Cell Adhesion: a FERM Grasp of the Tail Sorts out Integrins

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Cell Adhesion: a FERM Grasp of the Tail Sorts out Integrins Current Biology Vol 22 No 17 R692 and how the cell integrates them with 5. Nott, A., Jung, H.S., Koussevitzky, S., and retrograde pathway that functions in drought Chory, J. (2006). Plastid-to-nucleus retrograde and high light signaling in Arabidopsis. Plant one another and other cell/organelle signaling. Annu. Rev. Plant Biol. 57, 739–759. Cell 23, 3992–4012. functions. Answering these questions 6. Koussevitzky, S., Nott, A., Mockler, T.C., 15. Grieshaber, N.A., Fischer, E.R., Mead, D.J., will likely be a challenge considering Hong, F., Sachetto-Martins, G., Surpin, M., Dooley, C.A., and Hackstadt, T. (2004). Lim, J., Mittler, R., and Chory, J. (2007). Chlamydial histone-DNA interactions are that many of the biosynthetic pathways Signals from chloroplasts converge to regulate disrupted by a metabolite in the involved are essential, which limits our nuclear gene expression. 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Rapid induction of distinct References 11. Leister, D. (2012). Retrograde signaling in stress responses after the release of singlet 1. Barbrook, A.C., Howe, C.J., and Purton, S. plants: from simple to complex scenarios. oxygen in Arabidopsis. Plant Cell 15, (2006). Why are plastid genomes retained in Front. Plant Sci. 3, 135. 2320–2332. non-photosynthetic organisms? Trends Plant 12. Xiao, Y., Savchenko, T., Baidoo, E.E., 19. Wagner, D., Przybyla, D., Op den Camp, R., Sci. 11, 101–108. Chehab, W.E., Hayden, D.M., Tolstikov, V., Kim, C., Landgraf, F., Lee, K.P., Wursch, M., 2. Martin, W., Rujan, T., Richly, E., Hansen, A., Corwin, J.A., Kliebenstein, D.J., Keasling, J.D., Laloi, C., Nater, M., Hideg, E., et al. (2004). The Cornelsen, S., Lins, T., Leister, D., Stoebe, B., and Dehesh, K. (2012). Retrograde signaling by genetic basis of singlet oxygen-induced stress Hasegawa, M., and Penny, D. (2002). the plastidial metabolite MEcPP regulates responses of Arabidopsis thaliana. Science Evolutionary analysis of Arabidopsis, expression of nuclear stress-response genes. 306, 1183–1185. cyanobacterial, and chloroplast genomes Cell 149, 1525–1535. reveals plastid phylogeny and thousands of 13. Wilson, P.B., Estavillo, G.M., Field, K.J., cyanobacterial genes in the nucleus. Proc. Natl. Pornsiriwong, W., Carroll, A.J., Howell, K.A., 1Plant Biology Laboratory, 2Howard Hughes Acad. Sci. USA 99, 12246–12251. Woo, N.S., Lake, J.A., Smith, S.M., Harvey Medical Institute, The Salk Institute, 3. Pogson, B.J., Woo, N.S., Forster, B., and Millar, A., et al. (2009). The nucleotidase/ Small, I.D. (2008). Plastid signalling to the phosphatase SAL1 is a negative regulator of 10010 North Torrey Pines Road, La Jolla, nucleus and beyond. Trends Plant Sci. 13, drought tolerance in Arabidopsis. Plant J. 58, CA 92037, USA. 602–609. 299–317. E-mail: [email protected], [email protected] 4. Woodson, J.D., and Chory, J. (2008). 14. Estavillo, G.M., Crisp, P.A., Pornsiriwong, W., Coordination of gene expression between Wirtz, M., Collinge, D., Carrie, C., Giraud, E., organellar and nuclear genomes. Nat. Rev. Whelan, J., David, P., Javot, H., et al. (2011). Genet. 9, 383–395. Evidence for a SAL1-PAP chloroplast http://dx.doi.org/10.1016/j.cub.2012.07.028 Cell Adhesion: A FERM Grasp of the from conformations with relatively low affinity for ECM ligands to those Tail Sorts Out Integrins with high affinity. This transition is controlled by the binding of the FERM (4.1, ezrin, radixin, moesin) As well as modulating integrin activation, a conserved NPxY motif in integrin domain from the protein talin to cytoplasmic tails that binds the FERM-domain-containing proteins kindlin a membrane-proximal NPxY motif and sorting nexin 17 plays pivotal roles in integrin recycling and degradation. in the short cytoplasmic tail of the integrin b subunit [4]. Nina N. Brahme migration, embryonic development, More