Muscle Physiology Midterm 1 Flashcards
What are the 4 functions of muscles?
Generate force, fuel storage, temperature regulation, and force absorption.
2 examples of isotonic contractions
concentric and eccentric
Shortening contraction?
Concentric (fibres move closer to each other; up phase in a bicep curl)
Lengthening contraction?
Eccentric (fibres move away from each other; lowering phase in bicep curl)
Isometric contraction?
Muscle contracts, but muscle fibres are static/don’t move
What type of isotonic contraction generates more force?
Eccentric contraction generate more force…can lower much more weight than we can curl or squat
What type of muscle contraction causes the most damage?
Eccentric/lengthening…downhill running = muscles always shortening = painful
Percentage muscle makes up of total body mass?
30-40%…sometimes closer to 50
In order to maintain muscle mass, what must be equal?
The rate of protein synthesis and the rate of protein degradation
During muscular hypertrophy what is occurring?
Less protein breakdown and more protein synthesis (extracting more AA from diet to build more muscle/protein) results in NET muscle growth
What happens during muscular atrophy?
Protein degradation exceeds protein synthesis…AA used as a fuel source for other metabolic processes and to support other tissues
3 fuels in muscle
proteins, glycogen, lipid droplets
Why is it a good thing muscle protein is broken down for energy in times of need?
Muscles can still contract (just not with as much force) even at reduced protein levels, but my sacrificing itself, the muscle allows other systems/organs, like the kidney to continue working
Shivering thermogenesis?
Get cold, muscles contract. Overal mechanical efficiency is on about 20% with the balance of energy given off as heat.
Nonshivering thermogenesis?
UCP and SR Ca-ATPase
How does uncoupling proteins generate heat?
Dissipate the protein gradient in the inner mitchondrial membrane created by food stuffs, by allowing the H ions to flow back into the matrix without going through the ATP-synthase molecules, releasing the energy as heat instead
How do UCP increase BMR?
Food is being used to create gradient, but if no ATP is made from this gradient, more energy (food) must be used to create enough of a gradient to make ATP
How do muscles work as force absorbers?
Protect the skeleton and internal organs
What is muscle made of?
Approximately 20-30 thousand proteins
Is muscle homogeneous?
NO…heterogeneous
What makes a muscle heterogeneous?
Different proteins (pumps, channels, enzymes, etc), in different concentrations (more myosin than UCPs) and forms (different myosin isoforms,etc)
What determiens the specialized function and characteristics of a muscle cell?
Amount and patterns of expressions of various Protein isoforms
Are muscles homogeneous in structure/function?
YES! All have myosin, actin, Ca pumps, etc. Just in different amounts
Is muscle adaptable?
YES. Depends on stress placed on muscle. Example, 12-18 hours after a limb is casted, already there is an increase in protein breakdown and wasting and concentrations of proteins are already changing, like mitochondrial proteins
Contractile proteins?
Actin and myosin
Bulk of sacroplasm in muscle is made up of ?
Actin and myosin (2/3 dry mass)
Actomyosin ATPase does what?
Allws for interaction between actin and myosin. Myosin is an ATPase that uses ATP to chanfe shape of myosin molecule and allot connection with actin
Regulatory proteins?
Troponin and tropopmyosin
Role of regulatory proteins?
Regulate actin/myosin interactions (blocking function), so control contraction/relaxation cyle
Why is Ca2+ regulated?
If it wasn’t, contraction would be happening all the time.
Purpose of SR?
ER in other cells; storage, release and uptake of Ca2+; uses CA2+ ATPase to uptake CA into SR…used ATP because pumping Ca2+ against concentration gradient
What happens when calcium concentrations increase in the muscle fibre?
Ca binds to troponin, causing it to change shape and remove tropomyosin’s blocking action, allowing for strong actin-myosin interaction (increase in force)
How is muscle an excitable tissue?
Innervated by a motoneuron, which releases Ach onto motor endplate, causing a depolarization.
Purpose of t-tubules?
