Clathrin Explained

Class:collapsible
Symbol:Clathrin_propel
Clathrin heavy N-terminal propeller repeat
Pfam:PF01394
Pfam Clan:CL0020
Interpro:IPR022365
Scop:1bpo
Class:collapsible
Symbol:Clathrin-link
Clathrin heavy-chain linker
Pfam:PF09268
Pfam Clan:CL0020
Interpro:IPR015348
Scop:1b89
Class:collapsible
Symbol:Clathrin_propel
/VPS 7-fold repeat
Pfam:PF00637
Pfam Clan:CL0020
Interpro:IPR000547
Smart:SM00299
Prosite:PS50236
Scop:1b89
Cath:1b89
Class:collapsible
Symbol:Clathrin_lg_ch
Clathrin light chain
Pfam:PF01086
Interpro:IPR000996
Prosite:PDOC00196
Scop:3iyv

Clathrin is a protein that plays a major role in the formation of coated vesicles. Clathrin was first isolated by Barbara Pearse in 1976.[1] It forms a triskelion shape composed of three clathrin heavy chains and three light chains. When the triskelia interact they form a polyhedral lattice that surrounds the vesicle. The protein's name refers to this lattice structure, deriving from Latin clathri meaning lattice.[2] Barbara Pearse named the protein clathrin at the suggestion of Graeme Mitchison, selecting it from three possible options.[3] Coat-proteins, like clathrin, are used to build small vesicles in order to transport molecules within cells. The endocytosis and exocytosis of vesicles allows cells to communicate, to transfer nutrients, to import signaling receptors, to mediate an immune response after sampling the extracellular world, and to clean up the cell debris left by tissue inflammation. The endocytic pathway can be hijacked by viruses and other pathogens in order to gain entry to the cell during infection.[4]

Structure

Clathrin light chain a
Bodyclass:collapsible collapsed
Symbol:CLTA
Entrezgene:1211
Hgncid:HGNC:2090. CLTA.
Uniprot:P09496
Chromosome:9
Arm:q
Band:13
Clathrin light chain b
Bodyclass:collapsible collapsed
Hgncid:2091
Symbol:CLTB
Entrezgene:1212
Omim:118970
Refseq:NM_001834
Uniprot:P09497
Chromosome:5
Arm:q
Band:35
Clathrin heavy chain 1
Bodyclass:collapsible collapsed
Hgncid:2092
Symbol:CLTC
Altsymbols:CHC, CHC17, CLTCL2
Entrezgene:1213
Omim:118955
Refseq:NM_004859
Uniprot:Q00610
Chromosome:17
Arm:q
Band:23.1
Locussupplementarydata:-qter
Clathrin heavy chain 2
Bodyclass:collapsible collapsed
Hgncid:2093
Symbol:CLTCL1
Altsymbols:CLTCL
Entrezgene:8218
Omim:601273
Refseq:NM_001835
Uniprot:P53675
Chromosome:22
Arm:q
Band:11.21

The clathrin triskelion is composed of three clathrin heavy chains interacting at their C-termini, each ~190 kDa heavy chain has a ~25 kDa light chain tightly bound to it. The three heavy chains provide the structural backbone of the clathrin lattice, and the three light chains are thought to regulate the formation and disassembly of a clathrin lattice. There are two forms of clathrin light chains, designated a and b. The main clathrin heavy chain, located on chromosome 17 in humans, is found in all cells. A second clathrin heavy chain gene, on chromosome 22, is expressed in muscle.[5]

Clathrin heavy chain is often described as a leg, with subdomains, representing the foot (the N-terminal domain), followed by the ankle, distal leg, knee, proximal leg, and trimerization domains. The N-terminal domain consists of a seven-bladed β-propeller structure. The other domains form a super-helix of short alpha helices. This was originally determined from the structure of the proximal leg domain that identified and is composed of a smaller structural module referred to as clathrin heavy chain repeat motifs. The light chains bind primarily to the proximal leg portion of the heavy chain with some interaction near the trimerization domain. The β-propeller at the 'foot' of clathrin contains multiple binding sites for interaction with other proteins.[6]

When triskelia assemble together in solution, they can interact with enough flexibility to form 6-sided rings (hexagons) that yield a flat lattice, or 5-sided rings (pentagons) that are necessary for curved lattice formation. When many triskelions connect, they can form a basket-like structure. The structure shown, is built of 36 triskelia, one of which is shown in blue. Another common assembly is a truncated icosahedron. To enclose a vesicle, exactly 12 pentagons must be present in the lattice.