recently, human disease and David A. Calderwood* tissue formation, vasculogenesis, mutations and knockout studies have inflammatory and immune responses, implicated a second family of The ability of metazoan cells to and wound healing [1]. Like other FERM-domain proteins, the kindlins, in sense and adhere to the insoluble cell-surface receptors, integrins integrin activation [5–7]. Kindlins bind extracellular matrix (ECM) that can be regulated by controlling to the b integrin cytoplasmic tail, surrounds them is central to cell-surface delivery, endocytosis, specifically to the membrane-distal multicellular life. Integrins, the major and subsequent recycling or NPxY motif and its preceding family of ECM adhesion receptors degradation. Indeed, the importance threonines (Figure 1), and kindlin responsible for this ability, are of integrin internalization and recycling deficiency leads to defects in integrin transmembrane ab heterodimers that in a range of cellular processes is activation and signaling. However, the link the ECM to intracellular increasingly well appreciated [2,3]. molecular basis for kindlin function is cytoskeletal and signaling networks. However, a unique and defining feature not understood. In this issue of Current Integrins are thus integral to a range of integrin regulation is integrin Biology, Margadant et al. [8] provide of essential processes, including cell activation — the allosteric transition new insights into the differential roles Dispatch R693 of talin and kindlin in b1 integrin Talin Kindlin A regulation and for the first time link 1A: KLLMIIHDRREFAKFEKEKMNAKWDTGENPIYKSAVTTVVNPKYEGK kindlins to the control of lysosomal Sorting nexin-17 degradation of integrins. Using alternative approaches, two other B Active Inactive recent papers [9,10] also reveal a role integrin integrin for the kindlin-binding NPxY motif in 1 determining whether integrins are 5 lysosomally degraded or are recycled to the cell surface. However, these investigators find that binding of the Talin FERM-domain-containing protein Kindlin sorting nexin 17 (SNX17) triggers recycling versus degradation. While many details remain to be elucidated, Early endosome and discrepancies resolved, taken together all three new papers suggest that the dynamics of FERM-domain binding to integrin NPxY motifs govern Recycling not only activation but also recycling endosome and degradation. Understanding how this occurs, if and how the processes SNX17 are linked, and how FERM-domain binding and competition are regulated will be the next challenges. Margadant et al. [8] investigated the Lysosome Current Biology roles of the talin- and kindlin-binding sites in b1 integrin activation and trafficking by reconstituting Figure 1. b-tail-binding proteins in integrin activation and sorting. embryoid-body-derived b1 (A) Amino acid sequence of the cytoplasmic tail of human b1 integrin. Regions important for integrin-null cells with wild-type b1or binding talin, kindlin and sorting nexin 17 (SNX17) are indicated, and key residues that were b mutated to disrupt these interactions are highlighted in red. (B) Model for regulation of integrin with 1 containing tyrosine to alanine activation and trafficking. Binding of talin and kindlin leads to integrin activation at the plasma mutations in the membrane-proximal membrane. Internalization leads to dissociation of talin and kindlin from integrin. SNX17 binds or membrane-distal NxxY motifs. integrins in early endosomes and, by an unknown mechanism, facilitates their recycling: integ- As expected, mutations in the rins unable to bind SNX17 are targeted for lysosomal degradation. Kindlin’s role in integrin talin-binding membrane-proximal trafficking remains controversial but kindlin and SNX17 can compete for binding to integrin NPxY motif result in defects in cell and they do not colocalize in the same subcellular compartment. Whether other tail-binding proteins regulate additional
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