Recruitment of interictal- and ictal-like discharges in posterior piriform cortex by delta-rate (1-4 Hz) focal bursts in anterior piriform cortex in vivo.

The development and propagation of seizure-related activity was studied in piriform cortex (PC) and areas in the medial temporal lobe to which it projects. In the urethane anesthetized adult rat at normal body temperature, tiny injections of convulsants in anterior PC (APC) generate an epileptogenic zone (focus) that can recruit electrographic seizures in untreated posterior PC (PPC) when bursts in the focus are paced at delta frequency (1-4 Hz) by stimulating the lateral olfactory tract. Epileptiform activity initiated by this 'paced-recruitment' procedure propagates throughout PPC and into other areas involved in mesial temporal lobe epilepsy (mTLE) at an exceedingly low velocity (< 1 mm/sec) as reported for focal seizures in human cortex. Proconvulsants increased the probability of recruiting electrographic seizures relative to disinhibiting agents that typically recruited interictal discharges. Through methods including realtime recording of current source-density (CSD) with vertical 22-site silicon-based electrodes, and membrane potential with transmembrane microelectrode pairs, insights were gained into mechanisms for epileptogenesis from PC. These findings also may apply to seizure initiation from epileptogenic zones in other areas that project to PPC in addition to APC. Findings from surgical studies indicating that PC plays a critical role in mTLE suggest that the results may be relevant to finding new approaches for blocking seizures from this common, virulent form of epilepsy. Immediate implications for treatment include the optimal placement and patterning of deep brain stimulation to increase its effectiveness for blocking seizures from mTLE while reducing the risk to vasculature from direct stimulation of PC.

Cellular and subcellular localization of Kir2.1 subunits in neurons and glia in piriform cortex with implications for K+ spatial buffering.

Potassium channels of the Kir2 family are widely expressed in neurons and glia, where they form strong inwardly rectifying channels. Existing functional hypotheses for these channels in neurons are based on the weak outward conductance, whereas the leading hypothesis for glia, that they promote potassium spatial buffering, is based on inward conductance. Although the spatial buffering hypothesis has been confirmed for Müller glia in retina, many aspects of Kir2 channels that will be required for understanding their functional roles in neurons and other forms of glia have received little or no study. Particularly striking is the paucity of data regarding their cellular and subcellular localization. We address this gap for Kir2.1-containing channels by using light and electron microscopic immunocytochemistry. The analysis was of piriform cortex, a highly epileptogenic area of cerebral cortex, where pyramidal cells have K(+)-selective strong inward rectification like that observed in Müller cells, where Kir2.1 is the dominant Kir2 subunit. Pyramidal cells in adult piriform cortex also lack I(h), the mixed Na(+)-K(+) current that mediates a slower form of strong inward rectification in large pyramidal cells in neocortex and hippocampus. The experiments demonstrated surface expression of Kir2.1-containing channels in astrocytes and in multiple populations of pyramidal and nonpyramidal cells. Findings for astrocytes were not consistent with predictions for K(+) spatial buffering over substantial distance. However, findings for pyramidal cells suggest that they could be a conduit for spatially buffering K(+) when it is highly elevated during seizure.

Beta and gamma oscillations in the olfactory system of the urethane-anesthetized rat.

Fast oscillations in the beta (15-40 Hz in awake rats) and gamma (50-100 Hz) frequency ranges are prominent in field potentials induced by odorants in the mammalian olfactory bulb (OB) and piriform cortex (PC). Whereas the gamma oscillation has been studied for >50 yr, the beta oscillation has attracted attention only recently, and its origin, mechanism, and relationship to gamma are unknown. To address these questions, we have examined responses induced by odorants in the urethane-anesthetized rat-a preparation well-suited for the analysis of mechanisms. We found that both oscillations could be induced by odorants in a concentration-dependent manner. Analysis with a concentration series and spectral methods revealed that the beta and gamma oscillations were distinct and not harmonically related, indicating generation by independent mechanisms. The beta oscillation was synchronous at sites < or =4 mm apart in the OB, the greatest distance tested. In contrast, the gamma oscillation was synchronous in some experiments and asynchronous in others (frequency differed slightly at different sites, resulting in progressive phase shifts). Current source-density analysis indicated that, for both oscillations, the field potentials in the OB were generated by synaptic currents in granule cells. The two oscillations were differently affected by surgical interruption of the lateral olfactory tract. This lesion abolished the beta oscillation, whereas the gamma oscillation was still induced in the OB. Our results confirm previous reports that the gamma oscillation is generated within the OB but indicate that the beta oscillation requires the participation of PC.

Odor-evoked activity is spatially distributed in piriform cortex.

Much data on the olfactory bulb (OB) indicates that structural characteristics of odorant molecules are encoded as ordered, spatially consolidated sets of active cells. New results with "genetic tracing" (Zou et al. [2001] Nature 414:173-179) suggest that spatial order is also present in projections from the OB to the olfactory cortex. For the piriform cortex (PC), results with this technique indicate that afferents conveying input derived from single olfactory receptors (ORs) are distributed to well-defined patches in the anterior PC (APC) but that these patches are much larger than in the OB. We have used c-fos induction to examine how input patterning for single ORs is translated into patterns of odor-evoked cellular activity in the PC. The laminar distribution of labeled cells and dual-immunostaining for gamma-aminobutyric acid (GABA)ergic markers indicated that activity was detected largely in pyramidal cells. In odor-stimulated rats, labeled cells were present throughout the posterior PC (PPC) but were concentrated in prominent rostrocaudal bands in APC. Analysis of responses to different odorants and concentrations revealed that locations and shapes of bands conveyed no apparent information regarding odor quality, rather, they appeared to correspond to subregions of the APC distinguished by cytoarchitecture and connectivity. Small-scale variations in labeling density were observed within APC bands and throughout the PPC that could reflect the presence of a complex topographical order, but discrete patches at consistent locations as observed by genetic tracing were absent. This finding suggests that as a result of afferent overlap and intracortical processing, odor-quality information is represented by spatially distributed sets of cells. A distributed organization may be optimal for discriminating biologically relevant odorants that activate large numbers of ORs.