Your search keyword '"Brown TH"' showing total 13 results

1. Prolonged synaptic integration in perirhinal cortical neurons.

Author

Beggs JM, Moyer JR Jr, McGann JP, and Brown TH

Subjects

Animals, Calcium Signaling physiology, Electric Stimulation, Excitatory Postsynaptic Potentials physiology, Feedback physiology, Hippocampus cytology, In Vitro Techniques, Membrane Potentials physiology, Models, Neurological, Neural Conduction physiology, Neuronal Plasticity physiology, Rats, Rats, Sprague-Dawley, Hippocampus physiology, Neurons physiology, Pyramidal Cells physiology, Synapses physiology

Abstract

Layer II/III of rat perirhinal cortex (PR) contains numerous late-spiking (LS) pyramidal neurons. When injected with a depolarizing current step, these LS cells typically delay spiking for one or more seconds from the onset of the current step and then sustain firing for the duration of the step. This pattern of delayed and sustained firing suggested a specific computational role for LS cells in temporal learning. This hypothesis predicts and requires that some layer II/III neurons should also exhibit delayed and sustained spiking in response to a train of excitatory synaptic inputs. Here we tested this prediction using visually guided, whole cell recordings from rat PR brain slices. Most LS cells (19 of 26) exhibited delayed spiking to synaptic stimulation (>1 s latency from the train onset), and the majority of these cells (13 of 19) also showed sustained firing that persisted for the duration of the synaptic train (5-10 s duration). Delayed and sustained firing in response to long synaptic trains has not been previously reported in vertebrate neurons. The data are consistent with our model that a circuit containing late spiking neurons can be used for encoding long time intervals during associative learning.

Published

2000

2. Complex synaptic current waveforms evoked in hippocampal pyramidal neurons by extracellular stimulation of dentate gyrus.

Author

Xiang Z and Brown TH

Subjects

Action Potentials, Animals, Baclofen pharmacology, Electric Stimulation, GABA Agonists pharmacology, Male, Mossy Fibers, Hippocampal physiology, Patch-Clamp Techniques, Rats, Rats, Sprague-Dawley, Receptors, GABA-B drug effects, Receptors, GABA-B physiology, Synaptic Transmission physiology, Dentate Gyrus physiology, Pyramidal Cells physiology

Abstract

Excitatory postsynaptic currents (EPSCs) evoked in hippocampal CA3 pyramidal neurons by extracellular stimulation of the dentate gyrus typically exhibit complex waveforms. They commonly have inflections or notches on the rising phase; the decay phase may exhibit notches or other obvious departures from a simple monoexponential decline; they often display considerable variability in the latency from stimulation to the peak current; and the rise times tend to be long. One hypothesis is that these complex EPSC waveforms might result from excitation via other CA3 pyramidal cells that were recruited antidromically or trans-synaptically by the stimulus due to the complex anatomy of this region. An alternative hypothesis is that EPSC complexity does not emerge from the functional anatomy but rather reflects an unusual physiological property, intrinsic to excitation-secretion coupling in mossy-fiber (mf) synaptic terminals, that causes asynchronous quantal release. We evaluated certain predictions of our anatomic hypothesis by adding a pharmacological agent to the normal bathing medium that should suppress di- or polysynaptic responses. For this purpose we used baclofen (3 microM), a selective agonist for the gamma-aminobutyric acid B receptor. The idea was that baclophen should discriminate against polysynaptic versus monosynaptic inputs by hyperpolarizing the cells, bringing them further from spike threshold and possibly also through inhibitory presynaptic actions. Whole cell recordings were done from visually preselected CA3 pyramidal neurons and EPSCs were evoked by fine bipolar electrodes positioned into the granule cell layer of the dentate. To the extent that the EPSC complexity reflects di- or polysynaptic responses, we predicted baclofen to reduce the number of notches on the rising and decay phases, reduce the variance in latency to peak of the EPSCs, decrease the amplitudes and rise times of the individual and averaged EPSCs, and increase the apparent failures in evoked EPSCs. All of these predictions were confirmed, in support of the hypothesis that these complex EPSC waveforms commonly reflect di- or polysynaptic responses. We also documented a distinctly different, intermittent, form of EPSC complexity, which also is predicted and easily explained by our anatomic hypothesis. In particular, the results were in accord with the suggestion that stimulation of the dentate gyrus might antidromically stimulate axon collaterals of CA3 neurons that make recurrent synapses onto the recorded cell. We conclude that the overall pattern of results is consistent with expectations based on the functional anatomy. The explanation does not demand a special type of intrinsic asynchronous mechanism for excitation-secretion coupling in the mf synapses.

