Sound-level coding in the auditory nerve is achieved through the progressive recruitment of auditory nerve fibers (ANFs) that differ in threshold of activation and in the stimulus level at which the spike rate saturates. To investigate the functional state of the ANFs, the electrophysiological tests routinely used in clinics only capture the first action potentials firing in synchrony at the onset of the acoustic stimulation. Assessment of other properties (e.g., spontaneous rate and adaptation time constants) requires single-fiber recordings directly from the nerve, which for ethical reasons is not allowed in humans. By combining neuronal activity measurements at the round window and signal-processing algorithms, we constructed a peristimulus time response (PSTR), with a waveform similar to the peristimulus time histograms (PSTHs) derived from single-fiber recordings in young adult female gerbils. Simultaneous recordings of round-window PSTR and single-fiber PSTH provided models to predict the adaptation ...

Our brains continuously track the temporal structure of incoming information to anticipate upcoming events ([Haegens and Zion Golumbic, 2018][1]). Temporal expectations allow us to efficiently distribute attention over time ([Haegens and Zion Golumbic, 2018][1]), and they play an important role in

Current methods to isolate synaptic vesicles (SVs), the organellar quanta of synaptic transmission, require highly specialized materials and up to 24 hours. These technical obstacles have thus far limited the study of SVs in models of synaptic function and pathophysiology. Here, we describe techniques for the rapid isolation of SVs by immunoprecipitation with widely available antibodies conjugated to magnetic beads. We report that the inexpensive rho1D4 monoclonal antibody binds SVs and show that elution with the 1D4 peptide yields native vesicles that are ≥ 10-fold purer than those obtained with classical techniques. These methods substantially widen the accessibility of SVs, enabling their purification in 60-90 minutes for downstream analyses including mass spectrometry and cryo-electron microscopy. Immunopurified SV preparations from mouse brain contained apolipoprotein E (ApoE), the low-density lipoprotein (LDL) receptor Lrp1, and enzymes involved in lipid metabolism, suggesting that SVs may play direc...

Brain function depends on segregation and integration of information processing in brain networks often separated by long-range anatomic connections. Neuronal oscillations orchestrate such distributed processing through transient amplitude and phase coupling, yet surprisingly, little is known about local network properties facilitating these functional connections. Here, we test whether criticality, a dynamical state characterized by scale-free oscillations, optimizes the capacity of neuronal networks to couple through amplitude or phase, and transfer information. We coupled in silico networks which exhibit oscillations in the α band (8–16 Hz), and varied excitatory and inhibitory connectivity. We found that phase coupling of oscillations emerges at criticality, and that amplitude coupling, as well as information transfer, are maximal when networks are critical. Importantly, regulating criticality through modulation of synaptic gain showed that critical dynamics, as opposed to a static ratio of excitatory ...

During neuronal migration, forces generated by cytoplasmic dynein yank on microtubules extending from the centrosome into the leading process and move the nucleus along microtubules that extend behind the centrosome. Scaffolds, such as radial glia, guide neuronal migration outward from the ventricles, but little is known about the internal machinery that ensures that the soma migrates along its proper path rather than moving backward or off the path. Here we report that depletion of KIFC1, a minus-end-directed kinesin called HSET in humans, causes neurons to migrate off their appropriate path, suggesting that this molecular motor is what ensures fidelity of the trajectory of migration. For these studies, we used rat migratory neurons in vitro and developing mouse brain in vivo , together with RNA interference and ectopic expression of mutant forms of KIFC1. We found that crosslinking of microtubules into a nonsliding mode by KIFC1 is necessary for dynein-driven forces to achieve sufficient traction to thru...

The high sensitivity of night vision requires that rod photoreceptors reliably and reproducibly signal the absorption of single photons, a process that depends on tight regulation of intracellular cGMP concentration through the phototransduction cascade. Here in the mouse (Mus musculus), we studied a single-site D167A mutation of the gene for the α subunit of rod photoreceptor phosphodiesterase (PDEA), made with the aim of removing a noncatalytic binding site for cGMP. This mutation unexpectedly eliminated nearly all PDEA expression and reduced expression of the β subunit (PDEB) to ∼5%-10% of WT. The remaining PDE had nearly normal specific activity; degeneration was slow, with 50%-60% of rods remaining after 6 months. Responses were larger and more sensitive than normal but slower in rise and decay, probably from slower dark turnover of cGMP. Remarkably, responses became much less reproducible than WT, with response variance increasing for amplitude by over 10-fold, and for latency and time-to-peak by >10...

Hemalatha Muralidharan, Shrobona Guha, Kiran Madugula, Ankita Patil, Sarah A. Bennison, et al. (see pages [2149–2165][1]) The first cells of the developing nervous system are radial glial cells, the progenitors of neurons and astrocytes. These elongated cells contact both the ventricular (apical

Individuals with chronic pain often experience depression, resulting in greater disability and a worse prognosis than either condition alone ([Goesling et al., 2013][1]). The prevalence of depression among individuals experiencing neuropathic pain, one type of chronic pain caused by injury of the

During multisensory speech perception, slow δ oscillations (∼1–3 Hz) in the listener's brain synchronize with the speech signal, likely engaging in speech signal decomposition. Notable fluctuations in the speech amplitude envelope, resounding speaker prosody, temporally align with articulatory and body gestures and both provide complementary sensations that temporally structure speech. Further, δ oscillations in the left motor cortex seem to align with speech and musical beats, suggesting their possible role in the temporal structuring of (quasi)-rhythmic stimulation. We extended the role of δ oscillations to audiovisual asynchrony detection as a test case of the temporal analysis of multisensory prosody fluctuations in speech. We recorded Electroencephalograph (EEG) responses in an audiovisual asynchrony detection task while participants watched videos of a speaker. We filtered the speech signal to remove verbal content and examined how visual and auditory prosodic features temporally (mis-)align. Results...