Adhesome

The term Adhesome was first used by Richard Hynes to describe the complement of cell-cell and cell-matrix adhesion receptors in an organism [1] and later expanded by Benny Geiger and co-workers to include the entire network of structural and signaling proteins involved in regulating cell-matrix adhesion.[2][3][4]

Receptors

The major cell-matrix adhesion receptors are integrins and therefore the adhesome of cell-matrix adhesion is referred to as the integrin adhesome.[4] Cell-cell adhesion is primarily mediated by cadherin receptors and therefore the adhesome of cell-cell adhesion is referred to as the cadherin adhesome or cadhesome.[5] The first attempts to establish the set of proteins that participate directly ('bona fide' adhesome components) or affect indirectly ('associated' adhesome components) cell adhesion were based on mining of the primary research literature, and resulted in approximately 200 protein in either integrin or cadherin adhesomes.[4][5][6] Later, unbiased proteomic approaches utilizing mass spectrometry have detected hundreds more proteins associated with integrin adhesions.[7][8][9] However, a comparison of multiple proteomic studies of the integrin adhesome of fibroblasts attached to fibronectin found only 60 proteins common to all studies.

Proteins

Humphries and co-workers named these 60 proteins the 'consensus integrin adhesome'.[10]

Investigation

Cell-matrix adhesions have been more extensively investigated by proteomics compared with cell-cell adhesions because they are more readily isolated from cells attached to glass.[11] The advent of proximity biotinylation by birA*[12] has facilitated the first proteomics-based studies of the cadherin adhesome.[13][14]

Criteria

While proteomic methods identified many novel proteins that potentially might be adhesome components they cannot be regarded as adhesome components until they are validated to fulfill the following criteria: 1. they localize to a cell adhesion structure such as focal adhesion or adherens junction. 2. they directly interact with one of the core adhesome components, such as integrin, cadherin or catenins AND/OR their knockdown has a clear effect on cell adhesion.

Mass spectrometry

Mass spectrometry has been successfully used to identify changes in the composition of the adhesome upon perturbation. Schiller et al. as well as Kuo et al. examined the effect of inhibition of myosin contractility on the integrin adhesome composition and found LIM domain proteins and beta-PIX to be tension sensitive.[8][9] Gou et al. found little change in the cadherin adhesome after calcium depletion from the media, which essentially abrogates cell-cell adhesion.[13] Reinhard Fassler and co-workers used proteomics on specifically engineered cell lines to distinguish between the adhesome of β1- and αv-class integrins.[15]

Multi domain proteins

The adhesome contains multi domain proteins with various functions, some of which are specifically enriched in the adhesome compared to the cell proteome.[16] Protein domains enriched in the adhesome include: Pleckstrin homology (PH) and FERM domains, which target proteins to the plasma membrane; Calponin homology (CH) domain, which is an F-actin binding motif; Src homology 2 (SH2) domain, which mediate interaction with phosphorylated tyrosine residues; armadillo (ARM) GUK and LIM domains, which mediate specific protein-protein binding.[16] The literature-based adhesome contains enzymes, such as protein tyrosine and serine/threonine kinases and phosphatases, guanine nucleotide exchange factors and GTPase activating proteins, E3-ligases and proteases, that regulate adhesion through post translational modification of the many structural and scaffolding proteins found in the adhesome.[3] The proteomic-based studies have identified many proteins from functional groups that haven't previously been associated with cell adhesion sites, such as proteins involved in RNA splicing, translation, trafficking, golgi, endoplasmic reticulum, and metabolic enzymes. Whether these proteins are indeed an integral part of the adhesome or an artifact of the proteomic methods remains to be seen.

Genomes

The availability of genomes of many organisms on the tree of life has opened up the possibility to study how the adhesome evolved from the unicellular relatives of animals through simple animals (e.g. sponges) to mammals.[17][18] Surprisingly, the majority of cadherin adhesome proteins existed long before multicellularity and had other functions in cells. Later, with the emergence of the cadherin-catenin-actin structure they were co-opted into the cadhesome.[18][19]

