Multiple Modes of Network Homeostasis in Visual Cortical Layer 2/3

TTX increases, whereas LS decreases, the E/I balance. A , Examples of spontaneous excitatory and inhibitory synaptic currents from layer 2/3 pyramidal neurons in control, LS, and TTX conditions; neurons were held sequentially at the E _rev for GABA_A currents (−45 mV) to isolate spontaneous excitatory currents and AMPA–NMDA (+10 mV) to isolate spontaneous inhibitory currents. B , Average excitatory and inhibitory synaptic charge in control (black), LS (white), and TTX (gray) conditions. C , Average excitation (Exc)/inhibition (Inh) ratio (computed for individual neurons and then averaged for each condition) for control (black), LS (white), and TTX (gray) conditions. *Significantly different from control.

TTX increases, whereas LS decreases, mEPSC amplitude. A , Example traces showing raw mEPSC recordings (top) and average mEPSCs (bottom) for control (black), LS (dark gray), and TTX (light gray) conditions. B , Scaled average mEPSCs for each condition; control scaled to peak of LS (top) and to peak of TTX (bottom). Note similar kinetics in each condition. C , Average mEPSC amplitude (Amp) and frequency (Freq), computed for each neuron and then averaged for each condition. Data are presented as percentage of control. Black bar, Control; white bar, LS; gray bar, TTX. D , Cumulative distribution of mEPSC amplitudes in control (black), LS (dark gray), and TTX (light gray). E , Cumulative distributions of intereven intervals (IEI) between mEPSC for control (black), LS (dark gray), and TTX (light gray) conditions. For cumulative histograms, 50 events/neuron were included. *Significantly different from control.

Both TTX and LS depressed the amplitude of recurrent monosynaptic connections between layer 2/3 pyramidal neurons. A , Examples of evoked recurrent EPSCs in response to the firing of presynaptic neurons at 20 Hz in control, LS, and TTX conditions. B , Average EPSC amplitude (Amp; in picoamperes), paired-pulse ratio (PP ratio), CV, and failure rates (% failures) for control (black bar), LS (white bar), and TTX (gray bar) conditions. *Significantly different from control.

The effects of visual deprivation on evoked minimal synaptic transmission onto layer 2/3 pyramidal neurons from lower layers. A , Diagram of the experimental setup, showing the laminar and lateral positions of the whole-cell recording (RE) and the bipolar stimulating electrode (SE), and a morphological reconstruction of a layer 2/3 pyramidal neuron. B , Example EPSC and IPSC amplitude versus stimulus intensity (stim int) plots. The arrows indicate the minimal EPSC and IPSC for this neuron. C , Example minimal evoked EPSCs (−45 mV) and IPSCs (+10 mV) from control, LS, and TTX conditions. Each plot shows 10 responses for each condition (gray traces). The average of 30 events for each condition is overlaid in black. D , Average amplitudes (EPSC), paired-pulse ratio (PP ratio), and CV of minimal EPSC for control (black bar), LS (white bar), and TTX (gray bar) conditions. The same color code will be used also for the plots in E and F . E , Average amplitude (IPSC), PP ratio, and CV of minimal IPSC for each condition. F , Average EPSC/IPSC ratio (computed for each neuron and then averaged for each condition). *Significantly different from control.

Plasticity of intrinsic excitability. A , Example firing in response to DC depolarizing current steps for control, LS, and TTX conditions. For each neuron, the response to the same three current injection amplitudes are shown from low (black) to middle (dark gray) to high (light gray). B , Frequency versus current curves for control (black circles), LS (white circles), and TTX (gray circles) conditions. Asterisks highlight significant differences. C , Summary plots for action potential threshold (AP thr), resting membrane potential (V _m), resting input resistance (R _in), and membrane time constant (tau) for control (black bar), LS (white bar), and TTX (gray bar). Data are mean ± SEM. *Different from control.