Rapid structural alterations of the active zone lead to sustained changes in neurotransmitter release

Matz, Jacob; Gilyan, Andrew; Kolar, Annette; McCarvill, Terrence; Krueger, Stefan

doi:10.1073/pnas.0906087107

Cited by 144 publications

(138 citation statements)

References 37 publications

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“…It also corresponds well to the finding that prolonged depolarization leads to a reduction of both N and p vr (Moulder et al, 2004). Moreover, in a recent study, Matz et al (2010) used genetically expressed pHluorin to examine p syn in hippocampal cell cultures. They find that p syn changes spontaneously on a timescale of minutes.…”

Section: Discussionmentioning

confidence: 92%

“…However, rapid structural remodeling of synapses has been demonstrated previously. Another recent study at cultured hippocampal neurons found that the amount of fluorescently labeled Bassoon molecules at AZs changes on a timescale of minutes (Matz et al, 2010), suggesting a very dynamic structure of the cytomatrix. Furthermore, at postsynaptic densities, structural remodeling on the timescale of even milliseconds has been shown to influence paired-pulse ratios by diffusional exchange of desensitized and un-desensitized glutamate receptors (Heine et al, 2008).…”

Section: Discussionmentioning

confidence: 99%

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Rapid Active Zone Remodeling during Synaptic Plasticity

Weyhersmüller

Hallermann²,

Wagner³

et al. 2011

J. Neurosci.

169

226

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How can synapses change the amount of neurotransmitter released during synaptic plasticity? Although release in general is intensely investigated, its determinants during plasticity are still poorly understood. As a model for plastic strengthening of synaptic release, we here use the well-established presynaptic homeostatic compensation during interference with postsynaptic glutamate receptors at the Drosophila neuromuscular junction. Combining short-term plasticity analysis, cumulative EPSC analysis, fluctuation analysis, and quantal short-term plasticity modeling, we found an increase in the number of release-ready vesicles during presynaptic strengthening. High-resolution light microscopy revealed an increase in the amount of the active zone protein Bruchpilot and an enlargement of the presynaptic cytomatrix structure. Furthermore, these functional and structural alterations of the active zone were not only observed after lifelong but already after minutes of presynaptic strengthening. Our results demonstrate that presynaptic plasticity can induce active zone remodeling, which regulates the number of release-ready vesicles within minutes.

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Section: Discussionmentioning

confidence: 92%

Section: Discussionmentioning

confidence: 99%

Rapid Active Zone Remodeling during Synaptic Plasticity

Weyhersmüller

Hallermann²,

Wagner³

et al. 2011

J. Neurosci.

169

226

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“…Correlated bouton size changes might arise because boutons form contacts with postsynaptic cells displaying similar tuning properties (e.g., in the same cortical column), whereas spines along a dendrite likely make synapses with axons exhibiting different firing patterns. At the same time, fluctuations in EPB size could decrease the reliability of synaptic transmission (20), degrading the saliency of output signals. Long-term rather than short-term changes in synaptic weight may be at the basis of memory encoding (41).…”

Section: Increased Rates Of Change In Axonal Bouton Size and Cognitivementioning

confidence: 99%

“…Furthermore, because the size of the active zone correlates with the reliability of synaptic transmission (20), and synaptic vesicles are exchanged at high rates between neighboring EPBs along the axon in an activity-dependent manner (50), it is plausible that a combination of the aforementioned mechanisms could contribute to the increased rate of fluctuations in the size of Ag cortical EPBs (Fig. 5).…”

Section: Increased Rates Of Change In Axonal Bouton Size and Cognitivementioning

confidence: 99%

“…15) and behavioral training (13,16). Because the size of a synapse is directly related to its strength (17)(18)(19)(20), changes in the size of persistent synapses could play a significant role in mediating optimal cognitive function and experience-dependent plasticity alongside synapse formation, elimination, and stabilization (13,14,16,(21)(22)(23). However, little is known about structural changes of persistent synapses in the living brain.…”

mentioning

confidence: 99%

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Increased axonal bouton dynamics in the aging mouse cortex

