CCL28 in the mouse hippocampal CA1 area and the dentate gyrus during and after pilocarpine-induced status epilepticus

The present study showed a wide presence of CCL28 in mouse CNS, including cerebral, cerebellum, brain stem and spinal cord. In hippocampus, the expression of CCL28 at both mRNA and protein level was clarified. The CCL28 expression was mainly localized in pyramidal cells of CA area, granular cells of dentate gyrus and some interneurons in CA area and hilus. Double-labelling immunocytochemistry revealed that most of calbindin, calretinin and parvalbumin immunopositive neurons expressed CCL28. During and after pilocarpine induced status epilepticus (SE), a down-regulated expression of CCL28 in hippocampal interneurons in the CA1 area and in the hilus of the dentate gyrus was demonstrated. The present study may, therefore provide evidence that CCL28 may have a novel role in CNS and may be involved in the loss of hippocampal interneurons, and subsequent disinhibition of pyramidal neurons.     

Age-Dependent Changes in Calretinin Immunoreactivity and its Protein Level in the Gerbil Hippocampus

Calretinin (CR)-immunoreactive interneurons are well known as the interneuron specific interneurons in the hippocampus. CR-immunoreactive neurons form cellular network and regulate the activity of other GABAergic inhibitory interneurons in the hippocampus. In the present study, we investigated age-related changes in CR-immunoreactive neurons and protein levels in the gerbil hippocampus during normal aging. In all subregions of the gerbil hippocampus, the number of CR-immunoreactive neurons was significantly decreased in the postnatal month 6 (PM 6) group compared to that in the PM 1 group. Thereafter, CR-immunoreactive neurons were decreased with age. In addition, the number of CR-immunoreactive cells in the subgranular zone were significantly decreased in the PM 6 group. We also observed that CR protein levels were decreased gradually with age. These results indicate that both CR immunoreactivity and its protein level were decreased with age in the gerbil hippocampus during normal aging.     

Aging in the rat hippocampus is associated with widespread reductions in the number of glutamate decarboxylase-67 positive interneurons but not interneuron degeneration

Increased excitability of principal excitatory neurons is one of the hallmarks of aging in the hippocampus, signifying a diminution in the number and/or function of inhibitory interneurons with aging. To elucidate this, we performed comprehensive GABA-ergic interneuron cell counts in all layers of the dentate gyrus and the CA1 and CA3 subfields, using serial sections from adult, middle-aged and aged Fischer 344 rats. Sections were immunostained for glutamate decarboxylase-67 (GAD-67, a synthesizing enzyme of GABA) and GAD-67 immunopositive interneurons were counted using an unbiased cell counting method, the optical fractionator. Substantial declines in the absolute number of GAD-67 immunopositive interneurons were found in all hippocampal layers/subfields of middle-aged and aged animals, in comparison with the adult animals. However, the counts were comparable between the middle-aged and aged groups for all regions. Interestingly, determination of the absolute number of interneurons using neuron-specific nuclear antigen (NeuN) expression in the strata oriens and radiatum of CA1 and CA3 subfields revealed an analogous number of interneurons across the three age groups. Furthermore, the ratio of GAD-67 immunopositive and NeuN positive interneurons decreased from adult age to middle age but remained relatively static between middle age and old age. Collectively, the results underscore that aging in the hippocampus is associated with wide-ranging decreases in the number of GAD-67 immunopositive interneurons and most of the age-related changes in GAD-67 immunopositive interneuron numbers transpire by middle age. Additionally, this study provides novel evidence that age-related reductions in hippocampal GAD-67 immunopositive interneuron numbers are due to loss of GAD-67 expression in interneurons rather than interneuron degeneration.     

Parvalbumin Immunoreactivity and Protein Level are Altered in the Gerbil Hippocampus During Normal Aging

