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Myofilament

From Wikipedia, the free encyclopedia

Myofilament
Myofilament
Details
Part ofMyofibril
Identifiers
Latinmyofilamentum
THH2.00.05.0.00006  
FMA67897
Anatomical terms of microanatomy

Myofilaments are the three protein filaments of myofibrils in muscle cells. The main proteins involved are myosin, actin, and titin. Myosin and actin are the contractile proteins and titin is an elastic protein. The myofilaments act together in muscle contraction, and in order of size are a thick one of mostly myosin, a thin one of mostly actin, and a very thin one of mostly titin.[1][2]

Types of muscle tissue are striated skeletal muscle and cardiac muscle, obliquely striated muscle (found in some invertebrates), and non-striated smooth muscle.[3] Various arrangements of myofilaments create different muscles. Striated muscle has transverse bands of filaments. In obliquely striated muscle, the filaments are staggered. Smooth muscle has irregular arrangements of filaments.

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Transcription

Romeo and Juliet. Helen and Paris. Tristan and Isolde. These famous star-crossed lovers bring to mind insatiable longing, forbidden love, and tragic separation. And poets and emo rockers love them for it. But you know where else you can find a nice hot romance? Your muscle cells. They’ve got their own famous coupling -- a pretty pair of tiny protein strands called actin and myosin. Romeo and Juliet may have set a chain of tragic events into motion with their infatuation, but deep down in the cells of your muscles, the hot protein action between actin and myosin is actually, literally causing all of your motions. ALL of them. And I don’t just mean voluntary stuff, like walking down the street, or moving your mouth so you can talk or chew chips. Because your muscles also support your weight and help fend off gravity. The amazing thing about your complicated, self-healing, blood-guzzling muscle tissues is that they turn chemical potential energy into mechanical energy, or movement, simply by doing two things -- contracting and relaxing. And that contracting and relaxing is exactly what’s fueled by the constant coupling and separation of biology’s greatest lovers. Somebody get these proteins a movie contract. You will recall from our early lessons on tissues that you’re kept alive and moving by three types of muscle tissue: smooth, cardiac, and skeletal. Your smooth muscle tissue is found in the walls of all your hollow visceral organs, like your stomach, and airways, and blood vessels, where it involuntarily and very usefully pushes fluid and other material around by contracting and relaxing, over and over. Your heart is so important that it gets its very own muscle tissue type -- cardiac muscle, which looks striped, or striated, and also functions involuntarily to keep your blood pumping without you having to think about it. But when you hear the word “muscle,” you probably think of the kind you see on Chris Evans when he first walks out of that machine in Captain America. And those types -- the ones you can see and feel and flex -- are your 640 skeletal muscles. They’re striated like cardiac muscle tissue, but they’re also mostly voluntary, meaning you have to think about using them and activate them with your somatic nervous system. Most of them attach to your skeleton, and create movement by pulling bones in different directions as they contract. Each one of your different skeletal muscles -- like your biceps brachii, or vastus lateralis or gluteus maximus -- is technically its own organ, made up mostly of muscle tissue, but also of connective tissue, blood vessels, and nerve fibers. And because your muscles are voracious energy hogs, each one is rigged up with its own personal nerve to stimulate contraction, and its own artery and vein to keep it well-fed with all the blood, and oxygen, and nutrients it needs to operate. But to understand those operations, we first need to get a grip on the anatomy of a skeletal muscle, which involves fibers within fibers, and lots of layers. Basically, a skeletal muscle is constructed like a really sturdy piece of rope. Thousands of tiny, parallel threads called myofibrils squish together to form muscle fibers, which are your actual muscle cells -- cells with mitochondria, multiple nuclei, and a cellular membrane called a sarcolemma. Those muscle fibers then form larger, string-like bundles called fascicles, which combine to form the larger rope-like muscle organ, like your biceps brachii. Overall, this bundles-of-bundles configuration makes muscle tissue fairly sturdy. But considering how much abuse your muscles take when you do something like pretty simple, like lift a big bag of dog food, it’s no surprise they need a little help. That’s why every muscle contains a few different kinds of supportive sheaths of connective tissue -- the protective reinforcements to keep that bulging muscle from bursting. So that is the structure part of the story. But if you want to get into the nitty-gritty -- the down-and-dirty -- of how you actually move, well, there are rules. Really, just two main rules, and they have to do with proteins. And they’re both true for a lot of the proteins we talk about, whether they’re enzymes or ion channels or receptors or muscle proteins. And these rules are: One. Proteins like to change shape when stuff binds to them. And two. Changing shapes can allow proteins to bind -- or unbind -- with other stuff. So keep those rules in mind, while we see how a muscle fiber contracts and relaxes. Now, remember those tiny myofibrils that bundle up to form your muscle fibers? They’re divided lengthwise into segments called sarcomeres, which contain two even tinier strands of protein -- two different kinds of myofilaments called actin and myosin. And it’s their angsty story of star-crossed love that fuels every movement your body could possibly dream up. A sarcomere contains both thin filaments, made up mostly of two light and twisty actin strands, and thick filaments, composed of thicker, lumpy-looking myosin strands. Each sarcomere is separated by what’s known as a Z line at either end, which is just a border formed by alternating thin filaments in a kind of zig zag pattern. A muscle contracting is all about sarcomeres contracting, bringing those Z-lines closer together. All right, so now comes the romance. When your muscle cells are at rest, your actin & myosin strands don’t touch, but they really, really want