Published

1998

3. Comparative electrotonic analysis of three classes of rat hippocampal neurons.

Author

Carnevale NT, Tsai KY, Claiborne BJ, and Brown TH

Subjects

Algorithms, Animals, Dendrites physiology, In Vitro Techniques, Membrane Potentials physiology, Rats, Rats, Sprague-Dawley, Synapses physiology, Dentate Gyrus cytology, Hippocampus cytology, Neurons classification, Pyramidal Cells physiology

Abstract

We present a comparative analysis of electrotonus in the three classes of principal neurons in rat hippocampus: pyramidal cells of the CA1 and CA3c fields of the hippocampus proper, and granule cells of the dentate gyrus. This analysis used the electrotonic transform, which combines anatomic and biophysical data to map neuronal anatomy into electrotonic space, where physical distance between points is replaced by the logarithm of voltage attenuation (log A). The transforms were rendered as "neuromorphic figures" by redrawing the cell with branch lengths proportional to log A along each branch. We also used plots of log A versus anatomic distance from the soma; these reveal features that are otherwise less apparent and facilitate comparisons between dendritic fields of different cells. Transforms were always larger for voltage spreading toward the soma (V(in)) than away from it (V(out)). Most of the electrotonic length in V(out) transforms was along proximal large diameter branches where signal loss for somatofugal voltage spread is greatest. In V(in) transforms, more of the length was in thin distal branches, indicating a steep voltage gradient for signals propagating toward the soma. All transforms lengthened substantially with increasing frequency. CA1 neurons were electrotonically significantly larger than CA3c neurons. Their V(out) transforms displayed one primary apical dendrite, which bifurcated in some cases, whereas CA3c cell transforms exhibited multiple apical branches. In both cell classes, basilar dendrite V(out) transforms were small, indicating that somatic potentials reached their distal ends with little attenuation. However, for somatopetal voltage spread, attenuation along the basilar and apical dendrites was comparable, so the V(in) transforms of these dendritic fields were nearly equal in extent. Granule cells were physically and electrotonically most compact. Their V(out) transforms at 0 Hz were very small, indicating near isopotentiality at DC and low frequencies. These transforms resembled those of the basilar dendrites of CA1 and CA3c pyramidal cells. This raises the possibility of similar functional or computational roles for these dendritic fields. Interpreting the anatomic distribution of thorny excrescences on CA3 pyramidal neurons with this approach indicates that synaptic currents generated by some mossy fiber inputs may be recorded accurately by a somatic patch clamp, providing that strict criteria on their time course are satisfied. Similar accuracy may not be achievable in somatic recordings of Schaffer collateral synapses onto CA1 pyramidal cells in light of the anatomic and biophysical properties of these neurons and the spatial distribution of synapses.

Published

1997

4. Calcium dynamics in thorny excrescences of CA3 pyramidal neurons.

Author

Jaffe DB and Brown TH

Subjects

Animals, In Vitro Techniques, Membrane Potentials physiology, Microscopy, Confocal, Rats, Rats, Sprague-Dawley, Synapses physiology, Calcium metabolism, Pyramidal Cells metabolism

Abstract

Confocal laser scanning microscopy was used to visualize Ca2+ transients in a particular type of dendritic spine, known as a thorny excrescence, in hippocampal CA3 pyramidal neurons. These large excrescences or thorns, which serve as the postsynaptic target for the mossy-fiber synaptic inputs, were identified on the basis of their location, frequency, and size. Whole cell recordings were made from superficial CA3 pyramidal neurons in thick hippocampal slices with the use of infrared video microscopy; cells with proximal apical dendrites close to the surface of the slice were selected. Changes in intracellular Ca2+ levels were monitored by imaging changes in fluorescence of the dyes Calcium Green-1 and Fluo-3. Dual-emission fluorescence imaging was also employed with the use of a combination of Fluo-3 and the Ca2+-insensitive dye seminaphthorhodafluor-1. This method was used to decrease the potential influence of background fluorescence on the calculated changes in intracellular Ca2+ concentration ([Ca2+]i). Somatic depolarization produced increases in [Ca2+]i in both the thorn and the immediately adjacent dendrite. Changes in [Ca2+]i were time locked with the onset of depolarization and the decay began immediately after the termination of depolarization. The peak increase in the Ca2+ signal was significantly greater in the thorns than in the adjacent dendritic shafts. With the use of high-temporal-resolution methods (line scans), differences were also seen in the time course of Ca2+ signals in these two regions. The decay time constants of the Ca2+ signal were faster in thorns than in the adjacent dendritic shafts. These observations suggest that voltage-gated Ca2+ channels are localized directly on the dendritic spines receiving mossy-fiber input. Furthermore, Ca2+ homeostasis within thorny excrescences is distinct from Ca2+ regulation in the dendritic shaft, at least over brief time periods, a finding that could have important implications for synaptic plasticity and signaling.

