, transmitting the depolarization signal uniformly throughout the cell.

From depolarization to contraction

Proteins in the sarcolemma which forms the wall of the T-tubule change conformation, i.e.

they change their shape, in response to the excitation travelling over the sarcolemma. These proteins are in touch with calcium channels which are embedded in the membrane of the cisternae of the sarcoplasmatic reticulum. The change in the shape of the proteins belonging

to the T-tubule opens the calcium channels of the sarcoplasmatic reticulum. Calcium can now move from stores in the sarcoplasmatic reticulum into the cytoplasm surrounding the myofilaments.

(a)

-100 -50 0

Membrane potential (mV) End-plate

potential (EPP)

Action Potential

Time (msec)

Nerve impulse stimulation at axon terminal

A

B

C

-100

-50 0

Membrane potential (mV) End-plate

potential (EPP)

Action Potential

Time (msec)

Nerve impulse stimulation at axon terminal

A

B

C

Sarcoplasmic reticulum

- - - - + + + + + +

+ + + + + + +

- - - -

- -

+ + + + + + +

- - - -

- -

Sarcolemma T-tubules Sarcolemma T-tubules Sarcolemma

Sarcoplasmic

reticulum Ca²⁺

In the resting phase Ca²⁺is retained in the Sarcoplasmic

reticulum

(Point A in schematic graph of membrane potential)

+ + + ++ +

- -

- -

Nerve impulse leads to reversal of polarisation and causes release of the Ca ions

which bind to troponin and lead to muscle contraction

(Point B on graph)

Polarity is restored when the acetylcholine is broken down at the neuromuscular junction. This releases the calcium back to the

sarcoplasmic reticulum.

(Point C on graph)

Sarcoplasmic reticulum

- - - - + + + + + +

+ + + + + + +

- - - -

- -

+ + + + + + +

- - - -

- -

Sarcolemma T-tubules Sarcolemma T-tubules Sarcolemma

Sarcoplasmic

reticulum Ca²⁺

In the resting phase Ca²⁺is retained in the Sarcoplasmic

reticulum

(Point A in schematic graph of membrane potential)

+ + + ++ +

- -

- -

Nerve impulse leads to reversal of polarisation and causes release of the Ca ions

which bind to troponin and lead to muscle contraction

(Point B on graph)

Polarity is restored when the acetylcholine is broken down at the neuromuscular junction. This releases the calcium back to the

sarcoplasmic reticulum.

(Point C on graph)

(b)

Fig. 14a and b: Schematically showing the action potential at neuromuscular junction Sites of interaction between actin and myosin are in resting muscle cells "hidden" by

tropomyosin. Tropomyosin is kept in place by a complex of proteins collectively called troponin. The binding of calcium to troponin-C induces a conformational change in the troponin- tropomyosin complex, which permits the interaction between myosin and actin and, as a consequence of this interaction, contraction. Contraction is regulated by calcium ion concentration. In the resting state, a fiber keeps most of its intracellular calcium carefully sequestered in an extensive system of vessicles known as the sarcoplasmic reticulum. There are at least two receptors in the chain between depolarization and calcium release. Once released, calcium binds to troponin, opening the myosin binding sites on filamentous actin, and force is produced.

The interior of a resting muscle fiber has a resting potential of about −95 mV. The influx of sodium ions reduces the charge, creating an end plate potential. If the end plate potential reaches the threshold voltage (approximately −50 mV), sodium ions flow in with a rush and an action potential is created in the fiber. The action potential sweeps down the length of the

fiber just as it does in an axon. No visible change occurs in the muscle fiber during (and immediately following) the action potential. This period, called the latent period, lasts from 3–10 msec.

Before the latent period is over, the enzyme acetylcholinesterase breaks down the ACh in the neuromuscular junction (at a speed of 25,000 molecules per second) and the sodium channels close. And the junction is ready to receive another nerve impulse. The resting potential of the fiber is restored by an outflow of potassium ions. The brief (1–2 msec) period needed to restore the resting potential is called the refractory period. This entire sequence of events starting from excitation by nerve impulse at the neuromuscular junction, which results in physical contraction of the muscle is called as the excitation-contraction coupling