Propagation of APs into muscle cell
5 cellular systems of muscle
- Contractile system (myofibrils) 2. Ca2+ Regulation System 3. Excitation System–Electrical Potential 4. Metabolic/Energy System 5. Nucleus/multi-nucleation
The specific term used to refer to the ability of skeltal muscle to adapt to stress?
Plasticity
What is the function of SERCA?
UPTAKE of Ca2+
3 energy systems in muscle
PCr/High Energy Phosphate transfer system, Glycolytic system in cytosol of 11 reactions to form ATP from carbs, Oxidative Phosphorylation in mitochondria to make ATP from carbs, fats, AA
Broad term for enzymes that split ATP into ADP and Pi?
ATPase
Why are muscles multi-nucleated?
Need LOTS of proteins and also helps allow the cells to be elongated, which is better than many single nucleated cells working independently
Can muscle fibres regenerate?
NO, but can gain more nuclei, which allows for more proteins to be synthesized
% of ATP Actomyosin ATPase uses for crossbridge cycling?
70-80%
% ATP Ca2+ ATPase uses to pump calcium unto the SR?
20-30%
% ATP sarcolemma ATPase uses to maintain Na+/K+ gradient?
less then 10%
Purpose of t-tubules?
Allow AP to go into the muscle fibre, not just along the sarcolemma
Triad of the reticulum consists of?
2 terminal cisternae and tranverse tubule
2 types of mitchondria in muscle
SS mitochondria near the sarcolemma and IMF mitochondria between fibres
Purpose of triad of the reticulum?
Where AP is linked to calcium release…where electrical event is turned into chemical event
Does the sarcolemma cover the nuclei?
YES…want genetic information inside the cell
Skeletal muscle is composed of?
Connective tissues, muscle fasicles, blood vessels, nerves
Muscle fasicles are composed of?
individual muscle fibres/cells
Muscle fibres are composed of?
Sarcolemms, t-tubules, sarcoplasm, and multiple nuclei
Sarcoplasm consists of?
SR, myofibrils, mitochondria, gylcogen granules
Myofibrils are composed of?
Troponin, actin, tropomyosin, myosin, titin, nebulin
Thin filaments are composed of?
Actin, tropomyosin, troponin
Thick filaments are made of?
Myosin
Thin and thick filaments are organized into?
Sarcomeres
Cytoskeleton proteins?
Titin and nebulin
Purpose of cytoskeleton proteins?
Provide structure
What is the smallest function unit (can see length change) unit of a muscle?
Sarcomere…about 2.5 micrometres, but can change by stretching/shortening of sarcomeres
What is the most abundant molecule in skeletal muscle?
Myosin
Why is myosin considered a motor protein?
Converts chemical energy in ARP into the mechanical energy of movement
What does a certain myosin isoform determine?
Contractile speed (Vmax)
How many heavy chains does a myosin molecule have?
2 HC that intertwine to form a long coiled tail and a pair of heads that bind actin, forming cross bridges
How many reactive sites does myosin have and for what?
1 for actin and 1 for nucleotide (ATP) binding site
How many light chains are associated with the heavy change of each myosin head?
2…phoshphorylatable light chain and alkali light chain
Isoforms of the alkali light chain?
2 isoforms (LC1 and LC3)
Purpose of the alkali light chain?
Provides structural stability to cross bridge and regulates myosin ATPase activity (dependent on if it is LC1 or LC3)
Alkali light train is also known as?
The ESSENTIAL light chain
Phosphorylatable light chain is also known as?
The REGULATORY light chain (LC2)
Purpose of phosphorylatable light chain?
As Ca2+ is released during muscle activation, some of the Ca2+ can activate myosin light chain kinase, resulting in the phosphorylation of the P light chain, which can increase force and rate of force development
How many myosin molecule makes up a thick filament?
250 molecules, each thick filament arranged so bipolar myosin heads clustered at the ends and contral region is a bundle of myosin tails (H zone)
2nd most abundant protein in muscle
actin
Actin is composed of?
Small globular units (G action) that form long strands of fibrous actin (F actin)
Actin filament is formed by?