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References

  1. Whittaker, Charles A.; Bergeron, Karl-Frederik; Whittle, James; Brandhorst, Bruce P.; Burke, Robert D.; Hynes, Richard O. (December 2006). "The echinoderm adhesome". Developmental Biology. 300 (1): 252–266. doi:10.1016/j.ydbio.2006.07.044. PMC 3565218. PMID 16950242.
  2. Zaidel-Bar, Ronen; Itzkovitz, Shalev; Ma'ayan, Avi; Iyengar, Ravi; Geiger, Benjamin (2007). "Functional atlas of the integrin adhesome". Nature Cell Biology. 9 (8): 858–867. doi:10.1038/ncb0807-858. PMC 2735470. PMID 17671451.
  3. Zaidel-Bar, Ronen; Geiger, Benjamin (2010-05-01). "The switchable integrin adhesome". J Cell Sci. 123 (9): 1385–1388. doi:10.1242/jcs.066183. ISSN 0021-9533. PMC 2858016. PMID 20410370.
  4. Winograd-Katz, Sabina E.; Fässler, Reinhard; Geiger, Benjamin; Legate, Kyle R. (2014). "The integrin adhesome: from genes and proteins to human disease". Nature Reviews Molecular Cell Biology. 15 (4): 273–288. doi:10.1038/nrm3769. PMID 24651544.
  5. Zaidel-Bar, Ronen (2013-01-15). "Cadherin adhesome at a glance". J Cell Sci. 126 (2): 373–378. doi:10.1242/jcs.111559. ISSN 0021-9533. PMID 23547085.
  6. "Adhesome- Project Description". www.adhesome.org. Retrieved 2015-12-24.
  7. Byron, Adam; Humphries, Jonathan D.; Bass, Mark D.; Knight, David; Humphries, Martin J. (2011-04-05). "Proteomic Analysis of Integrin Adhesion Complexes". Sci. Signal. 4 (167): pt2. doi:10.1126/scisignal.2001827. ISSN 1945-0877. PMID 21467297.
  8. Schiller, Herbert B; Fässler, Reinhard (2013-06-01). "Mechanosensitivity and compositional dynamics of cell–matrix adhesions". EMBO Reports. 14 (6): 509–519. doi:10.1038/embor.2013.49. PMC 3674437. PMID 23681438.
  9. Kuo, Jean-Cheng; Han, Xuemei; Hsiao, Cheng-Te; III, John R. Yates; Waterman, Clare M. (2011). "Analysis of the myosin-II-responsive focal adhesion proteome reveals a role for β-Pix in negative regulation of focal adhesion maturation". Nature Cell Biology. 13 (4): 383–393. doi:10.1038/ncb2216. PMC 3279191. PMID 21423176.
  10. Horton, Edward R.; Byron, Adam; Askari, Janet A.; Ng, Daniel H. J.; Millon-Frémillon, Angélique; Robertson, Joseph; Koper, Ewa J.; Paul, Nikki R.; Warwood, Stacey (2015). "Definition of a consensus integrin adhesome and its dynamics during adhesion complex assembly and disassembly". Nature Cell Biology. 17 (12): 1577–1587. doi:10.1038/ncb3257. PMC 4663675. PMID 26479319.
  11. Kuo, J. C.; Han, X.; Yates Jr, 3rd; Waterman, C. M. (2012-01-01). Shimaoka, Motomu (ed.). Isolation of Focal Adhesion Proteins for Biochemical and Proteomic Analysis - Springer. Methods in Molecular Biology. 757. Humana Press. pp. 297–323. doi:10.1007/978-1-61779-166-6_19. ISBN 978-1-61779-165-9. PMC 4158431. PMID 21909920.
  12. Roux, Kyle J.; Kim, Dae In; Raida, Manfred; Burke, Brian (2012-03-19). "A promiscuous biotin ligase fusion protein identifies proximal and interacting proteins in mammalian cells". The Journal of Cell Biology. 196 (6): 801–810. doi:10.1083/jcb.201112098. ISSN 0021-9525. PMC 3308701. PMID 22412018.
  13. Guo, Zhenhuan; Neilson, Lisa J.; Zhong, Hang; Murray, Paul S.; Zanivan, Sara; Zaidel-Bar, Ronen (2014-12-02). "E-cadherin interactome complexity and robustness resolved by quantitative proteomics". Sci. Signal. 7 (354): rs7. doi:10.1126/scisignal.2005473. ISSN 1945-0877. PMC 4972397. PMID 25468996.
  14. Itallie, Christina M. Van; Tietgens, Amber Jean; Aponte, Angel; Fredriksson, Karin; Fanning, Alan S.; Gucek, Marjan; Anderson, James M. (2014-02-15). "Biotin ligase tagging identifies proteins proximal to E-cadherin, including lipoma preferred partner, a regulator of epithelial cell–cell and cell–substrate adhesion". J Cell Sci. 127 (4): 885–895. doi:10.1242/jcs.140475. ISSN 0021-9533. PMC 3924204. PMID 24338363.
  15. Schiller, Herbert B.; Hermann, Michaela-Rosemarie; Polleux, Julien; Vignaud, Timothée; Zanivan, Sara; Friedel, Caroline C.; Sun, Zhiqi; Raducanu, Aurelia; Gottschalk, Kay-E. (2013). "β1- and αv-class integrins cooperate to regulate myosin II during rigidity sensing of fibronectin-based microenvironments". Nature Cell Biology. 15 (6): 625–636. doi:10.1038/ncb2747. PMID 23708002.
  16. Systems Biomedicine: Concepts and Perspectives ed. E.T. Liu and D.A. Lauffenburger. Oxford: Academic Press. 2009. pp. 139–152.
  17. Zaidel-Bar, Ronen (2009-08-10). "Evolution of complexity in the integrin adhesome". The Journal of Cell Biology. 186 (3): 317–321. doi:10.1083/jcb.200811067. ISSN 0021-9525. PMC 2728394. PMID 19667126.
  18. Murray, Paul S.; Zaidel-Bar, Ronen (2014-12-15). "Pre-metazoan origins and evolution of the cadherin adhesome". Biology Open. 3 (12): 1183–1195. doi:10.1242/bio.20149761. ISSN 2046-6390. PMC 4265756. PMID 25395670.
  19. Padmanabhan, Anup; Rao, Megha Vaman; Wu, Yao; Zaidel-Bar, Ronen (2015). "Jack of all trades: functional modularity in the adherens junction". Current Opinion in Cell Biology. 36: 32–40. doi:10.1016/j.ceb.2015.06.008. PMID 26189061.
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