Excitation contraction coupling

Like most excitable cells, muscle fibers respond to the excitation signal with a rapid depolarization, which is coupled with its physiological response: contraction. The spread of excitation over the sarcolemma is mediated by voltage-gated ion channels. Invaginations of the sarcolemma form the T-tubule system, which "leads" the excitation into the muscle fibre, close to the border between the A- and I-bands of the myofibrils. Here, the T-tubules are in close apposition with cisternae formed by the sarcoplasmatic reticulum. This association is called a triad. The narrow gap between the T-tubule and the cisternae of the sarcoplasmatic reticulum is spanned by proteins, which mediate the excitation-contraction coupling. In summary, the generation of force is the result of stimulation of the motor nerve within a motor unit, and the signal arrives at the muscle membrane through the motor end plate in all the muscle fibers within the motor unit. The entire process is called Excitation-Contraction Coupling. The activation of the nerve is the result of the summation of a series of small electrical potentials. This summation can be temporal or spatial in nature. While two stimuli independently may not have enough strength to elicit an impulse in a nerve or a muscle, if they occur rapidly in time they may have an additive effect. Temporal summation involves repetitive firing over a single nerve, whereas spatial summation involves timed firing over multiple nerves. Finally, refractory period is the time when a nerve or muscle cell is unresponsive to external stimuli. It has two separate phases: the absolute refractory period where a cell cannot fire regardless of the stimulus strength, and the relative refractory period when the excitable cell can respond with an impulse but only to a stiumulus larger than normal. The concept of the refractory period only applies to the depolarization of the sarcolemma, and not to the events that follow (calcium release channel activation, calcium release, calcium-trponin interaction, cross bridge formation, power stroke).

Two basic types of contraction are isotonic and isometric

In an isotonic contraction the muscle shortens, keeping a constant tension. In an isometric contraction the muscle does not shorten and tension builds up. Most real contractions are mixtures of the two types.

A Single nerve impulse produces a muscle twitch

Single stimuli usually release enough acetylcholine in the neuromuscular junctions of the motor unit to produce action potentials in the muscle membranes and the muscles then contract after a short delay.

Order of events: ACh release -> muscle action potential -> Ca release -> contraction

A simple twitch gives only 20-30% of the maximum tension possible- the muscle starts to relax before the maximum is reached (Fig. 15a). If a second stimulus is given before a muscle relaxes the muscle will shorten further, building up more tension than a simple twitch- this is called summation (Fig. 15b). At 5 stimulations per second, the individual twitches begin to fuse together, a phenomenon called clonus. If many stimuli are given very close together (50 stimuli per second) the muscle will go into a smooth continuous contraction called tetanus (Fig. 15c). Tetanus gives the maximum tension, about 4X higher than a simple twitch (isometric contraction). Clonus and tetanus are possible because the refractory period is much briefer than the time needed to complete a cycle of contraction and relaxation. The amount of contraction is greater in clonus and tetanus than in a single twitch. Another way to increase the force of contraction is to recruit more motor units. Each muscle is made up of tens of thousands of motor units. Force generated by a muscle can be increased by firing more and more motor units.

Fig. 15a: A muscle is stimulated at 0.5 seconds and again at 2.5 seconds; there is complete relaxation between the stimuli and the tension reaches only 25% of maximum

(Madonna computer simulations of muscle contraction). It is assumed that tension is proportional to the amount of Ca bound to troponin

Fig. 15b: The muscle is stimulated at 0.5 seconds and again at 0.7 seconds. The muscle does not completely relax between stimuli and the tension summates to 35% of

maximum

Fig. 15c: The muscle was given 20 stimuli 0.1 seconds apart (lower trace). The contractions fuse to produce a tetanus that rises to over 90% of maximum

Different types of skeletal muscle fibers specialize for endurance or speed

Skeletal muscles contain two types of fibers, which differ in the mechanism they use to produce ATP; the amount of each type of fibre varies from muscle to muscle and from person to person.

Endurance fibers (type I) or the Red muscle fibres: Red ("slow-twitch") fibers have more mitochondria, store oxygen in myoglobin, rely on aerobic metabolism, and are associated with endurance; these produce ATP more slowly. Marathoners tend to have more red fibers.

Have many mitochondria- the mitochondria give these fibers a red appearance because one of the mitochondrial enzymes contains Fe. Also contain a red pigment called myoglobin, which stores O2. Contract slowly but resist fatigue.