Hippocampal interneurons are local circuit neurons which are responsible for inhibitory activity in the hippocampus. Parvalbumin (PV) is one of useful markers for GABAergic interneurons, not for principle cells, in the hippocampus. In the present study, we investigated age-related changes in PV immunoreactive neurons and protein levels in the gerbil hippocampus during normal aging. PV immunoreactive neurons were detected in all hippocampal subregions of all groups. PV immunoreactive neurons, which innervated principal neurons, were non-pyramidal neurons in the hippocampal CA1-3 regions, and were polymorphic neurons in the dentate gyrus. In the hippocampal CA1 region, the number of PV immunoreactive neurons was significantly reduced in the postnatal month 3 (PM 3) group, which was sustained by PM 18, and, at PM 24, the number of PV immunoreactive neurons was significantly decreased. In the CA2/3 region and dentate gyrus, the number of PV immunoreactive neurons was significantly decreased at PM 6: Thereafter, the number of PV immunoreactive neurons was sustained until PM 24. In addition, changes in PV protein levels in the gerbil hippocampus were similar to immunohistochemical changes during normal aging: PV protein levels were significantly decreased with age by PM 6: Thereafter, PV protein levels were sustained by PM 24. These results suggest that PV immunoreactive interneurons were decreased in the hippocampus with age in gerbils.     

Immediate effects of maternal separation on the development of interneurons derived from medial ganglionic eminence in the neonatal mouse hippocampus

Aversive experiences, including maternal separation (MS), have been known as a risk for abnormal hippocampus development. Given that impairment of GABA inhibitory system is known as one of the common features of the abnormal hippocampal development induced by MS, we examined whether the MS on 4‐day‐old (P4) mice for 24 hr abolishes the interneuron development. We observed that the MS reduced the volume of dorsal hippocampus on P14 as long‐term effects. In addition, the MS decreased the number of parvalbumin (PV)‐positive interneuron on P14 and P28 in the dorsal hippocampus. We further examined the immediate effects of MS by measuring the percentage of glutamic acid decarboxylase (GAD) 67‐positive interneurons among the immature interneurons derived from medial ganglionic eminence (MGE) progenitors marked in nkx2.1cre;β‐geo EGFP mice. During normal development from P4 to P5, the percentage of GAD67‐positive interneurons among the MGE‐derived interneurons in the dorsal hippocampus was significantly increased from 42.29% to 70.73% in the stratum pyramidale of the CA1 and increased from 46.4% to 56.99% in the stratum pyramidale of the CA2/3 region. However, the increase was not observed on P5 among the mice treated with the MS. These results suggest that the maturation of interneurons was suppressed by the MS. The suppressed maturation of interneurons may be one of the causes of the reduced volume of the hippocampus and PV+ interneurons observed in the hippocampus on P14 and P28 as a consequence of the MS during neonatal stage.     

EPSP amplification and the precision of spike timing in hippocampal neurons

The temporal precision with which EPSPs initiate action potentials in postsynaptic cells determines how activity spreads in neuronal networks. We found that small EPSPs evoked from just subthreshold potentials initiated firing with short latencies in most CA1 hippocampal inhibitory cells, while action potential timing in pyramidal cells was more variable due to plateau potentials that amplified and prolonged EPSPs. Action potential timing apparently depends on the balance of subthreshold intrinsic currents. In interneurons, outward currents dominate responses to somatically injected EPSP waveforms, while inward currents are larger than outward currents close to threshold in pyramidal cells. Suppressing outward potassium currents increases the variability in latency of synaptically induced firing in interneurons. These differences in precision of EPSP-spike coupling in inhibitory and pyramidal cells will enhance inhibitory control of the spread of excitation in the hippocampus.     

Modifications in muscarinic, dopaminergic and serotonergic receptors concentrations in the hippocampus and striatum of epileptic rats

The present study was undertaken in order to investigate the muscarinic (M(1)), dopaminergic (D(1) and D(2)) and serotonergic (5-HT(2)) receptors densities in hippocampus and striatum of Wistar rats after status epilepticus (SE) induced by pilocarpine. The control group was treated with 0.9% saline. An other group of rats received pilocarpine (400 mg/kg, s.c.) and both groups were sacrificed 1 h after treatment. The results have shown that pilocarpine administration and resulting SE produced a downregulation of M(1) receptor in hippocampus (41%) and striatum (51%) and an increase in the dissociation constant (K(d)) values in striatum (42%) alone. In both areas the 5-HT(2) receptor density remained unaltered, but a reduction (50%) and an increase (15%) in the K(d) values were detected in striatum and hippocampus, respectively. D(1) and D(2) receptor densities in hippocampus and striatum remained unaltered meanwhile K(d) values for D(1) receptor declined significantly, 33% in hippocampus and 26% in striatum. Similarly, K(d) values for D(2) decreased 55% in hippocampus and 52% in striatum. From the preceding results, it is clear that there is a possible relation between alterations in muscarinic receptor density and others systems studied as well as they suggest that changes in dissociation constant can be responsible for the establishment of pilocarpine-induced SE by altering the affinity of neurotransmitters such as acetylcholine, dopamine and serotonine.     

