Coordination of the axonal cytoskeleton during the emergence of axon collateral branches

The paralaminar nuclei, including the medial division of the medial geniculate nucleus, surround the auditory thalamus medially and ventrally. This multimodal area receives convergent inputs from auditory, visual, and somatosensory structures and sends divergent outputs to cortical layer 1, amygdala, basal ganglia, and elsewhere. Studies implicate this region in the modulation of cortical 40-Hz oscillations, cortical information binding, and the conditioned fear response. We recently showed that the basic anatomy and intrinsic physiology of paralaminar cells are unlike that of neurons elsewhere in sensory thalamus. Here we evaluate the synaptic inputs to paralaminar cells from the inferior and superior colliculi and the cortex. Combined physiological and anatomical evidence indicates that paralaminar cells receive both excitatory and inhibitory inputs from both colliculi and excitatory cortical inputs. Excitatory inputs from all three sources typically generate small summating EPSPs composed of AMPA and NMDA components and terminate primarily on smaller dendrites and occasionally on dendritic spines. The cortical input shows strong paired-pulse facilitation (PPF), whereas both collicular inputs show weak PPF or paired-pulse depression (PPD). EPSPs of cells with no low-threshold calcium conductance do not evoke a burst response when the cell is hyperpolarized. Longer-latency EPSPs were seen and our evidence indicates that these arise from axon collateral inputs of other synaptically activated paralaminar cells. The inhibitory collicular inputs are GABAergic, activate GABAA receptors, and terminate on dendrites. Their activation can greatly alter EPSP-generated spike number and timing.

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Electrotonic profiles of interneurons in stratum pyramidale of the CA1 region of rat hippocampus

Journal of Neurophysiology ◽

10.1152/jn.1994.71.5.1948 ◽

1994 ◽

Vol 71 (5) ◽

pp. 1948-1958 ◽

Cited By ~ 41

Author(s):

D. Thurbon ◽

A. Field ◽

S. Redman

Keyword(s):

Current Pulse ◽

Time Course ◽

Pyramidal Neurons ◽

Regional Distribution ◽

Total Surface Area ◽

Pulse Response ◽

Axon Collateral ◽

Ca1 Region ◽

Stratum Pyramidale ◽

Specific Membrane

1. Whole-cell recordings have been made from interneurons located in stratum pyramidale in the CA1 region of the hippocampus. The responses of these interneurons to brief current pulses were recorded; the neurons were filled with biocytin and their morphology was reconstructed. 2. The interneurons were identified as basket cells on the basis of the regional distribution of their axon collateral network and their location in stratum pyramidale. 3. A compartmental model of the reconstructed neuron was made, and the specific membrane resistivity (Rm), specific cytoplasmic resistivity (Ri), and somatic shunt leakage resistance (Rs) determined by adjusting these parameters until an optimal fit was obtained between the compartmental model's current pulse response and the recorded current pulse response of the neuron. 4. This procedure was successful for six neurons, giving Rm from 7 to 66 k omega cm2, Ri from 52 to 484 omega cm, and Rs from 84 M omega to infinity. The specific membrane capacitance was assumed to be 1 microF/cm2. The electrotonic length of the apical dendrites was 1.06 +/- 0.4, and for the basal dendrites it was 0.51 +/- 0.26 (mean +/- SD). 5. Although the total surface area of the interneurons and the physical length of their dendrites was much smaller than for CA1 pyramidal neurons, their electrotonic profiles were similar. Neurons with small physical profiles cannot be assumed to be more electrotonically compact than larger neurons, especially if the dendrites of the smaller neurons have a proportional reduction in diameter. 6. Two neurons did not require a somatic leakage conductance in their electrical representation. This suggests that when a somatic leakage conductance is required, it is an artifact resulting from electrode damage, rather than a requirement caused by a lower resistivity of the somatic membrane compared with the dendritic membrane. 7. Simulations of synaptic currents evoked in the dendrites of these interneurons while the soma is voltage clamped indicate large errors will occur in the time course measurements and amplitude of these currents. Also the ratio of N-methyl-D-aspartate:alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (NMDA:AMPA) currents at these synapses calculated from currents recorded at the soma will be in error because of the differential attenuation of the faster AMPA currents compared with the NMDA currents.