Fast twitch fibers (type II) or white muscle fibre: White ("fast-twitch") fibers have fewer mitochondria, are capable of more powerful (but shorter) contractions, metabolize ATP more quickly, and are more likely to accumulate lactic acid. Weightlifters and Sprinters tend to have more white fibers. They contain few mitochondria. Relying on glycolysis to supply energy (glycolysis is faster than respiration). Contract rapidly but fatigue quickly.

Comparison of different types of fibres is given in Table 2.

Table 2: Comparison of different types of skeletal muscle fibers

Fibre type Type I fibres Type IIa fibres Type IIb fibres

Contraction time Slow Fast Very fast

Size of motor neuron Small Large Very large Resistance to fatigue High Intermediate Low

Activity Used for Aerobic Long-term anaerobic Short-term anaerobic

Force production Low High Very high

Mitochondrial density

High High Low

Capillary density High Intermediate Low

Oxidative capacity High High Low

Glycolytic capacity Low High High

Major storage fuel Triglycerides Creatine phosphate, glycogen

Creatine phosphate, glycogen

Intermediate lengths of filaments produce the most isometric strength

If you measure the isometric tension of a muscle when it is fixed at different lengths you will find that there is an optimum length for producing tension. At rest many of the body's muscles are close to their optimum lengths.There is a connection between the chemical anatomy of actin and myosin and the amount of tension produced when they interact

The chemical connection is based upon two principles:

1) actin and myosin connect through crossbridges- the more crossbridges the more tension. Suppose the muscle is stretched so far that actin and myosin hardly overlap- then there will be few crossbridges and little tension. As the muscle is shortened from this extreme length more and more overlap will occur and the tension will rise.

2) when the muscle proteins interfere with crossbridges it will weaken the tension. If the muscle is shortened too much the actin filaments will bump into each other and bend- this distorts the sarcomere and weaken the contraction

Metabolism of the muscle contraction

Energy for the reorientation and movement of the myosin head comes from the molecule ATP. Oddly enough, stopping the process of muscle contraction also requires energy. The saying 'it takes energy to relax', is certainly true for skeletal muscle. Muscle contraction stops when Ca⁺⁺ is removed from the immediate environment of the myofilaments. The sarcoplasmic reticulum actively pumps Ca⁺⁺ back into itself and this requires utilization of ATP. Troponin-tropomyosin re-assume their inhibitory position between the actin and myosin molecules once Ca⁺⁺ is removed.

It is important to remember that the above scenario applies for groups of individual muscle fibers, which with their motor neuron are called motor units. When a muscle is required to contract during exercise not all motor units are used (or recruited). Most movements require only a fraction of the total power available from an entire muscle. Consequently, our motor system grades the intensity of muscle contraction by recruiting various numbers of motor units. Even during maximal shortening contractions (so called concentric contractions) it is doubtful that all motor units are recruited.

Energy supply for muscle contraction

ATP adenosine triphosphate (there are three phosphates in ATP) is the immediate source of energy for muscle contraction. ATP is not stored to a great degree in cells. Once muscle contraction starts the regeneration of ATP must occur rapidly. There are three primary sources of high-energy phosphate for ATP replenishment, which in order of their utilization, are creatine phosphate (CP), anaerobic glycolysis, and oxidative phosphorylation or cellular respiration in the mitochondria of the muscle fibres.

Creatine phosphate

The phosphate group in creatine phosphate is attached by a "high-energy" bond like that in ATP. Creatine phosphate derives its high-energy phosphate from ATP and can donate it back to ADP to form ATP.

Creatine phosphate + ADP ↔ creatine + ATP

The pool of creatine phosphate in the fiber is about 10 times larger than that of ATP and thus serves as a modest reservoir of ATP.

Glycogen

Skeletal muscle fibers contain about 1% glycogen. The muscle fiber can degrade this glycogen by glycogenolysis producing glucose-1-phosphate. This enters the glycolytic pathway to yield two molecules of ATP for each pair of lactic acid molecules produced. Not much, but enough to keep the muscle functioning if it fails to receive sufficient oxygen to meet its ATP needs by respiration. However, this source is limited and eventually the muscle must depend on cellular respiration.

Cellular respiration

Cellular respiration not only is required to meet the ATP needs of a muscle engaged in prolonged activity (thus causing more rapid and deeper breathing), but is also required afterwards to enable the body to resynthesize glycogen from the lactic acid produced earlier (deep breathing continues for a time after exercise is stopped). The body must repay its oxygen debt.