to. Specifically, that club-headed myosin wants to get all up-close-and-personal with the actin. When this happens -- and it will, eventually -- it’s called the sliding filament model of muscle contraction. But in the meantime, like in any good love story, the pair have some obstacles to overcome. Namely, actin is blocked by a couple of protein bodyguards -- called tropomyosin and troponin -- which keep getting in the way. Luckily, these guards can be bought off with a little ATP and some calcium. I prefer cash and nachos, but whatever. Remember, ATP is kind of like molecular currency. It contains chemical energy, and your muscles are all about converting chemical energy to motion, so they’re always hungry for more ATP. Your muscle cells have lots of nuclei, but some of them also have a lot of mitochondria, whose sole purpose in life is to crank out ATP. And muscle cells also have their own version of an endoplasmic reticulum -- the cell’s transport and storage system -- but in this case it’s specialized, so it gets a special name: the sarcoplasmic reticulum. Its walls are loaded with calcium pumps -- which use ATP to save up a bunch of calcium ions. And it’s also studded with calcium channels that are linked to voltage-sensitive proteins in the membrane of the muscle cell. Say I want to move my arm. My brain sends an action potential along the motor neuron until it synapses with a muscle cell in my arm. The receptors on that muscle cell are ligand-gated sodium channels, so when the motor neuron releases our old friend acetylcholine into the synapse, the channels open up, and create a rush of sodium into the cell as a graded potential, which, if it’s strong enough, causes nearby voltage-gated sodium channels to open. Now, I want to take a second and point out here that we’re still talking about an action potential, but not in a neuron. This is happening in a muscle cell, people. So that action potential zips along a muscle cell’s membrane, the sarcolemma, which has lots of tubes that run deep inside the cell, called T-Tubules. When the action potential travels down one of those tubes, it eventually triggers the voltage-sensitive proteins that are linked to those calcium channels on the cell’s sarcoplasmic reticulum. When those channels are thrown open, the calcium stored inside rushes into the rest of the cell, and finally myosin is like, YES! Here we go! At this point, the myosin is totally stoked, because the bodyguards that have been frustrating it are in for a big, irresistible distraction. That’s because the protein troponin just loves to bind with calcium, and remember: When stuff binds to proteins, the proteins change shape. So the calcium latches on to the troponin and causes it to pull the other bodyguard protein -- the tropomyosin -- away from the sites on the actin strands that the myosin really wants to get its paws on. And suddenly it’s all, “Okay?” “Okay.” But the only myosin heads that can bind to those newly exposed sites are ones that are ready for action. That is, the ones that have already grabbed a molecule of ATP that’s been floating around, and broken it down into ADP and the leftover phosphate. When a myosin head does that, it moves into an extended position, kinda like a stretched spring -- still holding on to the ADP and phosphate, and still storing the energy that was released when they were broken apart. So after all that, with the myosin primed for action and the bodyguards out of the way, the myosin finally binds to actin, and it is beautiful. When they bind, the myosin releases all that stored energy, and -- in the excitement of it all -- the myosin changes shape. It pulls on its precious actin strand, kind of like pulling a rope hand over fist. In the process, it shrinks the whole sarcomere, and contracts the muscle. That’s the sliding part of the sliding filament model. Now, with its energy spent, that little head has no use for the ADP and the phosphate. So they un-bind with it, because -- remember Rule Number Two, changing shape encourages proteins to bind or unbind with stuff. That unbinding causes a small change in its shape, which lets a fresh ATP binds there in its place. That binding causes another shape change. But this time, it causes the myosin to release from the actin, in a tear-jerking scene like some microscopic re-creation of the finale from Titanic. But fear not! This epic is not quite over! Because this is when the myosin breaks down its new molecule of ATP into ADP and a phosphate, which moves it into the armed position yet again, getting it ready for its next rendezvous. And meanwhile, those calcium pumps are working hard to restock the calcium in the sarcoplasmic reticulum. So they start grabbing the calcium that’s floating around, causing calcium to unbind from the troponin. When it unbinds, the resulting shape-change puts the tropomyosin bodyguards back into place. It’s a circle. Or potentially a big Hollywood franchise. With lots and lots of sequels. It keeps repeating itself many, many times every moment, while I sit here and talk, and while you sit there and eat and text and take notes, the whole drama replaying itself over and over. Kind of like you’ll have to play this video over and over again to get all the little steps of the sliding filament model straightened out. But hey, some stories get better the more you hear them. If you do watch this one again, you will re-learn that your smooth, cardiac, and skeletal muscles create movement by contracting and releasing in a process called the sliding filament model. You’d also re-learn that your skeletal muscles are constructed like a rope made of bundles of protein fibers, and that the smallest strands are your actin and myosin myofilaments. Its their use of calcium and ATP that causes the binding and unbinding that makes sarcomeres contract and relax. Special thanks to our Headmaster of Learning Thomas Frank for his support of Crash Course and free education. And thank you to all of our Patreon patrons who help make Crash Course possible through their monthly contributions. If you like Crash Course and want to help us keep making great new videos like this one, you can check out patreon.com/crashcourse Crash Course is filmed in the Doctor Cheryl C. Kinney Crash Course Studio. This episode was written by Kathleen Yale, edited by Blake de Pastino, and our consultant, is Dr. Brandon Jackson. Our director is Nicholas Jenkins, the editor and script supervisor is Nicole Sweeney, our sound designer is Michael Aranda, and the graphics team is Thought Café.