Neurogenesis in the adult brain. Functional consequences

In the adult mammalian brain, neuroblasts are continuously produced within the subgranular zone of the hippocampus and the subventricular zone (SVZ) of the forebrain. In this review we describe how some physiological and environmental factors play important roles in regulating neurogenesis in the hippocampus. Neuroblasts in the SVZ network migrate rostrally into the olfactory bulb where they differentiate into local interneurons. We focus on the production, survival and functional consequences of these newly generated interneurons. We show that enriched odor-exposure enhances the number of newborn neurons in the adult olfactory bulb but not in the hippocampus. This effect did not result from changes in cell proliferation but rather was due to greater neuronal survival. Furthermore, the enriched condition was found to dramatically extend the olfactory memory. By maintaining a constitutive turnover of interneurons subjected to regulation by bulbar activity, ongoing neurogenesis plays a key role in olfactory memory.     

Inhibitory interneurons in hippocampus

In the hippocampus and DG, a small number of morphologically and physiologically diverse interneurons controls the neuronal activity of large numbers of the principal excitatory output cells. The inhibitory interneurons are themselves regulated by glutamatergic and GABA-ergic intrinsic hippocampus afferents, as well as by extrinsic afferents, including cholinergic and serotonergic projections from the basal forebrain and the brainstem, respectively. In addition to the slow modulatory effects of the neurotransmitters released from these extrinsic pathways (11), recent evidence has revealed rapid effects of ACh and 5-HT mediated by ligand-gated ion channel receptors for these neurotransmitters. The direct, rapid excitatory action of ACh and 5-HT on hippocampus interneurons can explain many of the effects of these neurotransmitters on neuronal activity in the hippocampus circuit. Because the hippocampus receives both serotonergic and cholinergic innervation, there is strong potential for fast cholinergic and serotonergic synaptic transmission between these fibers and hippocampus interneurons, such as has been reported in other brain regions (e.g., visual cortex) (36). Moreover, these receptors may play important roles in the cognitive functions of the hippocampus, and show impaired function in certain neurological disorders, such as neurodegeneration. Recently McQuiston and Madison (77) have recorded functional nAChR-mediated responses in other interneuronal layers in the CA1 region of the rat hippocampus, and recently nAChR-mediated fast excitatory synaptic transmission has been provided in area CA1 of the rat hippocampus (78, 79). See Jones et al. (80) for a recent review.     

Cell migration from the ganglionic eminences is required for the development of hippocampal GABAergic interneurons

GABAergic interneurons have major roles in hippocampal function and dysfunction. Here we provide evidence that, in mice, virtually all of these cells originate from progenitors in the basal telencephalon. Immature interneurons tangentially migrate from the basal telencephalon through the neocortex to take up their final positions in the hippocampus. Disrupting differentiation in the embryonic basal telencephalon (lateral and medial ganglionic eminences) through loss of Dlx1/2 homeobox function blocks the migration of virtually all GABAergic interneurons to the hippocampus. On the other hand, disrupting specification of the medial ganglionic eminence through loss of Nkx2.1 homeobox function depletes the hippocampus of a distinct subset of hippocampal interneurons. Loss of hippocampal interneurons does not appear to have major effects on the early development of hippocampal projection neurons nor on the pathfinding of afferrent tracts.     

The Wobbler Mouse Model of Amyotrophic Lateral Sclerosis (ALS) Displays Hippocampal Hyperexcitability,and Reduced Number of Interneurons,but No Presynaptic Vesicle Release Impairments

