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The F-actin protein was discovered by Straub in 1942. The structure was speculated based on a low-resolution x-ray crystallograph found in 1990 by Holmes et al. and over this time, despite the importance of F-actin in eukaryotic cells, this speculated structure was accepted. A higher resolution structure was only recently deposited in the PDB databank in Decemeber 2008 by Oda et al. <ref> Oda T, Iwasa M, Aihara T, Maéda Y, and Narita A. 2009. The nature of the globular-to fibrous actin transition. Nature,457(7228):441-445. PMID: [http://www.ncbi.nlm.nih.gov/pubmed/19158791/ 19158791]</ref>. | The F-actin protein was discovered by Straub in 1942. The structure was speculated based on a low-resolution x-ray crystallograph found in 1990 by Holmes et al. and over this time, despite the importance of F-actin in eukaryotic cells, this speculated structure was accepted. A higher resolution structure was only recently deposited in the PDB databank in Decemeber 2008 by Oda et al. <ref> Oda T, Iwasa M, Aihara T, Maéda Y, and Narita A. 2009. The nature of the globular-to fibrous actin transition. Nature,457(7228):441-445. PMID: [http://www.ncbi.nlm.nih.gov/pubmed/19158791/ 19158791]</ref>. | ||
=== Polymer F-actin === | === Polymer F-actin === | ||
| - | <applet load=' | + | <applet load='2zwh_black_domains' size='200' color='black' frame='true' align='left' caption='Filamentous Actin (F-actin)'/> |
<scene name='Sandbox_154/Thing_in_the_middle/1'>This thing in the middle</scene> | <scene name='Sandbox_154/Thing_in_the_middle/1'>This thing in the middle</scene> | ||
F-actin has the appearance of two right-handed helices. It is actually composed of repeats of 13 actin units for every 6 left-handed turns, spanning a length of 350 Å. <ref> Holmes, K.C., Popp, D., Gebhard, W. and Kabsch, W. 1990. Atomic model of the actin filament. Nature,347(6288):44-49. PMID: [http://www.ncbi.nlm.nih.gov/pubmed/2395461/ 2395461]</ref>. Including the ADP and Ca<sup>2+</sup>, the F-actin molecule as shown here consists of 377 residues (43kDa), two major domains separated by a nucleotide-binding cleft<ref>oda</ref>. Depending on the state of the bound nucleotide, the most stable conformation of F-actin changes. In its ATP and ADP + Pi nucleotide bound states, it has a closed binding cleft. In its ADP only bound state, it has a wider binding cleft<ref>pfaendtner</ref>. Domain movement is made possible by the rotation about the <scene name='Sandbox_154/2zwh_helix_domains/1'> 141-142 and 335-336 residue bonds</scene> shown in purple. | F-actin has the appearance of two right-handed helices. It is actually composed of repeats of 13 actin units for every 6 left-handed turns, spanning a length of 350 Å. <ref> Holmes, K.C., Popp, D., Gebhard, W. and Kabsch, W. 1990. Atomic model of the actin filament. Nature,347(6288):44-49. PMID: [http://www.ncbi.nlm.nih.gov/pubmed/2395461/ 2395461]</ref>. Including the ADP and Ca<sup>2+</sup>, the F-actin molecule as shown here consists of 377 residues (43kDa), two major domains separated by a nucleotide-binding cleft<ref>oda</ref>. Depending on the state of the bound nucleotide, the most stable conformation of F-actin changes. In its ATP and ADP + Pi nucleotide bound states, it has a closed binding cleft. In its ADP only bound state, it has a wider binding cleft<ref>pfaendtner</ref>. Domain movement is made possible by the rotation about the <scene name='Sandbox_154/2zwh_helix_domains/1'> 141-142 and 335-336 residue bonds</scene> shown in purple. | ||
Revision as of 08:44, 26 March 2010
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| 2zwh, resolution 3.30Å () | |||||||
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| Ligands: | , | ||||||
| Non-Standard Residues: | |||||||
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| Resources: | FirstGlance, OCA, RCSB, PDBsum | ||||||
| Coordinates: | save as pdb, mmCIF, xml | ||||||
Contents |
F-Actin
Filamentous actin (F-actin) is also referred to as microfilament [1] and is a highly conserved proteinous component found near ubiquitously in eukaryotic cytoskeletons. F-actin and other actin proteins generally provide a structural role to the cell.
Introduction
Actin is found in nearly all eukaryotic cells and is known primarily for its function as a structural and translocation protein. It also has an ATPase function, as it hydrolyzes ATP --> ADP + Pi and undergoes conformational changes with each hydrolysis. Actin belongs to the actin superfamily, which includes other proteins such as Hsp70 and hexokinase, because of its nucelotide-dependent conformational change reference Graceffa. Prokaryotes are not known to have actin, but do however have an actin homologue, MreB reference
Actin occurs in two forms: globular actin (G-actin), the free monomeric units of actin, and filamentous actin (F-actin) which is the polymer form. These two forms exist in a dynamic equilibrium with one another as ATP-associated polymerization and depolymerization occur continuously within the cell.
Assembly
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Monomeric Unit - G-actin
G-actin is the free monomeric form of actin which transitions to F-actin. The structures of globular and filamentous actin are distinct from one another in numerous ways, despite the fact that G-actin comprises F-actin. When the monomeric actin becomes polymerized into F-actin, the unit becomes flattened. G-actin appears to have more ion ligands in its structure, and also has the ligand RHO as opposed to 4-methyl histidine as found in the F-actin structure.
Structure
History of the structure
The F-actin protein was discovered by Straub in 1942. The structure was speculated based on a low-resolution x-ray crystallograph found in 1990 by Holmes et al. and over this time, despite the importance of F-actin in eukaryotic cells, this speculated structure was accepted. A higher resolution structure was only recently deposited in the PDB databank in Decemeber 2008 by Oda et al. [2].
Polymer F-actin
|
F-actin has the appearance of two right-handed helices. It is actually composed of repeats of 13 actin units for every 6 left-handed turns, spanning a length of 350 Å. [3]. Including the ADP and Ca2+, the F-actin molecule as shown here consists of 377 residues (43kDa), two major domains separated by a nucleotide-binding cleft[4]. Depending on the state of the bound nucleotide, the most stable conformation of F-actin changes. In its ATP and ADP + Pi nucleotide bound states, it has a closed binding cleft. In its ADP only bound state, it has a wider binding cleft[5]. Domain movement is made possible by the rotation about the shown in purple.
Domains
Function
Enzymatic Role
Active Site
Ligand
Structural Role
References
- ↑ Microfilament - Wikipedia, the free encyclopedia. http://en.wikipedia.org/wiki/Microfilaments. Date accessed: March 16th, 2010.
- ↑ Oda T, Iwasa M, Aihara T, Maéda Y, and Narita A. 2009. The nature of the globular-to fibrous actin transition. Nature,457(7228):441-445. PMID: 19158791
- ↑ Holmes, K.C., Popp, D., Gebhard, W. and Kabsch, W. 1990. Atomic model of the actin filament. Nature,347(6288):44-49. PMID: 2395461
- ↑ oda
- ↑ pfaendtner
| Please do NOT make changes to this Sandbox until after April 23, 2010. Sandboxes 151-200 are reserved until then for use by the Chemistry 307 class at UNBC taught by Prof. Andrea Gorrell. |
