Oligomerization and nanocluster organization render specificity

Ruth Nussinov*, Hyunbum Jang, Chung Jung Tsai

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

41 Scopus citations

Abstract

Nanoclusters are anchored to membranes, either within them or in the cytoplasm latched onto the cytoskeleton, whose reorganization can regulate their activity. Nanoclusters have been viewed in terms of cooperativity and activation; here we perceive nanocluster organization from a conformational standpoint. This leads us to suggest that while single molecules encode activity, nanoclusters induce specificity, and that this is their main evolutionary aim. Distinct, isoform-specific nanocluster organization can drive the preferred effector (and ligand) interactions and thereby designate signalling pathways. The absence of detailed structural information across the nanocluster, due to size and dynamics, hinders an in-depth grasp of its mechanistic features; however, available data already capture some of the principles and their functional 'raison d'être'. Collectively, clustering lends stability and reduces the likelihood of proteolytic cleavage; it also increases the effective local concentration and enables efficient cooperative activation. However, clustering does not determine the ability of the single molecule to function. Drugs targeting nanoclusters can attenuate activity by hampering cooperativity; however, this may not perturb activation and signalling, which originate from the molecules themselves, and as such, are likely to endure. What then is the major role of nanoclustering? Assuming that single molecules evolved first, with a subsequent increase in cellular complexity and emergence of highly similar isoform variants, evolution faced the threat of signalling promiscuity. We reason that this potential risk was thwarted by oligomerization and clustering; clustering confers higher specificity, and a concomitant extra layer of cellular control. In our Ras example, signalling will be more accurate as a dimer than as a monomer, where its isomer specificity could be compromised.

Original languageEnglish
Pages (from-to)587-598
Number of pages12
JournalBiological Reviews
Volume90
Issue number2
DOIs
StatePublished - 1 May 2015

Funding

FundersFunder number
National Cancer Institute
National Institutes of HealthHHSN261200800001E
National Cancer InstituteZIABC010441

    Keywords

    • Allosteric
    • Allostery
    • Co-localization
    • Conformational states
    • Cytoskeleton
    • Microclusters
    • Nanoclusters
    • Oligomerization
    • Ras
    • Scaffolding
    • Signalling
    • Structure

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