During vision, it is believed that neural activity in the primary visual cortex is predominantly driven by sensory input from the environment. However, visual cortical neurons respond to repeated presentations of the same stimulus with a high degree of variability. Although this variability has been considered to be noise owing to random spontaneous activity within the cortex, recent studies show that spontaneous activity has a highly coherent spatio-temporal structure. This raises the possibility that the pattern of this spontaneous activity may shape neural responses during natural viewing conditions to a larger extent than previously thought. Here, we examine the relationship between spontaneous activity and the response of primary visual cortical neurons to dynamic natural-scene and random-noise film images in awake, freely viewing ferrets from the time of eye opening to maturity. The correspondence between evoked neural activity and the structure of the input signal was weak in young animals, but systematically improved with age. This improvement was linked to a shift in the dynamics of spontaneous activity. At all ages including the mature animal, correlations in spontaneous neural firing were only slightly modified by visual stimulation, irrespective of the sensory input. These results suggest that in both the developing and mature visual cortex, sensory evoked neural activity represents the modulation and triggering of ongoing circuit dynamics by input signals, rather than directly reflecting the structure of the input signal itself.
GABAergic inhibition plays a critical role in shaping neuronal activity in the neocortex. Numerous experimental investigations have examined perisomatic inhibitory synapses, which control action potential output from pyramidal neurons. However, most inhibitory synapses in the neocortex are formed onto pyramidal cell dendrites, where theoretical studies suggest they may focally regulate cellular activity. The precision of GABAergic control over dendritic electrical and biochemical signaling is unknown. Using cell type-specific optical stimulation in combination with 2-photon calcium (Ca(2+)) imaging, we show that somatostatin-expressing interneurons exert compartmentalized control over postsynaptic Ca(2+) signals within individual dendritic spines. This highly focal inhibitory action is mediated by a subset of GABAergic synapses that directly target spine heads. GABAergic inhibition thus participates in localized control of dendritic electrical and biochemical signaling.
The transient receptor potential TRPV1 is a nonselective cation channel that mediates pain sensations and is commonly activated by a wide variety of exogenous and endogenous, physical and chemical stimuli. While TRPV1 receptors are mainly found in nociceptive neurons of the peripheral nervous system, these receptors have also been described in the brain where their role is far less understood. Activation of TRPV1 reportedly regulates neurotransmitter release at several central synapses. Here we show, however, that TRPV1 suppresses excitatory transmission in rat and mouse dentate gyrus by regulating postsynaptic function in an input-specific manner. This suppression is due to a Ca2+-calcineurin and clathrin-dependent internalization of AMPA receptors. Moreover, synaptic activation of TRPV1 triggers a form of long-term depression (TRPV1-LTD) mediated by the endocannabinoid anandamide in a type 1 cannabinoid receptor-independent manner. Thus, our findings reveal a novel form of endocannabinoid- and TRPV1-mediated regulation of synaptic strength at central synapses.
We have synthesized a 7-diethylaminocoumarin (DEAC) derivative that allows wavelength selective, two-photon uncaging at 900 nm versus 720 nm. This new caging chromophore, called DEAC450, has an extended π-electron moeity at the 3-position that shifts the absorption spectrum maximum of DEAC from 375 nm to 450 nm. Two-photon excitation at 900 nm was more than 60-fold greater than at 720 nm. Two-photon uncaging of DEAC450-Glu at 900 nm at spine heads on pyramidal neurons in acutely isolated brain slices generated postsynaptic responses that were similar to spontaneous postsynaptic excitatory miniature currents, whereas significantly higher energies at 720 nm evoked no currents. Since many nitroaromatic caged compounds are two-photon active at 720 nm, optically selective uncaging of DEAC450-caged biomolecules at 900 nm may allow facile two-color optical interrogation of bimodal signaling pathways in living tissue with high resolution for the first time.