2 strands of F actin in coiled coil
How many active sites and for what does a G actin molecule have?
2 active site to which myosin heads will bind during contraction
Shape of tropomyosin?
long, rod-shaped, double-stranded, helical protein that is wrapped about the long axis of the actin backbone
Purpsoe of tropomyosin?
Serves to block the active site on actin, thereby inhibiting action and myosin from binding under resting conditions (Steric Blocking Model)…muscle contraction cannot occur
Troponin is a complex of how many polypeptides/subunits?
3
3 types of troponin?
Tropomyosin binding (T), inhibitory binding (I), and calcium-binding (C)
Job of T troponin?
Positions the 3 subunit complex of troponin on thin filament
Job of troponin I>
Binds to actin and inhibits interaction of actin and myosin
Job of troponin C?
Binds up to 4 Ca2+ and with Ca2+ bound, relieves inhibition of myosin binding to action by sliding troponin I out of the way, what moves tropomyosin and frees up the active site to allow strong cross bridges between actin and myosin
How many troponin complexes for every actin monomer?
7 troponin complexes for every 7 actin monomers
How many thin filaments surround each thick filament?
6
How many thick filaments surround each thin filament?
3
I-band consists of?
Thin filaments only
A band consists of?
Thin and thick filaments
H-zone consists of?
Tails of myosin/thick filaments only
Purpose of M line?
Keeps thick filaments in position and proper spacing. Also holds them in a regular hexagonal lattice
Purpose of A disk?
Keeps thin filaments in position
Purpose of alpha actinin?
Actin cross-linking protein in Z-disk region that anchors thin (actin) filaments, 2 isoforms
Purpose of desmin?
Conect 2 sarcomeres from adjacent myofibrils
Purpose of nebulin?
An ineleastic (rigid) giant protein that lies alongside think filaments and attaches to Z-dosk…helps align the actin filaments of the sarcomere, which stops them from being “floppy”
Purpose of titin?
Huge elastic molecule that stretched from 1 Z-disk to next M-line (1/2 a sarcomere), stabilizes position of contractile filaments (keeps thick filaments in middle between 2 z-lines for optimal length to generate force), and its elasticity returns stretched muscles to resting length
3rd most abundant protein in muscle?
TITIN
Major protein damaged during eccentric loading?
TITIN…actually breaks, which causes some sarcomeres not to return to optimal resting spot, so not optimum amount of myosin.actin interaction, so not enough force
Proteins at the M-line?
M protein and myomesin
Purpose of dystrophin?
Flexible, elongated actin-binding protein that anchors superficial myofibrils to sarcolemms, which allows for even distribution of force across the sarcolemms to avoid tearing of the membrane
Largest protein in body?
TITIN
Largest gene in the body codes for?
Dystrophin
Scientist that discovered sliding filament theory?
Huxley inn 1954
Basis of sliding filament theory?
Overlapping muscle filaments of fized lengths (thick and thin filaments slide past each other in an energy-requiring process, resulting in muscle contraction
During muscle contraction what shortens in the sarcomere?
H-zone nad I-band shorten, as z disks come closer together
What remains constant during muscle contraction?
A band
A band represents the length of?
Thick filaments (250 myosin molecules put together)
Myosin molecule consists of?
2 heavy chains intertwined to form a long coiled tail and a pair of heads that bind actin, forming cross bridges. Each head has 2 binding sites and 2 light chains associated with it.
2 thin filaments consist of?
2 strands of F-actin molecules in a coil with troponin subunits every 7 actin and tropomyosin wrapped about the long axis of the actin backbone
Excitation-Contraction coupling?
The sequence of events by which an action potential at the sarcolemms (an electrical event) initiates the sliding of the myofilaments, resulting in contraction (a mechanical event)
Steps on excitation-contraction coupling?
AP generated in MN, which releases ACh at NMJ, starting depolrization of sarcolemms. AP conducted along sarcolemma and into t-tubules. AP triggers Ca2+ release from the SR. Ca2+ binds to Troponin C, relieving troponin C, allowing tropomyosin to move from the actin active site. Strong cross bridges between actin and myosin. The power stroke of myosin moves actin filaments past it and the muscle contraction
Relaxation in muscle?
