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Fuzzy complex

From Wikipedia, the free encyclopedia

NMR structure of the cyclin-dependent kinase inhibitor Sic1 with the ubiquitin ligase Cdc4 (grey). Out of the nine phosphorylation sites of Sic 1 (spheres) the contacts with T45 and S76 are shown (orange and blue).
The fuzzy linker region (shown by dotted line) of the Ultrabithorax transcription factor (orange) connects the homedomain with the Extradenticle homedomain (blue) (PDB code 1bi). Alternative splicing modulates the length of the fuzzy region and thus its DNA (grey) binding affinity. Other regulatory fuzzy regions of Ultrabithorax are also shown by dotted lines.

Fuzzy complexes are protein complexes, where structural ambiguity or multiplicity exists and is required for biological function.[1][2] Alteration, truncation or removal of conformationally ambiguous regions impacts the activity of the corresponding complex.[3][4][5] Fuzzy complexes are generally formed by intrinsically disordered proteins.[6][7] Structural multiplicity usually underlies functional multiplicity of protein complexes [8][9][10] following a fuzzy logic. Distinct binding modes of the nucleosome are also regarded as a special case of fuzziness.[11][12]

Historical background

For almost 50 years molecular biology was based on two dogmas: (i) equating biological function of the protein with a unique three-dimensional structure and (ii) assuming exquisite specificity in protein complexes. Specificity/selectivity is ensured by unambiguous set of interactions formed between the protein and its ligand (another protein, DNA, RNA or small molecule). Many protein complexes however, contain functionally important/critical regions, which remain highly dynamic in the complex or adopt different conformations.[13] This phenomenon is defined fuzziness. The most pertinent example is the cyclin-dependent kinase inhibitor Sic1, which binds to the SCF subunit of Cdc4 in a phosphorylation dependent manner.[14] No regular secondary structures are gained upon phosphorylation and the different phosphorylation sites interchange in the complex.[15]

Classification of fuzzy complexes

Structural ambiguity in protein complexes covers a wide spectrum.[1] In a polymorphic complex, the protein adopts two or more different conformations upon binding to the same partner, and these conformations can be resolved.[16] Clamp,[17] flanking [18][19] and random complexes[20][21] are dynamic, where ambiguous conformations interchange with each other and cannot be resolved. Interactions in fuzzy complexes are usually mediated by short motifs.[22] Flanking regions are tolerant to sequence changes as long as the amino acid composition is maintained, for example in case of linker histone C-terminal domains [23] and H4 histone N-terminal domains.[24]

Regulatory pathways via fuzzy regions

Fuzzy regions modulate the conformational equilibrium [25] or flexibility [3][26] of the binding interface via transient interactions.[27] Dynamic regions can also compete with binding sites[28] or tether them to the target.[29] Modifications of fuzzy regions by further interactions,[8][30] or posttranslational modifications[31][32] impact binding affinity or specificity. Alternative splicing can modulate the length of fuzzy regions resulting in context-dependent binding (e.g. tissue-specificity) on the complex.[33][34][35] EGF/MAPK, TGF-β and WNT/Wingless signaling pathways employ tissue-specific fuzzy regions.

References

  1. ^ a b Tompa, Peter; Fuxreiter, Monika (2008). "Fuzzy complexes: Polymorphism and structural disorder in protein–protein interactions". Trends in Biochemical Sciences. 33 (1): 2–8. doi:10.1016/j.tibs.2007.10.003. PMID 18054235.
  2. ^ Fuxreiter, M. & Tompa, P. (2011) Fuzziness: Structural Disorder in Protein Complexes Austin, New York.[page needed]
  3. ^ a b Pufall, M. A; Lee, Gregory M; Nelson, Mary L; Kang, Hyun-Seo; Velyvis, Algirdas; Kay, Lewis E; McIntosh, Lawrence P; Graves, Barbara J (2005). "Variable Control of Ets-1 DNA Binding by Multiple Phosphates in an Unstructured Region". Science. 309 (5731): 142–5. Bibcode:2005Sci...309..142P. doi:10.1126/science.1111915. PMID 15994560.
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  18. ^ Zor, Tsaffrir; Mayr, Bernhard M; Dyson, H. Jane; Montminy, Marc R; Wright, Peter E (2002). "Roles of Phosphorylation and Helix Propensity in the Binding of the KIX Domain of CREB-binding Protein by Constitutive (c-Myb) and Inducible (CREB) Activators". Journal of Biological Chemistry. 277 (44): 42241–8. doi:10.1074/jbc.M207361200. PMID 12196545.
  19. ^ Selenko, Philipp; Gregorovic, Goran; Sprangers, Remco; Stier, Gunter; Rhani, Zakaria; Krämer, Angela; Sattler, Michael (2003). "Structural Basis for the Molecular Recognition between Human Splicing Factors U2AF65 and SF1/mBBP". Molecular Cell. 11 (4): 965–76. doi:10.1016/S1097-2765(03)00115-1. PMID 12718882.
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  24. ^ McBryant, Steven J; Klonoski, Joshua; Sorensen, Troy C; Norskog, Sarah S; Williams, Sere; Resch, Michael G; Toombs, James A; Hobdey, Sarah E; Hansen, Jeffrey C (2009). "Determinants of Histone H4 N-terminal Domain Function during Nucleosomal Array Oligomerization". Journal of Biological Chemistry. 284 (25): 16716–22. doi:10.1074/jbc.M109.011288. PMC 2719306. PMID 19395382.
  25. ^ Naud, Jean-François; McDuff, François-Olivier; Sauvé, Simon; Montagne, Martin; Webb, Bradley A; Smith, Steven P; Chabot, Benoit; Lavigne, Pierre (2005). "Structural and Thermodynamical Characterization of the Complete p21 Gene Product of Max". Biochemistry. 44 (38): 12746–58. doi:10.1021/bi0500729. PMID 16171389.
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This page was last edited on 8 November 2023, at 16:28
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