Structure

Muscle fiber showing thick and thin myofilaments of a myofibril.

There are three different types of myofilaments: thick, thin, and elastic filaments.[1]

  • Thick filaments consist primarily of a type of myosin, a motor proteinmyosin II. Each thick filament is approximately 15 nm in diameter, and each is made of several hundred molecules of myosin. A myosin molecule is shaped like a golf club, with a tail formed of two intertwined chains and a double globular head projecting from it at an angle. Half of the myosin heads angle to the left and half of them angle to the right, creating an area in the middle of the filament known as the M-region or bare zone.[4]
  • Thin filaments, are 7 nm in diameter, and consist primarily of the protein actin, specifically filamentous F-actin. Each F-actin strand is composed of a string of subunits called globular G-actin. Each G-actin has an active site that can bind to the head of a myosin molecule. Each thin filament also has approximately 40 to 60 molecules of tropomyosin, the protein that blocks the active sites of the thin filaments when the muscle is relaxed. Each tropomyosin molecule has a smaller calcium-binding protein called troponin bound to it. All thin filaments are attached to the Z-line.
  • Elastic filaments, 1 nm in diameter, are made of titin, a large springy protein. They run through the core of each thick filament and anchor it to the Z-line, the end point of a sarcomere.[citation needed] Titin also stabilizes the thick filament, while centering it between the thin filaments. It also aids in preventing overstretching of the thick filament, recoiling like a spring whenever a muscle is stretched.

