Impact of Cortical Network Activity on Short-term Synaptic Depression

We used spike-triggered current source-density analysis to examine axonal and postsynaptic currents generated in the visual cortex of awake rabbits by spontaneous spikes of individual sustained and transient dorsal lateral geniculate nucleus (LGNd) neurons. Using these data, we asked whether sustained/transient sensory responses are related to short-term synaptic dynamics at the thalamocortical synapse. Most sustained (34 of 40) and transient (24 of 25) neurons generated axonal and monosynaptic responses in layer 4 and/or 6 of the aligned cortical domain, with input from transient neurons arriving ϳ0.3 ms earlier and 100 -200 m deeper. Postsynaptic cortical responses generated by both thalamic cell classes were reduced in amplitude after a preceding impulse and slowly recovered over a period of Ͼ750 ms. We interpret this to reflect interval-dependent recovery from chronic depression at the thalamocortical synapse, caused by significant spontaneous firing of LGNd cells (ϳ8 Hz). Surprisingly, postsynaptic cortical responses generated by spontaneous spikes of sustained thalamic neurons were more depressed than those of transient neurons. This difference was seen both in layers 4 and 6. The depression saturated rapidly with multiple preceding impulses, and postsynaptic responses generated by sustained neurons during maintained visual stimulation remained sufficiently robust to allow a sustained flow of information to the cortex. Our results indicate a relationship between the sensory response properties of thalamic neurons and the short-term dynamics of their synapses, and suggest that cortical recipients of sustained and transient thalamic inputs will differ considerably in their response modulation by prior impulse activity.

Section: Sustainedsupporting

confidence: 93%

The Impact of an LGNd Impulse on the Awake Visual Cortex: Synaptic Dynamics and the Sustained/Transient Distinction

Stoelzel¹,

Bereshpolova²,

Gusev³

et al. 2008

“…We address tonic depression as a final candidate. Most cells are silent in slices, but in vivo their spontaneous activity may induce tonic short-term synaptic depression (Boudreau and Ferster, 2005;Reig et al, 2006;Hermann et al, 2007;Wang et al, 2010). In slices, a fast recovery phase has been observed, which depends on calcium buildup within the endbulb (Wang and Manis, 2008;Yang and Xu-Friedman, 2008).…”

Section: Low Release Probability Of the Endbulb Of Held In Vivomentioning

confidence: 99%

Factors Controlling the Input–Output Relationship of Spherical Bushy Cells in the Gerbil Cochlear Nucleus

Kuenzel¹,

Borst²,

Heijden³

2011

141

Despite the presence of large endbulb inputs, the spherical bushy cells (SBCs) of the rostral anteroventral cochlear nucleus do not function as simple auditory relays. We used the good signal-to-noise ratio of juxtacellular recordings to dissect the intrinsic and network mechanisms controlling the input-output relationship of SBCs in anesthetized gerbils. The SBCs generally operated close to action potential (AP) threshold and showed no evidence for synaptic depression, suggesting that the endbulbs of Held have low release probability in vivo. Analysis of the complex waveforms suggested that in the absence of auditory stimulation, postsynaptic spike depression and stochastic fluctuations in EPSP size were the main factors determining jitter and reliability of the endbulb synapse. During auditory stimulation, progressively larger EPSPs were needed to trigger APs at increasing sound intensities. Simulations suggested hyperpolarizing inhibition could explain the observed decrease in EPSP efficacy. Synaptic inhibition showed a delayed onset and generally had a higher threshold than excitatory inputs, but otherwise inhibition and excitation showed mostly overlapping frequency-response areas. The recruitment of synaptic inhibition caused postsynaptic spikes to be preferentially triggered by well-timed, large EPSPs, resulting in improved phase locking despite more variable EPSP-AP latencies. Our results suggest that the lack of synaptic depression, caused by low release probability, and the apparent absence of sound-evoked synaptic inhibition at low sound intensity maximize sensitivity of SBCs. At higher sound intensities, the recruitment of synaptic inhibition constrains their firing rate and optimizes their temporal precision.

“…Network responsiveness after the cessation of an Up state may be reduced through use-dependent depression of recurrent cortical connections (Crochet et al, 2004;Crochet and Petersen, 2006;Reig et al, 2006), the buildup of a slow afterhyperpolarization (Sanchez-Vives and McCormick, 2000;McCormick et al, 2003;Shu et al, 2003a), reduction in synaptic potentials through activity-dependent decreases in extracellular [Ca 2ϩ ] (Crochet and Petersen, 2006), or the slow activation or inactivation of a voltage-dependent inhibitory conductance (Bal and McCormick, 1996;Compte et al, 2003). The disproportionately increased excitability of fast-spiking inhibitory interneurons during the Up state may also result in reduced recurrent network activity, by enhancing the inhibitory contribution to whisker-evoked responses and consequently reducing the ability of excitatory inputs to initiate action potentials.…”

Section: Mechanisms Of Cyclical Changes In Responsivenessmentioning

confidence: 99%

“…Increased corticothalamic feedback during the Up state may also shift the thalamus out of the burst firing mode, resulting in a decrease in the number or frequency of spikes initiated in thalamocortical neurons by the whisker movement (McCormick and von Krosigk, 1992;Weyand et al, 2001) [see, however, Haslinger et al, (2006)]. Finally, tonic activity during the Up state may reduce responses to brief whisker stimuli through synaptic depression at the thalamocortical synapse (Gil et al, 1997;Beierlein and Connors, 2002;CastroAlamancos and Oldford, 2002;Hirata and Castro-Alamancos, 2006;Reig et al, 2006).…”

Section: Mechanisms Of Cyclical Changes In Responsivenessmentioning

confidence: 99%

State Changes Rapidly Modulate Cortical Neuronal Responsiveness

Hasenstaub¹,

Sachdev²,

McCormick³

2007

188

183

The responsiveness of cortical neurons is strongly and rapidly influenced by changes in the level of local network activity. In rodent somatosensory cortex, increases in network activity increase neuronal responsiveness to the intracellular injection of brief conductance stimuli but paradoxically decrease responsiveness to brief whisker deflections. However, whisker stimulation frequently evokes longlasting changes in the level of local circuit activity. The ability of stimuli to successfully evoke prolonged increases in circuit activity is associated with both an increase in the amount of conductance evoked by a whisker stimulus and an increase in action potential responsiveness to whisker stimulation. In addition, brief whisker stimuli presented during periods of high network activity evoke postsynaptic potentials containing a greater proportion of inhibition, consistent with an increased efficiency in the activation of inhibitory mechanisms during the Up state. In contrast, during prolonged and variable whisker stimulation, increased network activity is associated with an increase in overall responsiveness, dynamic range, output gain, and correlation between action potential response and speed of whisker movement. We conclude that stimulus-evoked or spontaneous alterations in cortical state can influence neuronal responsiveness in a complex manner, resulting in large changes in which, and how, sensory stimuli are represented.