ATP utilization in the muscle contraction

ATP is hence required for both contraction and relaxation of muscle. ATP is the energy supply for contraction. It is required for the sliding of the filaments, which is accomplished by a bending movement of the myosin heads. It is also required for the separation of actin and myosin, which relaxes the muscle. When ATP runs down after death muscle goes into a state of rigor mortis. In cardiac (heart) and smooth muscle special junctions help spread the excitation from one cell to another muscle contractions require energy, which is supplied by ATP. This energy is used to detach the myosin heads from the actin filaments. Because myosin heads must attach and detach a number of times during a single muscle contraction, muscle cells must have a continuous supply of ATP. Without ATP the myosin heads would stay attached to the actin filaments, keeping muscles permanently contracted. A muscle contraction, like a nerve impulse, is an all-or-none response- either fibers contract or they remain relaxed. The force of a muscle contraction is determined by the number of muscle fibers, that are stimulated. As more fibers are activated, the force of the contraction increases. Some muscles, such as the muscles that hold the body in an upright position and maintain posture, are nearly always at least partially contracted.

ATP hydrolysis for muscle contraction

The energy for muscle contraction comes from ATP hydrolysis (Fig. 16). ATP binds and the head group detaches ATP. The latter is a direct consequence of the interaction between myosin and actin. Actin catalyzes the ATPase activity of Myosin. The rate-limiting step is the release of products of ATP hydrolysis (ADP and Pi). The Release of Pi results in tighter binding and power stroke. These remain noncovalently bound to the myosin molecule and prevent further ATP binding and hydrolysis. Release of ADP begins another cycle. The binding of myosin to actin causes a rapid release of ADP and P from the myosin molecule.

Each cycle takes about 50 msec. Inability of myosin cross-bridges to detach in the absence of ATP is basis for rigor mortis.

Fig. 16: ATP utilization during muscle contraction

ATP is synthesized via glycolysis in the sarcoplasm and/or via oxidative phosphorylation in the mitochondria. Glycolysis may occur under anaerobic condition, the yield is 2 or 3 ATP/glucose. Oxidative phosphorylation provides 36 ATP/glucose. Also, dismutation of 2 ADP catalyzed by adenylate kinase yields 1 ATP + 1 AMP.

It is the globular head of the myosin molecule that binds to actin and hydrolyses ATP. Each actin molecule in the thin filaments can bind one myosin head. The heads bind with the same orientation to each actin subunit and thus point all in the same direction. The actin filament has a plus- and a minus-end (compare this to microtubules). The latter points towards the center of the sarcomere. The thin filaments on either side of the sarcomere are of opposite polarity to accommodate the oriented myosin heads appropriately. The myosin heads point in opposite directions away from the sarcomere center. The myosin heads walk from the minus ends of the thin filaments in center of the sarcomere to the plus-ends on the Z-discs. During this movement, ATP is hydrolysed and subsequent dissociation of the tightly bound products (ADP and P) produce an ordered series of changes in the conformation of myosin, moving the actin filaments along the thick filaments. The ATP concentration in muscle is quite low (5-8 mmoles/g muscle), enough only for a few contractions. The used ATP is immediately resynthesized from PCr. However, the PCr concentration is also low (20-25 mmoles/g),

enough for some additional contractions. Glycogen offers a rapid but still limited energy store (endogenous glycogen concentration about 75 mmoles glucose units in glycogen/g muscle), whereas oxidative phosphorylation is the slowest and most efficient process for ATP production. For example, the glycogen store offers energy for a runner for about 1/2 hr and oxidative phosphorylation for an additional 2 hrs.

Heat production during muscle contraction

The muscle converts the free energy of ATP into work and heat. According to the second law of thermodynamics, in a system like muscle, which is at uniform temperature, it is impossible to convert heat into work. (This is possible in steam engine, which is not at uniform temperature, but there is a rather large temperature gradient within the engine). It follows that in muscle the heat produced is a lost free energy and the efficiency of the muscle is the ratio of the work produced to the free energy of ATP:

Efficiency = Work produced / Free energy of ATP

The chemical reactions occurring in muscle generate heat that is vital for maintaining body temperature. Inversely, measuring heat in various phases of muscle contraction indicate the existence of exothermic chemical reactions.

