J. F. M. van Brederode

Distribution of the calcium-binding proteins parvalbumin and calbindin-D28k in the sensorimotor cortex of the rat

This study examined and compared the immunocytochemical distribution of the two calcium-binding proteins parvalbumin and calbindin-D28k in the primary motor and somatosensory areas of the rat neocortex. Parvalbumin-immunoreactive cells were found in all layers of the cortex except layer 1 and reached their peak density in the middle layers. The two cortical areas differed markedly in the number, cell size and morphology of immunoreactive cells. Parvalbumin-positive cells were more than twice as numerous in the somatosensory cortex compared to the motor cortex. In addition, the average size of their cell bodies was 25-30% larger in the somatosensory area. Parvalbumin cells in the motor area represented several classes of nonpyramidal cells, while the somatosensory cortex contained in addition many large cells with thick vertically oriented primary dendrites. Some of these cells resembled regular or inverted pyramidal neurons. Punctate neuropil labeling was much heavier in the upper layers of the somatosensory than in the motor cortex and was especially heavy in layer 4. Dense parvalbumin-positive perisomatic puncta surrounded large, unstained pyramidal cells in layer 5B of the motor cortex. Calbindin-D28k neuronal staining in both areas was confined to two populations. The most prominent was darkly labeled, small nonpyramidal cells confined to two bands in layers 2/3 and 5/6. There was also a lighter stained population composed of many pyramidal cells distributed throughout layers 2 and 3. In addition, the motor area contained a band of lightly stained, large pyramidal cells in layer 5B. Calbindin-D28k neuropil labeling was heaviest in layers 1 to 3. In contrast to parvalbumin, we found only minor differences in distribution, size and morphology of calbindin-D28k cell body or neuropil staining in the two cortical areas. Double-labeling immunocytochemistry showed that the large majority of immunoreactive cells contained only calbindin-D28k or parvalbumin, but a distinct population of multipolar cells in the upper layers of the somatosensory cortex contained both. The clear parcellation of parvalbumin immunoreactivity in the rat neocortex suggests that parvalbumin is preferentially associated with specific neuronal populations and terminals in the somatosensory cortex. The more general and homogeneous labeling of the upper layers of the cortex indicates that calbindin-D28k could be related to the relatively high density of calcium channels or N-methyl-D-aspartate receptors in the superficial layers of the rat cortex.

Transient co-localization of calretinin, parvalbumin, and calbindin-D28k in developing visual cortex of monkey

SummaryThis paper reports a double-labelling immunocytochemical study of the three calcium-binding proteins calretinin, parvalbumin, and calbindin-D28k in developing and adultMacaca primary visual cortex. In adult visual cortex, each protein marks a subset of GABAergic neurons with a characteristic laminar distribution and virtually no co-localization was found between these three proteins, suggesting that each calcium-binding protein may serve as a marker for one or more cortical subcircuits. The immature visual cortex, immunostained using identical techniques was then analysed to determine if each calcium-binding protein could serve as a developmental marker for these circuits. The Cajal-Retzius cells of layer 1 contained all three proteins during development. Calbindin-D28k and calretinin were co-localized starting at Fd (foetal day) 45 and after Fdl25, parvalbumin also was present in the same Cajal-Retzius cells. All three proteins continued to be expressed until the Cajal-Retzius disappeared postnatally. In layers 2–6 calbindin-D28k and calretinin were never co-localized. In contrast, parvalbumin and calretinin were found in neurons of deep layer 3 from Fd 155 to postnatal (P6) weeks with a few persisting even later. Before birth almost all PV+ neurons in layers 4–6 were CaB+, but by P3 weeks only a few PV+/CaB+ neurons remained in layer 4C and these completely disappeared by P6 weeks. Co-localization in layer 4 neurons overlaps the period of ocular dominance segregation, suggesting that the onset of cortical maturity coincides with segregation of calcium-binding proteins within the GABA interneurons.

The lectin Vicia villosa labels a distinct subset of GABAergic cells in macaque visual cortex.

The morphology and distribution of neurons labeled specifically by the lectin, Vicia villosa (VVA), were examined in striate cortex of adult macaque monkeys. Following incubation with VVA conjugated to histochemical markers, fine punctate reaction product appears to cover the surface of the soma and proximal dendrites of a population of cortical neurons. Although a small number of VVA-labeled cells are located in layers 2, 3A, 5, and 6, approximately 75% are located in a strip of cortex overlying layers 3B through 4Ca. Layers 1 and 4C beta are virtually devoid of labeled cells. The morphology of labeled cells varies throughout the layers. In the supragranular layers, the labeled cells generally display a round or multipolar soma with a small number of radially disposed dendrites. In deeper layers, labeled cells are multipolar or horizontal, and their proximal dendrites are often more densely labeled. There is no clear correlation between the distribution of labeled cells and the pattern of cytochrome oxidase staining in supragranular layers. Double labeling of single sections for VVA and for GABA (gamma-aminobutyric acid) immunoreactivity revealed that most VVA-labeled cells are also immunoreactive for GABA. The double-labeled cells comprise approximately 30% of all GABA immunoreactive cells. Soma size analysis of double-labeled cells shows that medium-to-large GABA cells in each layer are labeled by VVA. The soma size, laminar distribution, and morphology of the VVA-labeled GABA cells suggest that they include the large basket cells originally observed in Golgi preparations.

