Actin filaments: Difference between revisions

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Actin filaments are the thinnest of the three components of the [[Cytoskeleton|cytoskeleton]] in respect to its diameter (measuring 7-8nm in diameter in stained sections of muscle cells) and thus, makes it the most flexible. It is required for the movement on the surface of the [[Cell|cells]] and also to maintain the shape of the [[Cell|cell]], through a hign concentration of actin filaments beneath the cell membrane known as the cell cortex. They are found in cells such as [[Microvilli|microvilli]], [[Filopodia|filopodia]] as well as contractile bundles, the [[Plasma membrane|plasma membrane]] and also [[Muscle cell|muscle cells]]. In some preparations they are arranged in rosettes around myosin filaments; however they are most often gathered into bundles or cables,which are many microns long and often merge or branch and terminate by penetrating into a dense body/dense band.  
The protein actin is abundant in all eukaryotic cells. It was first discovered in [[Skeletal muscle|skeletal muscle]], where actin filaments slide along filaments of another protein called [[Myosin|myosin]] to make the cells contract. (In nonmuscle cells, actin filaments are less organized and [[Myosin|myosin]] is much less prominent.) Single actin monomers are called G-actin, these monomers polymerize into long filaments called F-actin which are about 7nm in diameter. Actin filaments are made up of identical actin proteins arranged in a long spiral chain. Like [[Microtubules|microtubules]], actin filaments have plus and minus ends, with more [[ATP|ATP]]-powered growth occurring at a filament's plus end. Once the filament has been synthesized it folds into a U-shape containing a binding site for [[ATP|ATP]] or [[ADP|ADP]] in the middle<ref>Hardin J, Bertoni G, Kleinsmith L J (2012) Becker's World of the Cell, 8th Edition, San Francisco, Pearson Education Inc. Pages: 434-437</ref>.  


Actin filament is a polymer made by polymerisation of actin monomers&nbsp;by hydrolysis of&nbsp;[[ATP|ATP]]. The filament is polarised and the monomers are more readily added to the positive side of the filament. And polymerisation is also regulated by different set of binding proteins such as bundle protein, cross linked protein, motor proteins etc.  
Actin-binding proteins interact with the actin filaments or monomers and regulate their assembly and organisation, they can convert actin from one form to another. These proteins include: severing proteins, filament capping proteins, crosslinking proteins, anchoring proteins, filament bundling proteins and monomer binding proteins.  


Actin is an abundant protein in typical animal cells and accounts for arround 5% of all proteins in the cell. Half of this can be found in filaments and the other half remains as monomers in the [[Cytosol|cytosol]] of the cell.  
In many types of cells, networks of actin filaments are found beneath the cell cortex, which is the meshwork of membrane-associated proteins that supports and strengthens the plasma membrane. Such networks allow cells to hold - and move - specialized shapes, such as the brush border of [[Microvilli|microvilli]]. [[Actin|Actin]] filaments are also involved in [[Cytokinesis|cytokinesis]] and cell movement due to their flexible and dynamic nature. For example. crawling cells have structures called [[Lamellipodia|lamellipodia]] and [[Filopodia|filopodia]]; polymerisation of the actin at the plus end extends the lamellipodium, this puts stress under the unpolymerized actin in the cortex causing retraction at the tail of the cell. This enables the cell to move along a surface<ref>Hardin J, Bertoni G, Kleinsmith LJ (2012)Becker's World of the Cell, 8th Edition, San Francisco, Pearson Education Inc. Pages: 436-437</ref>.  


The actin filament's motor proteins are the myosin. [[Myosin|Myosin]] have a head and a tail, the head binds to the actin filament and the tail is bound to [[Plasma membrane|plasma membrane]], [[Vesicles|vesicles]] and other yosin proteins. The hydrolysis of [[ATP|ATP]] drives the myosin resulting in movement.
=== References  ===


Myosin is further divided into [[Myosin 1|myosin 1]] and [[Myosin 2|myosin 2]].
<references />
 
Also see [[Actin|actin]]

Latest revision as of 11:34, 19 November 2018

The protein actin is abundant in all eukaryotic cells. It was first discovered in skeletal muscle, where actin filaments slide along filaments of another protein called myosin to make the cells contract. (In nonmuscle cells, actin filaments are less organized and myosin is much less prominent.) Single actin monomers are called G-actin, these monomers polymerize into long filaments called F-actin which are about 7nm in diameter. Actin filaments are made up of identical actin proteins arranged in a long spiral chain. Like microtubules, actin filaments have plus and minus ends, with more ATP-powered growth occurring at a filament's plus end. Once the filament has been synthesized it folds into a U-shape containing a binding site for ATP or ADP in the middle[1].

Actin-binding proteins interact with the actin filaments or monomers and regulate their assembly and organisation, they can convert actin from one form to another. These proteins include: severing proteins, filament capping proteins, crosslinking proteins, anchoring proteins, filament bundling proteins and monomer binding proteins.

In many types of cells, networks of actin filaments are found beneath the cell cortex, which is the meshwork of membrane-associated proteins that supports and strengthens the plasma membrane. Such networks allow cells to hold - and move - specialized shapes, such as the brush border of microvilli. Actin filaments are also involved in cytokinesis and cell movement due to their flexible and dynamic nature. For example. crawling cells have structures called lamellipodia and filopodia; polymerisation of the actin at the plus end extends the lamellipodium, this puts stress under the unpolymerized actin in the cortex causing retraction at the tail of the cell. This enables the cell to move along a surface[2].

References

  1. Hardin J, Bertoni G, Kleinsmith L J (2012) Becker's World of the Cell, 8th Edition, San Francisco, Pearson Education Inc. Pages: 434-437
  2. Hardin J, Bertoni G, Kleinsmith LJ (2012)Becker's World of the Cell, 8th Edition, San Francisco, Pearson Education Inc. Pages: 436-437
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