Regulation of synaptic stability by AMPA receptor reverse signaling

Ripley, Beth; Otto, Stefanie; Tiglio, Katie; Williams, Megan E.; Ghosh, Anirvan

doi:10.1073/pnas.1015163108

Cited by 39 publications

(36 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Postsynaptic Ca 2þ is, in turn, necessary for LTF, perhaps through retrograde signaling to presynaptic ApCAM, neurexin, or Trk receptors (Purcell et al 2003;Ormond et al 2004;Sharma et al 2006;Cai et al 2008;Hu et al 2010;Choi et al 2011;Kassabov et al 2013). The new postsynaptic clusters of AMPA-like receptors may also participate in retrograde signaling, and recruit presynaptic clusters of synaptophysin during a later stage of ITF and growth of presynaptic varicosities during LTF (Kim et al 2003;Ripley et al 2011;Lee et al 2012). These ideas are similar to theoretical "cascade" models of memory storage that can show plasticity as well as long-term stability (Fusi et al 2005), which would seem to be mutually exclusive but are both essential features of memory.…”

Section: Possible Relationships Between Mechanisms Contributing To Stmentioning

confidence: 55%

Nonassociative Learning in Invertebrates

Byrne¹,

Hawkins

2015

Cold Spring Harb Perspect Biol

View full text Add to dashboard Cite

The simplicity and tractability of the neural circuits mediating behaviors in invertebrates have facilitated the cellular/molecular dissection of neural mechanisms underlying learning. The review has a particular focus on the general principles that have emerged from analyses of an example of nonassociative learning, sensitization in the marine mollusk Aplysia. Learning and memory rely on multiple mechanisms of plasticity at multiple sites of the neuronal circuits, with the relative contribution to memory of the different sites varying as a function of the extent of training and time after training. The same intracellular signaling cascades that induce short-term modifications in synaptic transmission can also be used to induce longterm changes. Although short-term memory relies on covalent modifications of preexisting proteins, long-term memory also requires regulated gene transcription and translation. Maintenance of long-term cellular memory involves both intracellular and extracellular feedback loops, which sustain the regulation of gene expression and the modification of targeted molecules.

show abstract

Section: Possible Relationships Between Mechanisms Contributing To Stmentioning

confidence: 55%

Nonassociative Learning in Invertebrates

Byrne¹,

Hawkins

2015

Cold Spring Harb Perspect Biol

View full text Add to dashboard Cite

show abstract

“…Finally, one important mechanism through which synapse stability could be improved is by changes in the organization of the postsynaptic density (PSD) that promote trans-synaptic adhesion and contact. Expression of PSD95 and/or AMPA receptors enhances synaptic strength and synapse stability 28,29 . Several adhesion molecule systems have also been linked to spine stability, including neuroligin 1 (REFS 29,30) and N-cadherin.…”

Section: Spine Dynamicsmentioning

confidence: 99%

Structural plasticity upon learning: regulation and functions

2012

View full text Add to dashboard Cite

The contributions of brain networks to information processing and learning and memory are classically interpreted within the framework of Hebbian plasticity and the notion that synaptic weights can be modified by specific patterns of activity. However, accumulating evidence over the past decade indicates that synaptic networks are also structurally plastic, and that connectivity is remodelled throughout life, through mechanisms of synapse formation, stabilization and elimination 1. This has led to the concept of structural plasticity, which can encompass a variety of morphological changes that have functional consequences. These include on the one hand structural rearrangements at pre-existing synapses, and on the other hand the formation or loss of synapses, of neuronal processes that form synapses or of neurons. In this Review we focus on plasticity that involves gains and/or losses of synapses. Its key potential implication for learning and memory is to physically alter circuit connectivity, thus providing long-lasting memory traces that can be recruited at subsequent retrieval. Detecting this form of plasticity and relating it to its possible functions poses unique challenges, which are in part due to our still limited understanding of how structure relates to function in the nervous system.We review recent studies that relate the structural plasticity of neuronal circuits to behavioural learning and memory and discuss conceptual and mechanistic advances, as well as future challenges. The studies establish a number of strong links between specific behavioural learning processes and the assembly and loss of specific synapses. Further areas of substantial progress include molecular and cellular mechanisms that regulate synapse dynamics in response to alterations in synaptic activity, the specific spatial distribution of the syn aptic changes among identified neurons and dendrites and the relative roles of excitation and inhibition in regulating structural plasticity.The new findings provide exciting early vistas of how learning and memory may be implemented at the level of structural circuit plasticity. At the same time, they highlight major gaps in our understanding of plasticity regulation at the cellular, circuit and systems levels. Accordingly, achieving a better mechanistic understanding of learning and memory processes is likely to depend on the development of more effective techniques and models to investigate ensembles of identified synapses longitudinally, both functionally and structurally. Molecular mechanisms of synapse remodellingA remarkable feature of excitatory and inhibitory synapses is their high level of structural variability 2 and the fact that their morphologies and stabilities change over time 3 . This phenomenon is regulated by activity, and the size of spine heads correlates with synaptic strength 4 , presynaptic properties 5 and the long-term stability of the synapse 6 . The morphological characteristics of synapses thus reveal important features of their function and stabilit...