Published

1997

5. Electrotonic architecture of hippocampal CA1 pyramidal neurons based on three-dimensional reconstructions.

Author

Mainen ZF, Carnevale NT, Zador AM, Claiborne BJ, and Brown TH

Subjects

Animals, Calibration, Computer Simulation, Dendrites physiology, Electrophysiology, Hippocampus anatomy & histology, Hippocampus cytology, Male, Models, Neurological, Neural Conduction physiology, Neurons, Afferent physiology, Neurons, Afferent ultrastructure, Patch-Clamp Techniques, Pyramidal Cells ultrastructure, Rats, Rats, Sprague-Dawley, Hippocampus physiology, Pyramidal Cells physiology

Abstract

1. The spread of electrical signals in pyramidal neurons from the CA1 field of rat hippocampus was investigated through multicompartmental modeling based on three-dimensional morphometric reconstructions of four of these cells. These models were used to dissect the electrotonic architecture of these neurons, and to evaluate the equivalent cylinder approach that this laboratory and others have previously applied to them. Robustness of results was verified by the use of wide ranges of values of specific membrane resistance (Rm) and cytoplasmic resistivity. 2. The anatomy exhibited extreme departures from a key assumption of the equivalent cylinder model, the so-called "3/2 power law." 3. The compartmental models showed that the frequency distribution of steady-state electrotonic distances between the soma and the dendritic terminations was multimodal, with a large range and a sizeable coefficient of variation. This violated another central assumption of the equivalent cylinder model, namely, that all terminations are electronically equidistant from the soma. This finding, which was observed both for "centrifugal" (away from the soma) and "centripetal" (toward the soma) spread of electrical signals, indicates that the concept of an equivalent electrotonic length for the whole dendritic tree is not appropriate for these neurons. 4. The multiple peaks in the electrotonic distance distributions, whether for centrifugal or centripetal voltage transfer, were clearly related to the laminar organization of synaptic afferents in the CA1 region. 5. The results in the three preceding paragraphs reveal how little of the electrotonic architecture of these neurons is captured by a simple equivalent cylinder model. The multicompartmental model is more appropriate for exploring synaptic signaling and transient events in CA1 pyramidal neurons. 6. There was significant attenuation of synaptic potential, current, and charge as they spread from the dendritic tree to the soma. Charge suffered the least and voltage suffered the most attenuation. Attenuation depended weakly on Rm and strongly on synaptic location. Delay of time to peak was more distorted for voltage than for current and was more affected by Rm. 7. Adequate space clamp is not possible for most of the synapses on these cells. Application of a somatic voltage clamp had no significant effect on voltage transients in the subsynaptic membrane. 8. The possible existence of steep voltage gradients within the dendritic tree is consistent with the idea that there can be some degree of local processing and that different regions of the neuron may function semiautonomously. These spatial gradients are potentially relevant to synaptic plasticity in the hippocampus, and they also suggest caution in interpreting some neurophysiological results.

Published

1996

6. Metabotropic glutamate receptor activation induces calcium waves within hippocampal dendrites.

Author

Jaffe DB and Brown TH

Subjects

Animals, Culture Techniques, Membrane Potentials physiology, Pyramidal Cells physiology, Rats, Rats, Sprague-Dawley, Calcium physiology, Calcium Channels physiology, Dendrites physiology, Hippocampus physiology, Receptors, Metabotropic Glutamate physiology, Synaptic Transmission physiology