DC BA

Time marks: 0.2 sec

Heat production

Representation of the Fenn effect

DC BA

Time marks: 0.2 sec

Heat production

Representation of the Fenn effect

During isotonic contraction more heat is liberated than during isometric contraction. Fenn called this extra heat the shortening heat. The shortening heat is proportional to the shortening of the muscle; the larger the shortened distance, the more extra heat is produced (this is called the Fenn effect). In this simplified representation of the Fenn effect, Line A represents only isometric contraction. Lines B-D represent the time when the muscle was contracting isometrically until it was released and allowed to shorten various distances. Fenn gave his theory in 1923 and 1924 and this was further worked at by A.V Hill in 1938.

Relationship between work-output and O2 consumption: If work-output can be measured, it can be converted into kcal equivalents. For example, on the bicycle ergometer with a flywheel of 6 m and a pedaling rate of 50 RPM (300 m total distance per min) with 1 kg resistance, 300kg.meter work is performed per min. Since 1 kg.meter corresponds to 0.00234 kcal, 300 kg.meter can be converted into 0.7 kcal of work-output. Assuming 25% efficiency, the total energy expenditure per minute is 4 x 0.7 = 2.8 kcal. Since 4.8 kcal corresponds to 1- liter O2 consumption, the 2.8 kcal is equivalent to 0.58-liter O2 consumption. (Note the following terms: work = force x distance; force = mass x acceleration; power = work per unit of time; energy = the capacity of performing work).

Many studies were carried out to relate different work-outputs under various conditions with oxygen consumption, in healthy individuals and in patients. Such studies are helping

physicians to design programs for individuals to lose weight, improve athletic performance, or to rehabilitate following muscle injury or heart disease.

With an increase in competitive sports, the study of sports medicine has become important.

The analysis of an individual performance has become increasingly complex and athletes are put under scrutiny for their muscle performance, endurance as well as the physiological relation to their genetic constitution. Even under conditions of microgravity, the effect of muscle atrophy and fatigue have become important to determine the long term effect of space travel on astronomers.

During an intense period of exercise, phosphocreatinine level has decreased and much of the glycogen may have been converted to lactic acid. Oxygen debt is likely to be created. To restore the normal cellular metabolite levels, energy is needed and the muscle utilizes oxygen to provide energy for the cellular processes. The muscle continues to consume oxygen at a high rate after it has ceased to contract. Therefore, we breathe deeply and rapidly for a period of time, immediately following an intense period of exercise, repaying the oxygen debt.

Example for calculation of oxygen debt: After exercise, a total of 5.5 liters of O2 were consumed in recovery until the resting value of 0.31 liter/min was reached. The recovery time was 10 min.

Oxygen debt = 5.5 - (0.31 x 10) = 2.4 liters

It is customary to differentiate between high-intensity strength activities and low-intensity endurance exercises. The different types of exercises elicit different patterns of neural activity to muscle resulting in specific adaptation. High intensity strength activities, such as weight lifting and bodybuilding, induce hypertrophy of the muscle with an increase in strength. Endurance exercises, such as swimming and running, increase the capacity of muscle for aerobic metabolism with an increase in endurance.

Muscle fatigue is defined as a loss of work-output leading to a reduced performance of a given task. Fatigue may result from deleterious alterations in the muscle itself and/or from changes in the neural input to the muscle. During prolonged endurance exercise, e.g.

marathon-running, depletion of muscle glycogen, decrease in blood glucose, dehydration, or increase in body temperature contribute to fatigue. During intense muscular activity, e.g.

short-distance running, lactic acid is formed via anaerobic glycolysis. The H⁺ ions dissociated from lactic acid decrease the pH of the muscle; this may inhibit metabolic processes, disturb excitation-contraction coupling, Ca²⁺ fluxes, actomyosin ATPase activity, and thereby decrease work output.

Disorders of skeletal muscle and smooth muscle

Disorders of the muscles could be acquired, familial, and congenital types. Some of the common types of disorders are:

Compartment syndromes – It’s a condition where increased pressure within a limited space compromises the circulation and function of tissue within that space. Compartmentation involves mainly the leg but forearm, arm, thigh, shoulder, and buttock are also involved.

These lead to nerve compression, paralysis, and contracture. Some of the causes of increased pressure are trauma, tight dressings, hemorrhage, and exercise.