Function

Further information: Muscle cell § Muscle contraction in striated muscle

The protein complex composed of actin and myosin, contractile proteins, is sometimes referred to as actomyosin. In striated skeletal and cardiac muscle, the actin and myosin filaments each have a specific and constant length in the order of a few micrometers, far less than the length of the elongated muscle cell (up to several centimeters in some skeletal muscle cells).[5] The contractile nature of this protein complex is based on the structure of the thick and thin filaments. The thick filament, myosin, has a double-headed structure, with the heads positioned at opposite ends of the molecule. During muscle contraction, the heads of the myosin filaments attach to oppositely oriented thin filaments, actin, and pull them past one another. The action of myosin attachment and actin movement results in sarcomere shortening. Muscle contraction consists of the simultaneous shortening of multiple sarcomeres.[6]

Muscle fiber contraction

Main article: Muscle contraction

The axon terminal of a motor neuron releases the neurotransmitter, acetylcholine, which diffuses across the synaptic cleft and binds to the muscle fiber membrane. This depolarizes the muscle fiber membrane, and the impulse travels to the muscle's sarcoplasmic reticulum via the transverse tubules. Calcium ions are then released from the sarcoplasmic reticulum into the sarcoplasm and subsequently bind to troponin. Troponin and the associated tropomyosin undergo a conformational change after calcium binding and expose the myosin binding sites on actin, the thin filament. The filaments of actin and myosin then form linkages. After binding, myosin pulls actin filaments toward each other, or inward. Thus muscle contraction occurs, and the sarcomere shortens as this process takes place.[7]

Muscle fiber relaxation

The enzyme acetylcholinesterase breaks down acetylcholine and this ceases muscle fiber stimulation. Active transport moves calcium ions back into the sarcoplasmic reticulum of the muscle fiber. ATP causes the binding between actin and myosin filaments to break. Troponin and tropomyosin revert to their original conformation and thereby block binding sites on the actin filament. The muscle fiber relaxes and the entire sarcomere lengthens. The muscle fiber is now prepared for the next contraction.[8]

Response to exercise

The changes that occur to the myofilament in response to exercise have long been a subject of interest to exercise physiologists and the athletes who depend on their research for the most advanced training techniques. Athletes across a spectrum of sporting events are particularly interested to know what type of training protocol will result in maximal force generation from a muscle or set of muscles, so much attention has been given to changes in the myofilament under bouts of chronic and acute forms of exercise.

While the exact mechanism of myofilament alteration in response to exercise is still being studied in mammals, some interesting clues have been revealed in Thoroughbred race horses. Researchers studied the presence of mRNA in skeletal muscle of horses at three distinct times; immediately before training, immediately after training, and four hours after training. They reported statistically significant differences in mRNA for genes specific to production of actin. This study provides evidence of the mechanisms for both immediate and delayed myofilament response to exercise at the molecular level.[9]

More recently, myofilament protein changes have been studied in humans in response to resistance training. Again, researchers are not completely clear about the molecular mechanisms of change, and an alteration of fiber-type composition in the myofilament may not be the answer many athletes have long assumed.[10] This study looked at the muscle specific tension in the quadriceps femoris and vastus lateralis of forty-two young men. Researchers report a 17% increase in specific muscle tension after a period of resistance training, despite a decrease in the presence of MyHC, myosin heavy-chain. This study concludes that there is no clear relationship between fiber-type composition and in vivo muscle tension, nor was there evidence of myofilament packing in the trained muscles.

Research

Other promising areas of research that may illumine the exact molecular nature of exercise-induced protein remodeling in muscle may be the study of related proteins involved with cell architecture, such as desmin and dystrophin. These proteins are thought to provide the cellular scaffolding necessary for the actin-myosin complex to undergo contraction. Research on desmin revealed that its presence increased greatly in a test group exposed to resistance training, while there was no evidence of desmin increase with endurance training. According to this study, there was no detectable increase in dystrophin in resistance or endurance training.[11] It may be that exercise-induced myofilament alterations involve more than the contractile proteins actin & myosin.

While the research on muscle fiber remodeling is on-going, there are generally accepted facts about the myofilament from the American College of Sports Medicine.[citation needed] It is thought that an increase in muscle strength is due to an increase in muscle fiber size, not an increase in number of muscle fibers and myofilaments. However, there is some evidence of animal satellite cells differentiating into new muscle fibers and not merely providing a support function to muscle cells.