Amyotrophic lateral sclerosis (ALS) is the most common adult-onset motor neuron disease. It is a fatal degenerative disease, best recognized for its debilitating neuromuscular effects. ALS however also induces cognitive impairments in as many as 50% of affected individuals. Moreover, many ALS patients demonstrate cortical hyperexcitability, which has been shown to precede the onset of clinical symptoms. The wobbler mouse is a model of ALS, and like ALS patients the wobbler mouse displays cortical hyperexcitability. Here we investigated if the neocortical aberrations of the wobbler mouse also occur in the hippocampus. Consequently, we performed extracellular field excitatory postsynaptic potential recordings in the CA1 region of the hippocampus on acute brain slices from symptomatic (P45-P60) and presymptomatic (P17-P21) wobbler mice. Significant increased excitation of hippocampal synapses was revealed by leftward shifted input/output-curves in both symptomatic and presymptomatic wobbler mice, and substantiated by population spike occurrence analyses, demonstrating that the increased synaptic excitation precedes the onset of visible phenotypic symptoms in the mouse. Synaptic facilitation tested by paired-pulse facilitation and trains in wobbler and control mice showed no differences, suggesting the absence of presynaptic defects. Immunohistochemical staining revealed that symptomatic wobbler mice have a lower number of parvalbumin positive interneurons when compared to controls and presymptomatic mice. This study reveals that the wobbler mouse model of ALS exhibits hippocampal hyperexcitability. We suggest that the hyperexcitability could be caused by increased excitatory synaptic transmission and a concomitant reduced inhibition due to a decreased number of parvalbumin positive interneurons. Thus we substantiate that wobbler brain impairments are not confined to the motor cortex, but extend to the hippocampus. Importantly, we have revealed more details of the early pathophysiology in asymptomatic animals, and studies like the present may facilitate the development of novel treatment strategies for earlier intervention in ALS patients in the future.     

Time-Dependent Modulation of Mitogen Activated Protein Kinases and AKT in Rat Hippocampus and Cortex in the Pilocarpine Model of Epilepsy

The epileptogenesis may involve a variety of signaling events that culminate with synaptic reorganization. Mitogen-activated protein kinases (MAPKs) and AKT may be activated by diverse stimulus including neurotransmitter, oxidative stress, growth factors and cytokines and are involved in synaptic plasticity in the hippocampus and cerebral cortex. The pilocarpine model in rodents reproduces the main features of mesial temporal lobe epilepsy related to hippocampus sclerosis (MTLE-HS) in humans. We analyze the phosphorylation profile of MAPKs (ERK1/2, p38(MAPK), JNK1/2/3) and AKT by western blotting in the hippocampus (Hip) and cortex (Ctx) of male adult wistar rats in different periods, after pilocarpine induced status epilepticus (Pilo-SE) and compared with control animals. Biochemical analysis were done in the Hip and Ctx at 1, 3, 12?h (acute period), 5?days (latent period) and 50?days (chronic period) after Pilo-SE onset. Hence, the main findings include increased phosphorylation of ERK1 and p38(MAPK) in the Hip and Ctx 1 and 12?h after the Pilo-SE onset. The JNK2/3 isoform (54?kDa) phosphorylation was decreased at 3?h after the Pilo-SE onset and in the chronic period in the Hip and Ctx. The AKT phosphorylation increased only in the Hip during the latent period. Our study demonstrates, in a systematic manner, the profile of MAPKs and AKT modulation in the hippocampus and cerebral cortex in response to pilocarpine. Based in the role of each signaling enzyme is possible that these changes may be related, at least partially, to modifications in the intrinsic neuronal physiology and epileptogenic synaptic network that appears in the MTLE-HS.     

BAX敲除对小鼠大脑皮层和海马星形胶质细胞分布的影响

星形胶质细胞是大脑中一类高度异质的重要大胶质细胞,不仅在脑的发育和功能中起到重要作用,也参与多种神经病理生理学过程.多项研究表明B淋巴细胞瘤-2相关X蛋白(B-cell lymphoma-2 associated X protein,BAX)依赖性凋亡通路参与调控正常发育过程中脑内神经元的数量与分布,但是对其调控星形胶...     

Role of local nonspiking interneurons in the generation of rhythmic motor activity in the stick insect