Excitation (neural input) stops and Ca2+ is pumped back into SR by SERCA. Decrease in cystolic Ca2+ causes Troponin ! to go back to original spot, placing tropomyosin back to covering actin binding site. Binding site is blcoked so the actin and myosin dissociate and the muscle relaxes
Can a muscle contract without an AP?
Yes, just needs calcium
The Steric Blocking Model?
States that the regulatory protein, tropomyosin, exerts a blocking function between actin and myosin effectively preventing their interaction. Essentially, there’s NO actin-myosin interaction possible at low Ca2+ levels and role of calcium is simply to control the movement of TM in and out of blocking position
Kinetic studies show what contradictory evidence against the Steric Blocking Model>
Myosin can bind actin in 2 steps…an initial weak bound state (even at low Ca2+) and a strongly bond or rigor-like state in the presence of high Ca2+
TM movement into grovve of teh F-actin helix results in?
An increase in the number of myosin heads attached to actin
Calcium regulates both what and what?
Both the attachment of myosin ot actin and the transition from weak to strong binding states
The Kinetic Model?
Is based on the observation that actin-myosin can combine in weak binding at low Ca2+, and therefore the steric blocking mod is not entirely valid, although, there can still be some steric blocking. Rather, a KINETIC STEP in actin-myosin is involved, working through ATPase activity but results in transition from weak to strong binding
In An intact muscle, the initial event that is needed to begin contraction (not force generation) is?
Generation of an AP
What is responsible for the transition from weak to strong binding?
Increase in cystolic Ca2+ results In Myosin releasing Pi, allowing for strong attachment betwee actin and myosin because tropomyosin is out of blocking position
Steps on the Kinetic Model?
Myosin can bind to TN-TM-Actin both in the presence and absence of activating calcium levels, but activating calcium levels enhance interaction. Binding of Ca2+ to TN-C overcomes the inhibition of TN-I. TM filament moves. Activation of TN-TM-Actin (open binding site on actin). M-ADP-Pi binding to TN-TM-Actin* overcomes the rate limiting step of myosin ATP hydrolysis with release of Pi molecule. M-ADP binds the thin filament with a higher affinity and muscle contraction proceeds
What is the cross-bridging cycle?
The cyclic events that are necessary for the generation of force within the myosin heads during muscle contraction
Event responsible for the power stroke?
Release of ADP
Cross bridge cycling biochemical events?
Ca2+ activates Thin Filament, which alters ATPase to release Pi. Release of Pi is responsible for transition from weak to strong binding. Release of ADP responsible for power stroke,. ATP binding results in detachment from actin and/or weak binding
Sarcolemma?
Outer surface of plasma membrane that surrounds the entire cell
T-tubules?
Invaginations of the sarcolemma into the fibers interior along a line vertical to the fibre axis. Lumen of the t-tubule system is continuous with the extracellular space
Where are t-tubules located in sarcomere?
Near border of A-I junction in sarcomere and connects with Z-line of the myofibrils via intermediate filaments called desmin
Composition of sarcolemma and t-tubules?
Phospholipid bilayer with a variety of specialized proteins (channels, pumps, transporters, receptors, etc)
How is Ca2+ released from SR?
AP travels down t-tubules trips off DHPR, which is physically connected to RyR on the SR, causing them to open ad release Ca2+ into cytosol
What is resting membrane potential difference?
An electrical gradient between the extracellular fluid and the intracellular fluid
For sarcolemms and the T-tubules’ membrane potentials are determined essentially by what 3 ions?
Na+, K+, and Cl-
What 2 factors contribute to the net membrane potential?
Concentration gradient across the membrane (how many ions are where) and membrane permeability (more permeable to some ions than others, can change permeability by opening/closing ion channels)
Extracellular, intracellular concentrations of Na+?
150 Extracellular mM and 15 Intracellular mM
What is the extracellular and intracellular concentrations of K+?