Evidence of altered inhibition in layer V pyramidal neurons from neocortex of Kcna1-null mice.

Mice lacking the potassium channel subunit KCNA1 exhibit a severe epileptic phenotype beginning at an early postnatal age. The precise cellular physiological substrates for these seizures are unclear, as is the site of origin. Since KCNA1 mRNA in normal mice is expressed in the neocortex, we asked whether neurons in the neocortex of three to four week-old Kcna1-null mutants exhibit evidence of hyperexcitability. Layer V pyramidal neurons were directly visualized in brain slices with infrared differential-interference contrast microscopy and evaluated with cellular electrophysiological techniques. There were no significant differences in intrinsic membrane properties and action potential shape between Kcna1-null and wild-type mice, consistent with previous findings in hippocampal slice recordings. However, the frequency of spontaneous post-synaptic currents was significantly higher in Kcna1-null compared to wild-type mice. The frequency of spontaneous inhibitory post-synaptic currents and miniature (action-potential-independent) inhibitory post-synaptic currents was also significantly higher in Kcna1-null compared to wild-type mice. However, the frequency of spontaneous and miniature excitatory post-synaptic currents was not different in these two groups of animals. Comparison of the amplitude and kinetics of miniature inhibitory and excitatory post-synaptic currents revealed differences in amplitude, rise time and half-width between Kcna1-null and wild-type mice. Our data indicate that the inhibitory drive onto layer V pyramidal neurons is increased in Kcna1 knockout mice, either directly through an increased spontaneous release of GABA from presynaptic terminals contacting layer V pyramidal neurons, or an enhanced excitatory synaptic input to inhibitory interneurons.

Morphological and electrophysiological properties of atypically oriented layer 2 pyramidal cells of the juvenile rat neocortex

We used whole-cell patch clamp recordings combined with intracellular dye-filling to examine the morphological and electrophysiological properties of atypically oriented pyramidal cells located at the layer 1/2 border of the juvenile rat neocortex. Orientation of the apical dendrite varied from oblique (>20 degrees from vertical) to truly horizontal (90 degrees from vertical). The length of the apical dendrite ranged from 150 to 400 microm. The total horizontal domain of the dendritic tree (including basal dendrites) of the longest horizontal pyramids exceeded 500 microm, but we also found short horizontal cells with horizontal dendritic domains of less than 300 microm. In addition, atypically oriented pyramids had long horizontal axon collaterals in layer 1/2. Electrophysiologically, atypically oriented pyramidal cells had intrinsic membrane properties similar to regularly oriented pyramids that have been described in the superficial layers at this age in the rat. Cells that fired repetitively were all regular spiking. In addition, we identified a subgroup of neurons (20%) in this sample, which were unable to fire more than a few spikes at the beginning of the current pulse. We suggest that the unique orientation and size of their dendritic trees and the length and arrangement of their local axons collaterals make atypically oriented pyramids in layer 2 ideally suited to perform horizontal integration of synaptic inputs in the neocortex.

GAD67-GFP+ Neurons in the Nucleus of Roller: A Possible Source of Inhibitory Input to Hypoglossal Motoneurons. I. Morphology and Firing Properties

In this study we examined the electrophysiological and morphological properties of inhibitory neurons located just ventrolateral to the hypoglossal motor (XII) nucleus in the Nucleus of Roller (NR). In vitro experiments were performed on medullary slices derived from postnatal day 5 (P5) to P15 GAD67-GFP knock-in mouse pups. on cell recordings from GFP+ cells in NR in rhythmic slices revealed that these neurons are spontaneously active, although their spiking activity does not exhibit inspiratory phase modulation. Morphologically, GFP+ cells were bi- or multipolar cells with small- to medium-sized cell bodies and small dendritic trees that were often oriented parallel to the border of the XII nucleus. GFP+ cells were classified as either tonic or phasic based on their firing responses to depolarizing step current stimulation in whole cell current clamp. Tonic GFP+ cells fired a regular train of action potentials (APs) throughout the duration of the pulse and often showed rebound spikes after a hyperpolarizing step. In contrast, phasic GFP+ neurons did not fire throughout the depolarizing current step but instead fired fewer than four APs at the onset of the pulse or fired multiple APs, but only after a marked delay. Phasic cells had a significantly smaller input resistance and shorter membrane time constant than tonic GFP+ cells. In addition, phasic GFP+ cells differed from tonic cells in the shape and time course of their spike afterpotentials, the minimum firing frequency at threshold current amplitude, and the slope of their current-frequency relationship. These results suggest that GABAergic neurons in the NR are morphologically and electrophysiologically heterogeneous cells that could provide tonic inhibitory synaptic input to HMs.