Local nonspiking interneurons in the thoracic ganglia of insects are important premotor elements in posture control and locomotion. It was investigated whether these interneurons are involved in the central neuronal circuits generating the oscillatory motor output of the leg muscle system during rhythmic motor activity. Intracellular recordings from premotor nonspiking interneurons were made in the isolated and completely deafferented mesothoracic ganglion of the stick insect in preparations exhibiting rhythmic motor activity induced by the muscarinic agonist pilocarpine. All interneurons investigated provided synaptic drive to one or more motoneuron pools supplying the three proximal leg joints, that is, the thoraco-coxal joint, the coxa-trochanteral joint and the femur-tibia joint. During rhythmicity in 83% (n=67) of the recorded interneurons, three different kinds of synaptic oscillations in membrane potential were observed: (1) Oscillations were closely correlated with the activity of motoneuron pools affected; (2) membrane potential oscillations reflected only certain aspects of motoneuronal rhythmicity; and (3) membrane potential oscillations were correlated mainly with the occurrence of spontaneous recurrent patterns (SRP) of activity in the motoneuron pools. In individual interneurons membrane potential oscillations were associated with phase-dependent changes in the neuron's membrane conductance. Artificial changes in the interneurons' membrane potential strongly influenced motor activity. Injecting current pulses into individual interneurons caused a reset of rhythmicity in motoneurons. Furthermore, current injection into interneurons influenced shape and probability of occurrence for SRPs. Among others, identified nonspiking interneurons that are involved in posture control of leg joints were found to exhibit the above properties. From these results, the following conclusions on the role of nonspiking interneurons in the generation of rhythmic motor activity, and thus potentially also during locomotion, emerge: (1) During rhythmic motor activity most nonspiking interneurons receive strong synaptic drive from central rhythm-generating networks; and (2) individual nonspiking interneurons some of which underlie sensory-motor pathways in posture control, are elements of central neuronal networks that generate alternating activity in antagonistic leg motoneuron pools. © 1995 John Wiley & Sons, Inc.     

Silencing lncRNA PVT1 inhibits activation of astrocytes and increases BDNF expression in hippocampus tissues of rats with epilepsy by downregulating the Wnt signaling pathway

The aim of this study is to investigate the effects of long-chain noncoding RNA plasmacytoma variant translocation 1 (PVT1) on the activation of astrocytes and the expression of brain-derived neurotrophic factor (BDNF) in hippocampus tissues of epileptic rats. The epilepsy rat model was induced by intraperitoneal injection of lithium chloride–pilocarpine. Successfully modeled rats were grouped, and their spatial learning and memory, neuronal loss, number of TdT-mediated dUTP nick labeling (TUNEL)-positive cells, and the expression of cleaved-caspase-3, pro-caspase-3, Bax, Bcl-2, GFAP, BDNF, tumor necrosis factor-α (TNF-α), interleukin-1β (IL-1β), IL-6, axin, and cyclin D1 in hippocampus tissues were evaluated. Increased expression of PVT1 was found in hippocampus tissues of epileptic rats. Silencing of PVT1 improved spatial learning and memory, decreased neuronal loss, decreased the number of TUNEL-positive cell, decreased the expression of cleaved-caspase-3 and Bax while increased pro-caspase-3 and Bcl-2 expression, decreased the expression of GFAP, increased the expression of BDNF, decreased the expression of TNF-α, IL-1β, and IL-6, and decreased the expression of axin and cyclin D1 in hippocampus tissues in epileptic rats. Our study provides evidence that the inhibition of PVT1 may decrease the loss of neurons, inhibit the activation of astrocytes, and increase the expression of BDNF in hippocampus by downregulating the Wnt signaling pathway.     

Assessing the roles of glutamatergic and cholinergic synaptic drive in the control of fictive swimming frequency in young Xenopus tadpoles

This paper investigates the proposal that the frequency of the swimming central pattern generator in young Xenopus tadpoles is partly determined by the population of glutamatergic premotor interneurons active on each cycle. During fictive swimming spinal neurons also receive cholinergic and electrotonic excitation from motoneurons. As frequency changes during swimming we make two predictions: first, since most motoneurons fire very reliably at all frequencies, the electrotonic and nicotinic drive from motoneurons should remain constant, and second, when swimming frequency decreases, the glutamatergic drive should decrease as the number of active premotor excitatory interneurons decreases. We have tested these predictions by measuring the excitatory synaptic drive to motoneurons as frequency changes during fictive swimming. The components of synaptic drive were revealed by the local microperfusion of strychnine together with different excitatory antagonists. After blocking the nicotinic acetylcholine receptor, the mainly glutmatergic excitatory synaptic drive still changed with frequency. However, when glutamate receptors or all chemical transmission was blocked, excitation did not change with frequency. Our predictions are confirmed, suggesting that premotor excitatory interneurons are a major factor in frequency control in the tadpole central pattern generator and that motoneurons provide a stable background excitation. Accepted: 14 August 1998     