5 mM Extracellular and 150 mM intracellular
What is the extracellular and intracellular concentrations of Cl-?
123 mM Extracellularly and 4.2 mM Intracellularly
What is equilibrium potential?
The embrane potential difference that exactly opposes the concentration gradient of the ion
What is the equilibrium of K+?
-90 mV
Equilibrium potential of Na+?
+60 mV
What is the RESTING membrane potential of muscle?
-70 mV
Why is the resting MP of muscle -70 mV?
Muscle cells are about 40x more permeable to K+ that to Na+, and as a result, a cells resting MP is closer to the Ek of -90 mV than to the ENa of +60 mV
What determines membrane permeability to a particular ion?
Opening and closing of ion channels
What causes changes in MP (i.e. the AP)?
Changes in membrane permeability to Na+ and K+ (i.e. opening of Na+ or K+ channels)
Steps in an AP
- Resting MP -70 mV 2. Depolarizing stimulus (ACh onto motor end plate) 3. Membrane depolarizes to threshold. Voltage-gated Na+ channels open and Na+ enters cell. Voltage-gated K+ channels begin to open slowly 4. Rapid Na+ entry depolarizes cell 5. Na+ channels close and sower K+ channels open 6. K+ moves from cell to ECF 7. K+ channels remain open and additional K+ leaves cell, hyperpolarizing it 8. Voltage-gated K+ channels close, some K+ enters cell through leaky channels 9. Cell returns to resting ion permeability and resting MP
What does the Na+ - K+ - ATPase do?
Carries 3 Na+ out of the cell at the same time as 2 K+ are moved into the cell. This action requires 1 ATP for every 3 Na+ and 2K+ pumped across.
Why is the ratio of Na+ pumped out of the cell and K+ pumped into the cell in a 3:2 ratio?
Want to have more positive charges leaving than coming in, in order to maintain negative MP
Function of Na+-K+-ATPase?
Insure the primary control of cell volume and maintenance of Na+ and K+ gradients across the cell membrane
Structure of the Na+-K+-ATPase?
Sarcolemmal enzyme; functional dimer (alpha and beta subunits…both must be present for pump to work)
Capacity of Na+-K+-ATPase determined by?
Concentration of pumps (how many pumps there are) and the activity of the pumps (how fast/slow they are working)
Alpha subunit of Na+/K+ ATPase has binding sites for?
ATP and Na+/K+
Beta subunits in the Na+-K+-ATPase serve what purpose?
Involved in proper insertion of alpha subunit into the plasma membrane and required for proper enzymatic activity
Isoforms of alpha subunits in Na+/K+ ATPase?
Alpha 1 and alpha 2
Isoforms of Beta subunits in Na+-K+-ATPase?
Beta 1, Beta 2, and Beta 3
What happens to the NA+/K+ ATPase during exercise?
E/NE bind to beta2-adrenoreceptors, activate adenylate cyclase and increase cAMP levels. This second messenger activates protein kinase A, which increases Na+-K+-ATPase activity. Alsom alpha-beta subunits are translocated from the SR to the sarcolemma.
What is the SR?
Extensive membrane system surrounding each myofibril within muscle cells that plays a critical role in skeletal muscle to regulate intracellular free calcium, and to store Ca2+, release it, and uptake Ca2+ upon relaxation
Two parts of the SR?
Terminal Cisternae/Junctional SR and Longitudinal SR
Purpose of terminal cisternae/junctional SR?
Forms junction with T-Tubule called triad membrane (10-20 nm gap), contains Ca2+ release channel (Ryanodine Receptor), most Ca2+ is found bound to calsequestrin, and its major function is Ca2+ release
Purpose of longitudinal SR?
Contain the Ca2+-ATPase pumps (SERCA), and its major function is Ca2+ UPTAKE
Function of calsequestrin?
Found in the SR and has a high capacity Ca2+ binding (storage) in the lumen of SR
Phospholamban (PLN)?
Found in SR and regulates SERCA activity; expression is fibre type and species dependent
Sarcolipin (SLN)?