show abstract

“…The observation that the amount of GluR1 does not correlate with presynaptic strength, whereas the amount of NMDA receptors and PSD-95 does, suggests that not all postsynaptic proteins are affected by retrograde signaling that matches preand postsynaptic properties. Recent studies showed that the amount of AMPA receptors does not correlate with presynaptic strength with baseline activity (Tokuoka and Goda 2008), and AMPA receptor subunits retrogradely stabilize presynaptic terminals when neuroligin-1 is present (Ripley et al 2010). Our work suggests that the amount of two postsynaptic proteins, NMDA receptors and PSD-95, is an indirect indicator of presynaptic strength, regardless of the spatial configuration or the identity of postsynaptic neuron targets.…”

Section: Discussionmentioning

confidence: 74%

Determinants of synaptic strength vary across an axon arbor

Peng

Parsons

Balice-Gordon

2012

Journal of Neurophysiology

View full text Add to dashboard Cite

Peng X, Parsons TD, Balice-Gordon RJ. Determinants of synaptic strength vary across an axon arbor. J Neurophysiol 107: 2430-2441, 2012. First published January 25, 2012 doi:10.1152/jn.00615.2011.-We used synaptophysin-pHluorin expressed in hippocampal neurons to address how functional properties of terminals, namely, evoked release, total vesicle pool size, and release fraction, vary spatially across individual axon arbors. Consistent with previous reports, over short arbor distances (ϳ100 m), evoked release was spatially heterogeneous when terminals contacted different postsynaptic dendrites or neurons. Regardless of the postsynaptic configuration, the evoked release and total vesicle pool size spatially covaried, suggesting that the fraction of synaptic vesicles available for release (release fraction) was similar over short distances. Evoked release and total vesicle pool size were highly correlated with the amount of NMDA receptors and PSD-95 in postsynaptic specialization. However, when individual axons were followed over longer distances (several hundred micrometers), a significant increase in evoked release was observed distally that was associated with an increased release fraction in distal terminals. The increase in distal release fraction can be accounted for by changes in individual vesicle release probability as well as readily releasable pool size. Our results suggest that for a single axon arbor, presynaptic strength indicated by evoked release over short distances is correlated with heterogeneity in total vesicle pool size, whereas over longer distances presynaptic strength is correlated with the spatial modulation of release fraction. Thus the mechanisms that determine synaptic strength differ depending on spatial scale. synaptic vesicle; release properties; vesicle pool; hippocampus; presynaptic THE ABILITY OF HIPPOCAMPAL NEURONS to differentially regulate presynaptic strength at terminals located along the same axonal branch is thought to underlie reliable neurotransmission in the presence of highly variable stimuli. Several studies have documented the heterogeneous functional properties among presynaptic terminals of initial release probability (Hessler et al. 1993;Huang and Stevens 1997;Murthy et al. 1997;Rosenmund et al. 1993), short-term plasticity (Dobrunz and Stevens 1997), and heterogeneous cellular determinants such as the active zone area, numbers of docked vesicles, and total vesicles (Schikorski and Stevens 1997). Heterogeneity can be quantified by measurement of coefficients of variation (Murthy et al. 1997) or normalized differences in these properties between any pair of presynaptic terminals (Branco et al. 2008). However, previous studies mainly focused on assessing the functional properties of a small number of terminals without much spatial information or those in short axon segments (Hessler et al. 1993;Huang and Stevens 1997;Koester and Johnston 2005;Murthy et al. 1997;Rosenmund et al. 1993 Here we address two specific questions: what is the spatial distribution of presynap...

show abstract

Regulation of synaptic stability by AMPA receptor reverse signaling

Cited by 39 publications

References 43 publications

Nonassociative Learning in Invertebrates

Nonassociative Learning in Invertebrates

Structural plasticity upon learning: regulation and functions

Determinants of synaptic strength vary across an axon arbor

Contact Info

Product

Resources

About