The weakened contractile function of skeletal muscle is also linked to the state of the myofibrils. Recent studies suggest that these conditions are associated with altered single fiber performance due to decreased expression of myofilament proteins and/or changes in myosin-actin cross-bridge interactions. Furthermore, cellular and myofilament-level adaptations are related to diminished whole muscle and whole body performance.[12]

References

  1. ^ a b Saladin, Kenneth (2012). Anatomy & physiology : the unity of form and function (6th ed.). New York, NY: McGraw-Hill. pp. 245–246. ISBN 9780073378251.
  2. ^ Kellermayer, D; Smith JE, 3rd; Granzier, H (May 2019). "Titin mutations and muscle disease". Pflügers Archiv: European Journal of Physiology. 471 (5): 673–682. doi:10.1007/s00424-019-02272-5. PMC 6481931. PMID 30919088.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  3. ^ Cao, T; Thongam, U; Jin, JP (15 May 2019). "Invertebrate troponin: Insights into the evolution and regulation of striated muscle contraction". Archives of Biochemistry and Biophysics. 666: 40–45. doi:10.1016/j.abb.2019.03.013. PMC 6529277. PMID 30928296.
  4. ^ Al-Khayat, HA; Kensler, RW; Morris, EP; Squire, JM (12 November 2010). "Three-dimensional structure of the M-region (bare zone) of vertebrate striated muscle myosin filaments by single-particle analysis". Journal of Molecular Biology. 403 (5): 763–76. doi:10.1016/j.jmb.2010.09.025. PMC 3314970. PMID 20851129.
  5. ^ Alberts, Bruce (2015). Molecular biology of the cell (Sixth ed.). New York, NY. p. 918. ISBN 9780815344643.{{cite book}}: CS1 maint: location missing publisher (link)
  6. ^ Alberts, Bruce., et al., "Muscle Contraction." Essential Cell Biology. 3rd. New York: Garland Science, 2010. p. 599. Print.
  7. ^ Shier, David., et al., "Muscular System", Hole's Essentials of Anatomy & Physiology. 9th. McGraw Hill, 2006. p. 175. Print.
  8. ^ Shier, David., et al., "Muscular System", Hole's Essentials of Anatomy & Physiology. 9th. McGraw Hill, 2006. p. 175. Print.
  9. ^ McGivney BA, Eivers SS, MacHugh DE, et al. (2009). "Transcriptional adaptations following exercise in thoroughbred horse skeletal muscle highlights molecular mechanisms that lead to muscle hypertrophy". BMC Genomics. 10: 638. doi:10.1186/1471-2164-10-638. PMC 2812474. PMID 20042072.
  10. ^ Erskine RM, Jones DA, Maffulli N, Williams AG, Stewart CE, Degens H (February 2011). "What causes in vivo muscle specific tension to increase following resistance training?". Exp. Physiol. 96 (2): 145–55. doi:10.1113/expphysiol.2010.053975. PMID 20889606. S2CID 20304624.
  11. ^ Parcell AC, Woolstenhulme MT, Sawyer RD (March 2009). "Structural protein alterations to resistance and endurance cycling exercise training". J Strength Cond Res. 23 (2): 359–65. doi:10.1519/JSC.0b013e318198fd62. PMID 19209072. S2CID 29584507.
  12. ^ Miller MS, Callahan DM, Toth MJ (2014). "Skeletal muscle myofilament adaptations to aging, disease, and disuse and their effects on whole muscle performance in older adult humans". Front Physiol. 5: 369. doi:10.3389/fphys.2014.00369. PMC 4176476. PMID 25309456.
  • Muscle :: Diversity of Muscle—Britannica Online Encyclopedia." Encyclopedia - Britannica Online Encyclopedia. Web.
  • Saladin, Kenneth S. "Myofilaments." Anatomy & Physiology: the Unity of Form and Function. 5th ed. New York: McGraw-Hill, 2010. 406–07. Print.

External links

This page was last edited on 15 October 2023, at 18:04
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