PLN homologue that regulates SERCA activity; expression is fibre and species dependent
Triadin/Junctin?
2 junctional SR proteins that form complex with CRC and CSQ to regulate CRC function
How many Ca2+ can SERCA bring into cell, and for what metabolic cost?
2 Ca2+ per 1 ATP
What do PLN and SLN do to the efficiency of SERCA?
Decrease efficiency…but increase BMR
Where is the ATP binding site on SERCA?
in the cytosol
What is the purpose of the phosphorylation domain in SERCA?
Influences activity and confirmation
How transmembrane helices does SERCA have?
10
How many binding sites does SERCA have for calcium?
2
Elementary steps of Ca2+ translocation?
- Binding of 2 Ca2+ to the enzyme in a strong binding confirmation towards the cytoplasm (2Ca2+:E1) 2. ATP binds to the enzyme (2CA2+:E1:ATP) 3. ATP is hydrolyzed and a phosphorylated intermediate is formed (2Ca2+:E1~P) 4. Change in the enzyme configuration from the E1 to E2 state with translocation of Ca2+ to the lumen (2Ca2+:E2~P) 5. Release of Ca2+ to the lumen of the SR. Affinity of Ca2+ binding sites reduced by 3-fold (E2~P) 6. Mg2+ dependent hydrolysis of the E2~P intermediate (E2~Pi) 7. Release of inorganic phosphate (E2) 8. Change in enzyme confirmation from E2 to E1 state (E1)
RYR1 gene is for expression of ryanodine receptors for what?
Skeletal muscle
RYR2 gene is for expression of ryanodine receptors for what?
Cardiac and smooth muscle
Malignant hyperthermia?
Defect in ryanodine receptor. Anesthetics or stress lead to prolonged release of Ca2+ and prolonged contraction and damage
SR proteins involved in altering efficiency of SERCA?
Phospholamban and sarcolipon
Transition of the E1 to the E2 is important in SERCA because?
Decreases affinity for Ca2+ binding to SERCA and the Ca2+ binding site is now facing the lumen
Muscle fibers are classified by?
Contractile characteristics, myofibrillar organization, E-C coupling, metabolism, phosphorylation state, membrane transporters, histochemistry, and morphological features
2 primary factors that differentiate muscle fibre types?
Rate of speed of contraction (Vmax) and fatigue characteristics
Which had faster Vmax type 1 or 2?
Type 2
The rate of speed of contraction is directly related to?
Actomyosin ATPase activity, which is determined by the MHC isoform
Order fastest to slowest muscle fibre types?
HC2B HC2x(d) HC2a HC1
Do humans express HC2b fibers?
No!!! Only rodents
At pH 4.6, M-ATPase of type 1 fibers stain?
Dark
At pH 4.6, M-ATPase of type 2a fibers stain?
Light
At pH 4.6, M-ATPase of type 2b/x fibers stain?
Medium
Type 1 fibers are acid what? Alkali what?
Acid stable, alkali labile
Type 2 fibers are acid what? Alkali what?
Acid labile, alkali stable
Index of fatigue?
Final tension/initial tension x 100
Shape of slow, fast resistant, and fast fatigue muscle fatigability graph?
Almost straight line, some what steep, super curved
The maximal rate of muscle shortening is influenced by?
Myosin heavy chain expression, which determines which myosin ATPase isoform is present
At pH of 7, which fibre type in rats would have the highest ATPase activity?
MHCIIb
At a pH of 7 what fibre type in humans would have the highest ATPase activity?
MHCIIx
What does SAG refer to?
The time it takes to observe a reduction in force output
How is SAG determined?
Using a protocol of continuous tetanic stimulations (muscle contraction) for a period of time (until force begins to drop)
Based on metabolic characteristics, fibres are classified as?
Fast-Glycolytic, Fast-Oxidative-Glycolytic, or Slow-Oxidative
For an an oxidative test, SO fibres will stain?
Dark
For an oxidative test, FOG (IIa) fibres will stain?
Medium
For an oxidative test, FG (IIx/d) will stain?
Medium-light