In a cell, clathrin triskelion in the cytoplasm binds to an adaptor protein that has bound membrane, linking one of its three feet to the membrane at a time. Clathrin cannot bind to membrane or cargo directly and instead uses adaptor proteins to do this. This triskelion will bind to other membrane-attached triskelia to form a rounded lattice of hexagons and pentagons, reminiscent of the panels on a soccer ball, that pulls the membrane into a bud. By constructing different combinations of 5-sided and 6-sided rings, vesicles of different sizes may assemble. The smallest clathrin cage commonly imaged, called a mini-coat, has 12 pentagons and only two hexagons. Even smaller cages with zero hexagons probably do not form from the native protein, because the feet of the triskelia are too bulky.[7]

Function

Clathrin performs critical roles in shaping rounded vesicles in the cytoplasm for intracellular trafficking. Clathrin-coated vesicles (CCVs) selectively sort cargo at the cell membrane, trans-Golgi network, and endosomal compartments for multiple membrane traffic pathways. After a vesicle buds into the cytoplasm, the coat rapidly disassembles, allowing the clathrin to recycle while the vesicle gets transported to a variety of locations.

Adaptor molecules are responsible for self-assembly and recruitment. Two examples of adaptor proteins are AP180[8] and epsin.[9] [10] [11] AP180 is used in synaptic vesicle formation. It recruits clathrin to membranes and also promotes its polymerization. Epsin also recruits clathrin to membranes and promotes its polymerization, and can help deform the membrane, and thus clathrin-coated vesicles can bud. In a cell, a triskelion floating in the cytoplasm binds to an adaptor protein, linking one of its feet to the membrane at a time. The triskelion foot will bind to other ones attached to the membrane to form a polyhedral lattice, triskelion foot, which pulls the membrane into a bud. The foot does not bind directly to the membrane, but binds to the adaptor proteins that recognize the molecules on the membrane surface.

Clathrin has another function aside from the coating of organelles. In non-dividing cells, the formation of clathrin-coated vesicles occurs continuously. Formation of clathrin-coated vesicles is shut down in cells undergoing mitosis. During mitosis, clathrin binds to the spindle apparatus, in complex with two other proteins: TACC3 and ch-TOG/CKAP5. Clathrin aids in the congression of chromosomes by stabilizing kinetochore fibers of the mitotic spindle. The amino-terminal domain of the clathrin heavy chain and the TACC domain of TACC3 make the microtubule binding surface for TACC3/ch-TOG/clathrin to bind to the mitotic spindle. The stabilization of kinetochore fibers requires the trimeric structure of clathrin in order to crosslink microtubules.[12] [13] [14]

Clathrin-mediated endocytosis (CME) regulates many cellular physiological processes such as the internalization of growth factors and receptors, entry of pathogens, and synaptic transmission. It is believed that cellular invaders use the nutrient pathway to gain access to a cell's replicating mechanisms. Certain signalling molecules open the nutrients pathway. Two chemical compounds called Pitstop 1 and Pitstop 2, selective clathrin inhibitors, can interfere with the pathogenic activity, and thus protect the cells against invasion. These two compounds selectively block the endocytic ligand association with the clathrin terminal domain in vitro.[15] However, the specificity of these compounds to block clathrin-mediated endocytosis has been questioned.[16] In later studies, however, the specificity of Pitstop 2 was validated as being clathrin dependent.[17]