Grillo

Song

Ruivo

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

114

100

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Aging is a major risk factor for many neurological diseases and is associated with mild cognitive decline. Previous studies suggest that aging is accompanied by reduced synapse number and synaptic plasticity in specific brain regions. However, most studies, to date, used either postmortem or ex vivo preparations and lacked key in vivo evidence. Thus, whether neuronal arbors and synaptic structures remain dynamic in the intact aged brain and whether specific synaptic deficits arise during aging remains unknown. Here we used in vivo two-photon imaging and a unique analysis method to rigorously measure and track the size and location of axonal boutons in aged mice. Unexpectedly, the aged cortex shows circuit-specific increased rates of axonal bouton formation, elimination, and destabilization. Compared with the young adult brain, large (i.e., strong) boutons show 10-fold higher rates of destabilization and 20-fold higher turnover in the aged cortex. Size fluctuations of persistent boutons, believed to encode long-term memories, also are larger in the aged brain, whereas bouton size and density are not affected. Our data uncover a striking and unexpected increase in axonal bouton dynamics in the aged cortex. The increased turnover and destabilization rates of large boutons indicate that learning and memory deficits in the aged brain arise not through an inability to form new synapses but rather through decreased synaptic tenacity. Overall our study suggests that increased synaptic structural dynamics in specific cortical circuits may be a mechanism for agerelated cognitive decline.neural circuits | ageing | structural plasticity | axon | in vivo imaging W hat are the cellular mechanisms that lead to age-related cognitive decline? There is significant evidence suggesting that synaptic impairment, rather than neuronal loss, may be the leading cause of cognitive deterioration (1-3). However, the mechanisms that underlie this synaptic impairment remain poorly understood.It is widely believed that learning deficits within the aging brain result from reduced synaptic density and plasticity (3). Most studies so far have focused on dendritic spines, the postsynaptic sites of excitatory synapses. Both the size and the number of dendritic spines are affected in pyramidal neurons of the aged (Ag) cortex and hippocampus (2-5). Interestingly, it is mainly thin spines, likely to be the main site of postsynaptic plasticity (6), that are reduced in numbers and display a larger spine head volume in cortical neurons of the Ag monkey (7) and in rat cortex (8). Much less is known about presynaptic deficits with aging. Synaptophysin (a synaptic vesicle component) labeling decreases (9), and treatments that rescue age-related cognitive decline lead to increased synaptophysin immunoreactivity and increased synaptic plasticity in the hippocampus (10). Overall these findings from different brain areas and species point to a reduction of the number, size, and plasticity of neuronal connections in the Ag brain. However, most studies to date h...

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Persistence of intact retinal ganglion cell terminals after axonal transport loss in the DBA/2J mouse model of glaucoma

Smith

Xia

Fening

et al. 2016

J of Comparative Neurology

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Axonal transport defects are an early pathology occurring within the retinofugal projection of the DBA/2J mouse model of glaucoma. Retinal ganglion cell (RGC) axons and terminals are detectable after transport is affected, yet little is known about the condition of these structures. We examined the ultrastructure of the glaucomatous superior colliculus (SC) using three-dimensional serial block-face scanning electron microscopy (3-D EM) to determine the distribution and morphology of retinal terminals in aged mice exhibiting varying levels of axonal transport integrity. After initial axonal transport failure, retinal terminal densities did not vary when compared to either transport-intact or control tissue. While retinal terminals lacked overt signs of neurodegeneration, transport-intact areas of glaucomatous SC exhibited larger retinal terminals and associated mitochondria. This likely indicates increased oxidative capacity and may be a compensatory response to the stressors this projection is experiencing. Areas devoid of transported tracer label showed reduced mitochondrial volumes as well as decreased active zone number and surface area, suggesting oxidative capacity and synapse strength are reduced as disease progresses, but before degeneration of the synapse. Mitochondrial volume was a strong predictor of bouton size independent of pathology. These findings indicate that RGC axons retain connectivity after losing function early in the disease process—creating an important therapeutic opportunity for protection or restoration of vision in glaucoma.

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Rapid structural alterations of the active zone lead to sustained changes in neurotransmitter release

Cited by 144 publications

References 37 publications

Rapid Active Zone Remodeling during Synaptic Plasticity

Rapid Active Zone Remodeling during Synaptic Plasticity

Increased axonal bouton dynamics in the aging mouse cortex

Persistence of intact retinal ganglion cell terminals after axonal transport loss in the DBA/2J mouse model of glaucoma

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