Physiological and morphological characterization of olfactory descending interneurons of the male silkworm moth, Bombyx mori

In order to understand the neural mechanisms of pheromone-oriented walking in male silkworm moths, Bombyxmori, we have characterized olfactory responses and three-dimensional structure of two clusters (Group-I, Group-II) of descending interneurons in the brain by intracellular recording and staining with lucifer yellow. Neurons were imaged with laser-scanning confocal microscopy. Group-I and Group-II descending interneurons were classified into three morphological types, respectively. In response to the sex pheromone, bombykol, Type-A Group-I descending interneurons showed characteristic flipflopping activity. The Group-I descending interneurons had dendritic arborizations in the lateral accessory lobe and varicose profiles in the posterior-lateral part of the suboesophageal ganglion where the dendritic arborizations of a neck motor neuron (i.e., cv1 NMN) reside. Other types of Group-I descending interneurons exhibited long-lasting suppression of firing. The pheromonal responses of Group-II descending interneurons fell into two classes: brief excitation and brief inhibition. Type-A Group-II descending interneurons showing brief excitation had blebby processes in the posterior-lateral part of the suboesophageal ganglion. Type-B and Type-C Group-II descending interneurons did not have varicose profiles there. Therefore, the neck motor neuron regulating head turning, which accompanies the pheromone-oriented walking, may be controlled by these two types, flipflop and phasic excitation, of descending activity patterns. Accepted: 2 November 1998     

Mechanisms of gamma oscillations in the hippocampus of the behaving rat

Gamma frequency oscillations (30-100 Hz) have been suggested to underlie various cognitive and motor functions. Here, we examine the generation of gamma oscillation currents in the hippocampus, using two-dimensional, 96-site silicon probes. Two gamma generators were identified, one in the dentate gyrus and another in the CA3-CA1 regions. The coupling strength between the two oscillators varied during both theta and nontheta states. Both pyramidal cells and interneurons were phase-locked to gamma waves. Anatomical connectivity, rather than physical distance, determined the coupling strength of the oscillating neurons. CA3 pyramidal neurons discharged CA3 and CA1 interneurons at latencies indicative of monosynaptic connections. Intrahippocampal gamma oscillation emerges in the CA3 recurrent system, which entrains the CA1 region via its interneurons.     

Classification and function of GABAergic interneurons of the mammalian cerebral cortex

GABAergic interneurons make up about 20% of neurons in the cortex and are a heterogeneous group of cells. In recent years it has become clear that different populations of interneurons not only provide the balance of excitation and inhibition in neural networks but are also critically important for generation of rhythmic activity, successful processing of sensory information, implementation of synaptic plasticity and a number of other functions. We examine current approaches to classification of interneurons and review the properties and the functional role of basket cells, chandelier cells, neurogliaform interneurons, Martinotti cells, and some other classes of interneurons based on morphological, immunohistochemical, electrophysiological and optogenetic studies. Besides, we consider the opportunities of the selective impact on target population of interneurons and review the data on the role of different types of interneurons in the pathogenesis of epilepsy and schizophrenia.     

Simulation of Gamma Rhythms in Networks of Interneurons and Pyramidal Cells

Networks of hippocampal interneurons, with pyramidal neuronspharmacologically disconnected, can generate gamma-frequency(20 Hz and above) oscillations. Experiments and models have shownhow the network frequency depends on excitation of the interneurons,and on the parameters of GABA_{{\rm A}}-mediated IPSCs betweenthe interneurons (conductance and time course). Herewe use network simulations to investigate how pyramidal cells, connected tothe interneurons and to each other throughAMPA-type and/or NMDA-type glutamatereceptors, might modify the interneuron network oscillation. With orwithout AMPA-receptor mediated excitation of the interneurons, the pyramidal cells and interneurons fired in phaseduring the gamma oscillation. Synaptic excitation of the interneuronsby pyramidal cellscaused them to fire spike doublets or short bursts at gammafrequencies, thereby slowing the population rhythm.Rhythmic synchronized IPSPs allowed the pyramidal cells toencode their mean excitation by their phase of firing relativeto the population waves.Recurrent excitation between the pyramidal cells couldmodify the phase of firing relative to the population waves.Our model suggests that pools of synaptically interconnectedinhibitory cells are sufficient to produce gamma frequency rhythms,but the network behavior can be modified by participation ofpyramidal cells.