Lack of an endogenous GABAA receptor‐mediated tonic current in hypoglossal motoneurons

•  Tonic GABAA receptor‐mediated currents have profound effects on neuronal excitability, yet it is not known whether this current is present in mammalian motoneurons. •  This study shows that tonic GABAA receptor‐mediated current can be observed in hypoglossal motoneurons in vitro under certain experimental conditions. •  The tonic current was only observed when exogenous GABA was applied and GABA transporters were blocked suggesting that GABA transporters highly regulate extracellular GABA concentration. •  Furthermore, we demonstrate that the current probably arises from activation of extrasynaptic GABAA receptors containing a δ subunit. •  This tonic current may function to reduce the excitability of hypoglossal motoneurons; these motoneurons are important in many functions including chewing, swallowing, suckling, vocalization and upper airway patency.

VVA-labelled cells in monkey visual cortex are double-labelled by a polyclonal antibody to a cell surface epitope

SummaryThe staining patterns produced by the lectinVicia villosa and by a commercially available polyclonal antibody generated to substance P were analysed and compared in monkey visual cortex at the light and electron microscopic levels.Vicia villosa lectin labels the cell surface of a subpopulation of cortical cells, producing a meshlike pattern over the soma and proximal dendrites. The polyclonal antibody labels three distinct elements in the cortex: a pericellular epitope present on a subpopulation of non-pyramidal cells, and putative intracellular sites in a type of small pyramidal cell located at the layer 5/6 border, and in a small number of non-pyramidal cells in the underlying white matter. Because of the similarity of the appearance of theVicia villosa lectin labelling and the pericellular labelling produced by the polyclonal antibody, further experiments were conducted to determine the relationship between the cell surface sites recognized by these markers. Double-labelling experiments show that both sites are present on the same population of cells, and at the ultrastructural level both markers appear to outline the intersynaptic cell membrane, sometimes extending around presynaptic elements. However, preadsorption experiments indicate that the markers recognize different sites on the cell membrane. Preadsorption experiments also show that the pericellular epitope recognized by the polyclonal antibody is unlikely to be substance P, but it may be structurally similar to keyhole limpet haemocyanin. Comparison of cortical and subcortical staining patterns produced with the polyclonal antibody and with a commonly used monoclonal antibody to substance P reveal that one of the putative intracellular epitopes recognized by the polyclonal antibody is likely to be substance P.

Retinal influences induce bidirectional changes in the kinetics of N-methyl-D-aspartate receptor-mediated responses in striate cortex cells during postnatal development.

Development of the visual callosal projection in rodents goes through an early critical period, from postnatal day (P) 4 to P6, during which retinal input specifies the blueprint for normal topographic connections, and a subsequent period of progressive pathway maturation that is largely complete by the time the eyes open, around P13. This study tests the hypothesis that these developmental stages correlate with age-related changes in the kinetics of synaptic responses mediated by the N-methyl-D-aspartate subclass of glutamate receptors (NMDARs). We used an in vitro slice preparation to perform whole-cell recordings from retrogradely-labeled visual callosal cells, as well from cortical cells with unknown projections. We analyzed age-related changes in the decay time constant of evoked as well as spontaneous excitatory postsynaptic currents mediated by N-methyl-D-aspartate subclass of glutamate receptors (NMDAR-EPSCs) in slices from normal pups and pups enucleated at different postnatal ages. In normal pups we found that the decay time constant of NMDAR-EPSCs increases starting at about P6 and decreases by about P13. In contrast, these changes were not observed in rats enucleated at birth. However, by delaying the age at which enucleation was performed we found that the presence of the eyes until P6, but not until P4, is sufficient for inducing slow NMDAR-EPSC kinetics during the second postnatal week, as observed in normal pups. These results provide evidence that the eyes exert a bidirectional effect on the kinetics of NMDARs: during a P4-P6 critical period, retinal influences induce processes that slow down the kinetics of NMDAR-EPSCs, while, near the age of eye opening, retinal input induces a sudden acceleration of NMDAR-EPSC kinetics. These findings suggest that the retinally-driven processes that specify normal callosal topography during the P4-P6 time window also induce an increase in the decay time constant of NMDAR-EPSCs. This increase in response kinetics may play an important role in the maturation of cortical topographic maps after P6. Using ifenprodil, a noncompetitive NR2B-selective blocker, we obtained evidence that although NR1/NR2B diheteromeric receptors contribute to evoked synaptic responses in both normal and enucleated animals, they are not primarily responsible for either the age-related changes in the kinetics of NMDAR-mediated responses, or the effects that bilateral enucleation has on the kinetics of NMDAR-EPSCs.

Differences in Synaptic Input and Excitability Between Superficial and Deep Pyramidal Cells in the Cat Sensorimotor Cortex

In this study we recorded stimulus-evoked intracellular synaptic potentials in superficial and deep pyramidal neurons of the cat sensorimotor cortex. All cells studied received non-NMDA receptor-mediated fast depolarizing excitation, while some deep pyramidal cells also showed a slower NMDA-mediated input. Superficial pyramidal cells showed a triphasic response characterized by both fast and slow hyperpolarizing inhibition. The latter response was absent in deep pyramidal cells. These results suggest that pyramidal cells from different cortical layers receive different types of synaptic input. These differences are likely to have consequences for the way excitatory and inhibitory inputs interact and the kind of operations that can be performed by cortical neurons.