Abstract

1. We investigated the effects of metabotropic glutamate (mGlu) receptor activation on intracellular Ca2+ concentration ([Ca2+]i) in the soma and dendrites of hippocampal CA1 pyramidal neurons. Changes in [Ca2+]i were measured using confocal imaging simultaneously with whole-cell recording techniques. Differences in [Ca2+]i were visualized as changes in the fluorescence of the Ca(2+)-sensitive dye Fluo-3. 2. Brief application of the specific mGlu receptor agonist (1S,3R)-ACPD to either the apical or basal dendrites produced initially localized increases in [Ca2+]i that subsequently propagated as waves throughout much of the neuron. These Ca2+ waves, which propagated at approximately 40 microns/s, were shown not to reflect intracellular Ca2+ diffusion or extracellular diffusion of ACPD and were always accompanied by small outward membrane currents. 3. Repetitive application of ACPD failed to trigger further Ca2+ release. We found that a threshold level of voltage-gated Ca2+ entry during trains of action potentials was needed to prime further mGlu-stimulated Ca2+ release. In contrast, the passage of time alone did not cause the mGlu-release system to reactivate--restoration of ACPD-stimulated Ca2+ release. The spike-mediated Ca2+ signal was unaffected by mGlu-stimulated depletion of intracellular stores. 4. These experiments demonstrate that specific mGlu receptor activation can mobilize Ca2+ in dendrites of CA1 neurons and trigger waves of Ca(2+)-induced Ca(2+)-release throughout the cell. A use-dependent relationship between voltage-gated Ca2+ entry during trains of action potentials and mGlu-stimulated Ca2+ release is suggested.

Published

1994

7. Quantal mechanism of long-term potentiation in hippocampal mossy-fiber synapses.

Author

Xiang Z, Greenwood AC, Kairiss EW, and Brown TH

Subjects

Animals, Culture Techniques, Electric Stimulation, Male, Membrane Potentials physiology, Rats, Rats, Sprague-Dawley, Hippocampus physiology, Long-Term Potentiation physiology, Nerve Fibers physiology, Quantum Theory, Synapses physiology, Synaptic Transmission physiology

Abstract

1. The quantal mechanism underlying the expression of long-term potentiation (LTP) was studied in the mossy-fiber (mf) synapses of the rat hippocampus. Whole-cell recordings were used to measure the excitatory postsynaptic currents (EPSCs) before and after LTP induction in brain slices maintained at 31 +/- 1 degrees C. 2. Evoked EPSCs were recorded from 473 CA3 pyramidal neurons. The mf synapses were stimulated using paired pulses (40-ms interpulse interval) repeated every 2-10 s. At least 400 pairs of mf responses were obtained before and during the expression of LTP, which was produced by high-frequency (100 Hz) mf stimulation. Sufficiently stationary data were obtained from five neurons that exhibited LTP and that also satisfied strict criteria and procedures that are necessary for eliciting and identifying unitary mf responses. 3. Three independent lines of evidence implicated a presynaptic component to the mechanism underlying mf LTP. The first was based on a graphical version of the classical method of variance. The graphical variance (GV) method was evaluated by clamping the cell at two different holding potentials during paired-pulse facilitation (PPF). The results indicated that the GV method can distinguish changes in mean quantal content m and mean quantal size q in rat mf synapses. The same analysis, when applied to PPF before and after LTP induction, indicated that both result from an increase in m. 4. The second line of evidence was based on the classical method of failures. Consistent with the inference that mf LTP is due to an increase in m, there was a statistically significant reduction in the number of quantal release failures.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1994

8. Interpretation of voltage-clamp measurements in hippocampal neurons.

Author

Johnston D and Brown TH

Subjects

Animals, Electric Conductivity, Electrophysiology methods, Guinea Pigs, Hippocampus cytology, In Vitro Techniques, Kinetics, Models, Neurological, Neurophysiology methods, Synapses physiology, Synaptic Transmission, Hippocampus physiology, Membrane Potentials

Published

1983

9. Electrotonic structure and specific membrane properties of mouse dorsal root ganglion neurons.

Author

Brown TH, Perkel DH, Norris JC, and Peacock JH

Subjects

Animals, Culture Techniques, Electric Conductivity, Electric Stimulation, Membrane Potentials, Mice, Neurons physiology, Ganglia, Spinal physiology

Published

1981

10. Voltage-clamp analysis of mossy fiber synaptic input to hippocampal neurons.

Author

Brown TH and Johnston D

Subjects

Animals, Biophysical Phenomena, Biophysics, Electric Conductivity, Evoked Potentials, Guinea Pigs, In Vitro Techniques, Neuronal Plasticity, Neurotransmitter Agents physiology, Hippocampus physiology, Synapses physiology, Synaptic Transmission

Published

1983

11. Voltage-clamp analysis of synaptic inhibition during long-term potentiation in hippocampus.

Author

Griffith WH, Brown TH, and Johnston D

Subjects

Animals, Electric Conductivity, Evoked Potentials, In Vitro Techniques, Membrane Potentials, Microelectrodes, Pyramidal Tracts physiology, Rats, Time Factors, Hippocampus physiology, Synapses physiology