Experience-dependent modifications of neural circuits and function are believed to heavily depend on changes in synaptic efficacy such as LTP/LTD. Hence, much effort has been devoted to elucidating the mechanisms underlying these forms of synaptic plasticity. While most of this work has focused on excitatory synapses, it is now clear that diverse mechanisms of long-term inhibitory plasticity have evolved to provide additional flexibility to neural circuits. By changing the excitatory/inhibitory balance, GABAergic plasticity can regulate excitability, neural circuit function and ultimately, contribute to learning and memory, and neural circuit refinement. Here we discuss recent advancements in our understanding of the mechanisms and functional relevance of GABAergic inhibitory synaptic plasticity.
Multi-electrode extracellular recordings in area 17 of awake behaving ferrets were conducted to characterize the pattern of spontaneous activity in the developing visual cortex before eye opening. A linear array of 16 microwire electrodes was used to record extracellular neuronal activity across a 3.2 mm strip of visual cortex between postnatal days 22 and 28. Whereas synchronous bursts of activity were observed at all recording sites, cross-correlation analysis revealed that the timing of spike activity at all electrodes was not precisely correlated. Correlated activity between cortical sites exhibited a patchy organization having long-range components. Long-range correlated activity was observed between cortical patches that were separated by a mean distance of 1 mm. The spatial pattern of correlated activity persisted during transient lateral geniculate nucleus (LGN) activity block, indicating that long-range correlated activity is generated by intrinsic circuits within the cortex, independent of LGN input activity. These results demonstrate an innate patchy organization of correlated spontaneous activity within the cortex during the early development of cortical functional and anatomical organization.
Preservation of a balance between synaptic excitation and inhibition is critical for normal brain function. A number of homeostatic cellular mechanisms have been suggested to play a role in maintaining this balance, including long-term plasticity of GABAergic inhibitory synapses. Many previous studies have demonstrated a coupling of postsynaptic spiking with modification of perisomatic inhibition. Here, we demonstrate that activation of NMDA-type glutamate receptors leads to input-specific long-term potentiation of dendritic inhibition mediated by somatostatin-expressing interneurons. This form of plasticity is expressed postsynaptically and requires both CaMKIIα and the β2 subunit of the GABA-A receptor. Importantly, this process may function to preserve dendritic inhibition, as genetic deletion of NMDAR signaling results in a selective weakening of dendritic inhibition. Overall, our results reveal a new mechanism for linking excitatory and inhibitory input in neuronal dendrites and provide novel insight into the homeostatic regulation of synaptic transmission in cortical circuits.
At a synapse, presynaptic terminals form a specialized area of the plasma membrane called the active zone that mediates neurotransmitter release. RIM1␣ is a multidomain protein that constitutes a central component of the active zone by binding to other active zone proteins such as Munc13 s, ␣-liprins, and ELKS, and to synaptic vesicle proteins such as Rab3 and synaptotagmin-1. In mice, knockout of RIM1␣ significantly impairs synaptic vesicle priming and presynaptic long-term plasticity, but is not lethal. We now find that the RIM1 gene encodes a second, previously unknown RIM1 isoform called RIM1 that is upregulated in RIM1␣ knock-out mice. RIM1 is identical to RIM1␣ except for the N terminus where RIM1 lacks the N-terminal Rab3-binding sequence of RIM1␣. Using newly generated knock-out mice lacking both RIM1␣ and RIM1, we demonstrate that different from the deletion of only RIM1␣, deletion of both RIM1␣ and RIM1 severely impairs mouse survival. Electrophysiological analyses show that the RIM1␣ deletion abolishes long-term presynaptic plasticity, as does RIM1␣ deletion alone. In contrast, the impairment in synaptic strength and short-term synaptic plasticity that is caused by the RIM1␣ deletion is aggravated by the deletion of both RIM1␣ and RIM1. Thus, our data indicate that the RIM1 gene encodes two different isoforms that perform overlapping but distinct functions in neurotransmitter release.
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