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In Vivo Intracellular Analysis of Granule Cell Axon Reorganization in Epileptic Rats

Journal of Neurophysiology ◽

10.1152/jn.1999.81.2.712 ◽

1999 ◽

Vol 81 (2) ◽

pp. 712-721 ◽

Cited By ~ 119

Author(s):

Paul S. Buckmaster ◽

F. Edward Dudek

Keyword(s):

Granule Cell ◽

Granule Cells ◽

Molecular Layer ◽

Axon Collateral ◽

Cell Axon ◽

Recurrent Excitation ◽

The Difference ◽

Intracellular Analysis

In vivo intracellular analysis of granule cell axon reorganization in epileptic rats. In vivo intracellular recording and labeling in kainate-induced epileptic rats was used to address questions about granule cell axon reorganization in temporal lobe epilepsy. Individually labeled granule cells were reconstructed three dimensionally and in their entirety. Compared with controls, granule cells in epileptic rats had longer average axon length per cell; the difference was significant in all strata of the dentate gyrus including the hilus. In epileptic rats, at least one-third of the granule cells extended an aberrant axon collateral into the molecular layer. Axon projections into the molecular layer had an average summed length of 1 mm per cell and spanned 600 μm of the septotemporal axis of the hippocampus—a distance within the normal span of granule cell axon collaterals. These findings in vivo confirm results from previous in vitro studies. Surprisingly, 12% of the granule cells in epileptic rats, and none in controls, extended a basal dendrite into the hilus, providing another route for recurrent excitation. Consistent with recurrent excitation, many granule cells (56%) in epileptic rats displayed a long-latency depolarization superimposed on a normal inhibitory postsynaptic potential. These findings demonstrate changes, occurring at the single-cell level after an epileptogenic hippocampal injury, that could result in novel, local, recurrent circuits.

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Projection Neuron Axon Collaterals in the Dorsal Horn: Placing a New Player in Spinal Cord Pain Processing

Frontiers in Physiology ◽

10.3389/fphys.2020.560802 ◽

2020 ◽

Vol 11 ◽

Author(s):

Tyler J. Browne ◽

David I. Hughes ◽

Christopher V. Dayas ◽

Robert J. Callister ◽

Brett A. Graham

Keyword(s):

Spinal Cord ◽

Dorsal Horn ◽

Spinal Pain ◽

Spinal Cord Dorsal Horn ◽

Axon Collateral ◽

Pain Processing ◽

Axon Collaterals ◽

Output Neurons ◽

Local Circuits ◽

Collateral System

The pain experience depends on the relay of nociceptive signals from the spinal cord dorsal horn to higher brain centers. This function is ultimately achieved by the output of a small population of highly specialized neurons called projection neurons (PNs). Like output neurons in other central nervous system (CNS) regions, PNs are invested with a substantial axon collateral system that ramifies extensively within local circuits. These axon collaterals are widely distributed within and between spinal cord segments. Anatomical data on PN axon collaterals have existed since the time of Cajal, however, their function in spinal pain signaling remains unclear and is absent from current models of spinal pain processing. Despite these omissions, some insight on the potential role of PN axon collaterals can be drawn from axon collateral systems of principal or output neurons in other CNS regions, such as the hippocampus, amygdala, olfactory cortex, and ventral horn of the spinal cord. The connectivity and actions of axon collaterals in these systems have been well-defined and used to confirm crucial roles in memory, fear, olfaction, and movement control, respectively. We review this information here and propose a framework for characterizing PN axon collateral function in the dorsal horn. We highlight that experimental approaches traditionally used to delineate axon collateral function in other CNS regions are not easily applied to PNs because of their scarcity relative to spinal interneurons (INs), and the lack of cellular organization in the dorsal horn. Finally, we emphasize how the rapid development of techniques such as viral expression of optogenetic or chemogenetic probes can overcome these challenges and allow characterization of PN axon collateral function. Obtaining detailed information of this type is a necessary first step for incorporation of PN collateral system function into models of spinal sensory processing.

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