Abstract
Positive feedback plays a key role in the ability of signaling molecules to form highly localized clusters in the membrane or cytosol of cells. Such clustering can occur in the absence of localizing mechanisms such as pre-existing spatial cues, diffusional barriers, or molecular cross-linking. What prevents positive feedback from amplifying inevitable biological noise when an un-clustered “off” state is desired? And, what limits the spread of clusters when an “on” state is desired? Here, we show that a minimal positive feedback circuit provides the general principle for both suppressing and amplifying noise: below a critical density of signaling molecules, clustering switches off; above this threshold, highly localized clusters are recurrently generated. Clustering occurs only in the stochastic regime, suggesting that finite sizes of molecular populations cannot be ignored in signal transduction networks. The emergence of a dominant cluster for finite numbers of molecules is partly a phenomenon of random sampling, analogous to the fixation or loss of neutral mutations in finite populations. We refer to our model as the “neutral drift polarity model.” Regulating the density of signaling molecules provides a simple mechanism for a positive feedback circuit to robustly switch between clustered and un-clustered states. The intrinsic ability of positive feedback both to create and suppress clustering is a general mechanism that could operate within diverse biological networks to create dynamic spatial organization.
Highlights
The formation of local, high density regions of signaling molecules can switch cellular pathways between ‘‘off’’ and ‘‘on’’ states and direct downstream processes [1]
Additional mechanisms may be combined with positive feedback for regulating pattern formation, including coupled inhibitors [9], long-range negative feedback [10], tight regulation of input noise [11], or sequestration of components required for positive feedback [12]
What prevents positive feedback from amplifying inevitable biological noise when an un-clustered ‘‘off’’ state is desired? And, what limits the spread of clusters when an ‘‘on’’ state is desired? In theory many additional mechanisms could be postulated
Summary
The formation of local, high density regions of signaling molecules (referred to below as ‘‘clusters’’) can switch cellular pathways between ‘‘off’’ and ‘‘on’’ states and direct downstream processes [1]. This transition may require careful regulation, when an ‘‘on’’ state initiates large-scale cellular changes, such as observed in migration, cell division, or immune responses [2,3,4,5,6]. Positive feedback can amplify and reinforce spatially asymmetric distributions of signaling molecules in single cells This amplification, is indiscriminate; stochastic fluctuations could cause switches between ‘‘off’’ and ‘‘on’’ states to occur at undesired times, and sites of activation to occur in undesired locations [7,8]. Additional mechanisms may be combined with positive feedback for regulating pattern formation, including coupled inhibitors [9], long-range negative feedback [10], tight regulation of input noise [11], or sequestration of components required for positive feedback [12]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