See also

Further reading

External links

Notes and References

  1. Pearse BM . Clathrin: a unique protein associated with intracellular transfer of membrane by coated vesicles . Proceedings of the National Academy of Sciences of the United States of America . 73 . 4 . 1255–1259 . April 1976 . 1063406 . 430241 . 10.1073/pnas.73.4.1255 . free . 1976PNAS...73.1255P .
  2. Web site: clathrate, adjective . . Merriam-Webster . 29 November 2023.
  3. Pearse BM . Clathrin and coated vesicles . EMBO J . 6 . 9 . 2507–12 . September 1987 . 2890519 . 553666 . 10.1002/j.1460-2075.1987.tb02536.x .
  4. Web site: InterPro . 2015-10-07 . live . https://web.archive.org/web/20160116085409/http://www.ebi.ac.uk/interpro/potm/2007_4/Page1.htm . 2016-01-16 .
  5. Robinson MS . Forty Years of Clathrin-coated Vesicles . Traffic . 16 . 12 . 1210–38 . December 2015 . 26403691 . 10.1111/tra.12335 . free .
  6. Robinson MS . Forty Years of Clathrin-coated Vesicles . Traffic . 16 . 12 . 1210–38 . December 2015 . 26403691 . 10.1111/tra.12335 . free .
  7. Fotin A, Kirchhausen T, Grigorieff N, Harrison SC, Walz T, Cheng Y . Structure determination of clathrin coats to subnanometer resolution by single particle cryo-electron microscopy . J Struct Biol . 156 . 3 . 453–60 . December 2006 . 16908193 . 2910098 . 10.1016/j.jsb.2006.07.001 .
  8. Web site: Clathrin and its interactions with AP180.. McMahon HT. MRC Laboratory of Molecular Biology. https://web.archive.org/web/20090501052207/http://endocytosis.org/AP180/Clathrin.html. 2009-05-01. micrographs of clathrin assembly. 2009-04-17. dead.
  9. Web site: Epsin 1 EM gallery. McMahon HT. MRC Laboratory of Molecular Biology. https://web.archive.org/web/20090102032308/http://www.endocytosis.org/epsin/EM/MonolayerEMs.html. 2009-01-02. micrographs of vesicle budding. 2009-04-17. dead.
  10. Ford MG, Pearse BM, Higgins MK, Vallis Y, Owen DJ, Gibson A, Hopkins CR, Evans PR, McMahon HT . Simultaneous binding of PtdIns(4,5)P2 and clathrin by AP180 in the nucleation of clathrin lattices on membranes . Science . 291 . 5506 . 1051–1055 . February 2001 . 11161218 . 10.1126/science.291.5506.1051 . dead . 2009-04-17 . Barbara Pearse . 10.1.1.407.6006 . 2001Sci...291.1051F . https://web.archive.org/web/20081121191304/http://www.endocytosis.org/epsin/EM/ford.pdf . 2008-11-21 .
  11. Higgins MK, McMahon HT . Snap-shots of clathrin-mediated endocytosis . Trends in Biochemical Sciences . 27 . 5 . 257–263 . May 2002 . 12076538 . 10.1016/S0968-0004(02)02089-3 . dead . 2009-04-17 . https://web.archive.org/web/20081121220307/http://www.endocytosis.org/epsin/EM/mcmahon.pdf . 2008-11-21 .
  12. Royle SJ, Bright NA, Lagnado L . Clathrin is required for the function of the mitotic spindle . Nature . 434 . 7037 . 1152–1157 . April 2005 . 15858577 . 3492753 . 10.1038/nature03502 . 2005Natur.434.1152R .
  13. Hood FE, Williams SJ, Burgess SG, Richards MW, Roth D, Straube A, Pfuhl M, Bayliss R, Royle SJ . Coordination of adjacent domains mediates TACC3-ch-TOG-clathrin assembly and mitotic spindle binding . The Journal of Cell Biology . 202 . 3 . 463–478 . August 2013 . 23918938 . 3734082 . 10.1083/jcb.201211127 .
  14. Prichard KL, O'Brien NS, Murcia SR, Baker JR, McCluskey A . Role of Clathrin and Dynamin in Clathrin Mediated Endocytosis/Synaptic Vesicle Recycling and Implications in Neurological Diseases . Frontiers in Cellular Neuroscience . 15 . 754110 . 2022-01-18 . 35115907 . 8805674 . 10.3389/fncel.2021.754110 . free .
  15. Role of the Clathrin Terminal Domain in Regulating Coated Pit Dynamics Revealed by Small Molecule Inhibition|Cell, Volume 146, Issue 3, 471–484, 5 August 2011 Abstract
  16. Dutta D, Williamson CD, Cole NB, Donaldson JG . Pitstop 2 is a potent inhibitor of clathrin-independent endocytosis . PLOS ONE . 7 . 9 . e45799 . Sep 2012 . 23029248 . 3448704 . 10.1371/journal.pone.0045799 . free . 2012PLoSO...745799D .
  17. Robertson MJ, Horatscheck A, Sauer S, von Kleist L, Baker JR, Stahlschmidt W, Nazaré M, Whiting A, Chau N, Robinson PJ, Haucke V, McCluskey A . 5-Aryl-2-(naphtha-1-yl)sulfonamido-thiazol-4(5H)-ones as clathrin inhibitors . Organic & Biomolecular Chemistry . 14 . 47 . 11266–11278 . November 2016 . 27853797 . 10.1039/C6OB02308H .