Abstract

The excitatory synaptic response evoked by stimulating the mossy fiber synaptic input to hippocampal CA3 neurons in normally accompanied by concomitant feedforward or recurrent inhibition. The purpose of the present study was to determine whether a decrease in the inhibitory conductance of this mixed synaptic response contributes to the enhanced synaptic efficacy observed during long-term potentiation (LTP). Intracellular recordings were made from CA3 neurons of rat hippocampal brain slices. Current- and voltage-clamp measurements of the mixed excitatory/inhibitory evoked synaptic response were made, using a single-electrode clamp system. Outward and inward rectification were reduced, respectively, by intracellular injection and bath application of Cs+. Biophysical analysis of the evoked synaptic conductance sequence was performed before and 15 min to 1 h after inducing LTP. As expected, measurements made in the early part of the conductance sequence, which represents primarily the monosynaptic excitatory input, demonstrated an increase in the slope conductance during LTP. Measurements made later in the conductance sequence, when the excitatory component appeared to have declined to a negligible value, revealed no decrease in the slope conductance of the inhibitory component of the mixed response. We conclude that a decrease in the conductance associated with the inhibitory component of the mixed synaptic response plays little or no role in the increase in synaptic efficacy observed during LTP of this synaptic system.

Published

1986

12. Passive electrical constants in three classes of hippocampal neurons.

Author

Brown TH, Fricke RA, and Perkel DH

Subjects

Animals, Cell Membrane physiology, Dendrites physiology, Electrophysiology, Guinea Pigs, In Vitro Techniques, Models, Neurological, Neurons physiology, Synapses physiology, Hippocampus physiology

Published

1981

13. Conductance mechanism responsible for long-term potentiation in monosynaptic and isolated excitatory synaptic inputs to hippocampus.

Author

Barrionuevo G, Kelso SR, Johnston D, and Brown TH

Subjects

Animals, Electric Conductivity, Electric Stimulation, Electrophysiology, Evoked Potentials, Guinea Pigs, In Vitro Techniques, Rats, Hippocampus physiology, Synapses physiology

Abstract

The biophysical mechanisms underlying long-term potentiation (LTP) were investigated in identifiable and monosynaptic excitatory inputs to hippocampal neurons. The results provide the first insights into the conductance changes that are responsible for the expression of LTP. Both current- and voltage-clamp measurements of the mossy fiber synaptic response in pyramidal neurons of region CA3 were made with a single-electrode-clamp system. The excitatory postsynaptic response was pharmacologically isolated by bathing hippocampal slices in saline containing 10 microM picrotoxin, which blocks the synaptic inhibition that normally accompanies the experimentally evoked mossy fiber response. LTP was induced by tetanically stimulating the mossy fiber input for 1 s at 100 Hz. Before and 20 min to 1 h after inducing LTP, we attempted to measure the mean excitatory postsynaptic potential (EPSP) amplitude, intrasomatic current-voltage relationship to a step (RN) or alpha function (AN) current waveform, membrane time constant (tau m), spike threshold (T50), peak excitatory postsynaptic current amplitude (IP), synaptic conductance increase (delta G), and synaptic reversal potential (VR); but adequate assessments of all eight of these were not always obtained for every cell that was studied. The induction of LTP increased the mean (+/- SE) EPSP amplitude form 10.5 +/- 1.4 mV during the control period to 16.8 +/- 2.4 mV after the induction of LTP (n = 14; P less than 0.05). This change was not accompanied by increases in the mean value of RN (63 +/- 11 M omega before and 61 +/- 11 M omega after induction; n = 8; P greater than 0.05); AN, which approximates the effective synaptic input resistance at the soma (10.0 +/- 1.50 M omega before and 10.5 +/- 1.60 M omega after; n = 10; P greater than 0.05); or tau m (22 +/- 2 ms before and 20 +/- 2 ms after; n = 8; P greater than 0.05). There was no significant change in T50, which was also assessed with an alpha function current waveform (1.48 +/- 0.11 nA before and 1.49 +/- 0.10 nA after; n = 6; P greater than 0.05). The mean value of IP increased from 1.1 +/- 0.2 nA during the control period to 1.8 +/- 0.3 nA after inducing LTP (n = 15; P less than 0.05). Similarly, delta G increased from 30 +/- 4 nS before to 47 +/- 4 nS after induction (n = 10; P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1986