Clathrin: Difference between revisions
No edit summary |
Cleaned up the references. Cleaned up the text. |
||
| Line 1: | Line 1: | ||
Clathrin is a [[Protein|protein]] heavily involved in the creation of [[Coated vesicles|coated vesicles]], it also allows for the trafficking inside cell pathways, mechanisms and regulation. It forms a polyhedral (soccer-ball-shaped) lattice made up of many clathrin molecules that | Clathrin is a [[Protein|protein]] heavily involved in the creation of [[Coated vesicles|coated vesicles]], it also allows for the trafficking inside cell pathways, mechanisms and regulation. It forms a polyhedral (soccer-ball-shaped) lattice made up of many clathrin molecules that coat a new vesicle as it forms and also helps in protein sorting<ref>J.A. Ybe et al., Nature 399 (1999), 371-375.</ref>. | ||
Clathrin subunits is made of polypeptide chains that | Clathrin subunits is made of polypeptide chains that assemble into a structure called triskelions. Each clathrin triskelions have light chains and heavy chains, which contribute to the function of clathrin coat in aiding vesicle transport. Light chains bind to the actin filament, which helps to move vesicles in the cell. N terminal domain of triskelions binds to adaptor protein, a mediator between triskelions and cargo molecules<ref>Alberts B. Molecular biology of the cell. 6th ed. New York, NY [u.a.]: Garland Science Taylor &amp;amp;amp; Francis; 2014.</ref>. | ||
Vesicles do not form spontaneously, but rather, are facilitated by coat-proteins like clathrin. Clathrin doesn't bind directly to a membrane to form vesicles; instead, it binds to adaptor proteins that recognize molecules on a membrane surface. At least 20 different clathrin adaptors have been identified, each recognizing and binding to membrane proteins and phospholipids that are unique to a particular [[Organelle|organelle]]<ref>RCSB Molecule of the Month by Graham T. Johnson and David Goodsell (April 2007)</ref>. | Vesicles do not form spontaneously, but rather, are facilitated by coat-proteins like clathrin. Clathrin doesn't bind directly to a membrane to form vesicles; instead, it binds to adaptor proteins that recognize molecules on a membrane surface. At least 20 different clathrin adaptors have been identified, each recognizing and binding to membrane proteins and phospholipids that are unique to a particular [[Organelle|organelle]]<ref>RCSB Molecule of the Month by Graham T. Johnson and David Goodsell (April 2007)</ref>. | ||
| Line 7: | Line 7: | ||
During vesicle transport, cargo-loaded vesicles form at a donor compartment, with the help of the specialised clathrin coat. It is one of three types of coating. | During vesicle transport, cargo-loaded vesicles form at a donor compartment, with the help of the specialised clathrin coat. It is one of three types of coating. | ||
Clathrin-dependent endocytosis is the process by which cells undergo [[Endocytosis|endocytosis]] by the inward budding of plasma membrane<ref>Trafficking inside cells, pathways, mechanisms and regulation – Nava Segar Springer Lin (c2009) pages 7-9</ref>. | Clathrin-dependent endocytosis is the process by which cells undergo [[Endocytosis|endocytosis]] by the inward budding of plasma membrane<ref>Trafficking inside cells, pathways, mechanisms and regulation – Nava Segar Springer Lin (c2009) pages 7-9</ref>. | ||
=== References === | |||
<references /> | |||
Latest revision as of 19:58, 4 December 2017
Clathrin is a protein heavily involved in the creation of coated vesicles, it also allows for the trafficking inside cell pathways, mechanisms and regulation. It forms a polyhedral (soccer-ball-shaped) lattice made up of many clathrin molecules that coat a new vesicle as it forms and also helps in protein sorting[1].
Clathrin subunits is made of polypeptide chains that assemble into a structure called triskelions. Each clathrin triskelions have light chains and heavy chains, which contribute to the function of clathrin coat in aiding vesicle transport. Light chains bind to the actin filament, which helps to move vesicles in the cell. N terminal domain of triskelions binds to adaptor protein, a mediator between triskelions and cargo molecules[2].
Vesicles do not form spontaneously, but rather, are facilitated by coat-proteins like clathrin. Clathrin doesn't bind directly to a membrane to form vesicles; instead, it binds to adaptor proteins that recognize molecules on a membrane surface. At least 20 different clathrin adaptors have been identified, each recognizing and binding to membrane proteins and phospholipids that are unique to a particular organelle[3].
During vesicle transport, cargo-loaded vesicles form at a donor compartment, with the help of the specialised clathrin coat. It is one of three types of coating.
Clathrin-dependent endocytosis is the process by which cells undergo endocytosis by the inward budding of plasma membrane[4].
References
- ↑ J.A. Ybe et al., Nature 399 (1999), 371-375.
- ↑ Alberts B. Molecular biology of the cell. 6th ed. New York, NY [u.a.]: Garland Science Taylor &amp;amp; Francis; 2014.
- ↑ RCSB Molecule of the Month by Graham T. Johnson and David Goodsell (April 2007)
- ↑ Trafficking inside cells, pathways, mechanisms and regulation – Nava Segar Springer Lin (c2009) pages 7-9