Activity-Dependent Regulation of NMDAR1 Immunoreactivity in the Developing Visual Cortex

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (60)

Citing Articles via Google Scholar

Google Scholar

Articles by Catalano, S. M.

Articles by Shatz, C. J.

Search for Related Content

PubMed

PubMed Citation

Articles by Catalano, S. M.

Articles by Shatz, C. J.

Previous Article  |  Next Article

Volume 17, Number 21, Issue of November 1, 1997 pp. 8376-8390
Copyright ©1997 Society for Neuroscience

Activity-Dependent Regulation of NMDAR1 Immunoreactivity in the Developing Visual Cortex

Susan M. Catalano, Catherine K. Chang, and Carla J. Shatz
Howard Hughes Medical Institute and Department of Molecular and Cell Biology, University of California, Berkeley, California 94720

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

NMDA receptors have been implicated in activity-dependent synaptic plasticity in the developing visual cortex. We examinedthe distribution of immunocytochemically detectable NMDAR1 invisual cortex of cats and ferrets from late embryonic ages toadulthood. Cortical neurons are initially highly immunostained.This level declines gradually over development, with the notableexception of cortical layers 2/3, where levels of NMDAR1 immunostainingremain high into adulthood. Within layer 4, the decline in NMDAR1immunostaining to adult levels coincides with the completion ofocular dominance column formation and the end of the criticalperiod for layer 4. To determine whether NMDAR1 immunoreactivityis regulated by retinal activity, animals were dark-reared orretinal activity was completely blocked in one eye with tetrodotoxin(TTX). Dark-rearing does not cause detectable changes in NMDAR1immunoreactivity. However, 2 weeks of monocular TTX administrationdecreases NMDAR1 immunoreactivity in layer 4 of the columns ofthe blocked eye. Thus, high levels of NMDAR1 immunostaining withinthe visual cortex are temporally correlated with ocular dominancecolumn formation and developmental plasticity; the persistenceof staining in layers 2/3 also correlates with the physiologicalplasticity present in these layers in the adult. In addition,visual experience is not required for the developmental changesin the laminar pattern of NMDAR1 levels, but the presence of highlevels of NMDAR1 in layer 4 during the critical period does requireretinal activity. These observations are consistent with a centralrole for NMDA receptors in promoting and ultimately limiting synapticrearrangements in the developing neocortex.
Key words: NMDAR1; activity-dependent; visual cortex; development; critical period; plasticity

INTRODUCTION

Neural activity is required for pattern formation and synaptic plasticity in neocortex (Katz and Shatz, 1996). During thesegregation of geniculocortical axons to form ocular dominancecolumns in development, monocular deprivation causes a functionaland anatomical expansion of the open eye's cortical territory(Hubel et al., 1977; Shatz and Stryker, 1978; Stryker and Harris,1986; Antonini and Stryker, 1993a), whereas eliminating all retinalactivity in both eyes prevents column formation (Stryker and Harris,1986). The formation of highly specific horizontal connectionsbetween orientation-specific domains in layers 2/3 also requiresvisual experience (Callaway and Katz, 1991; Ruthazer and Stryker,1996).

NMDA receptors are thought to be involved in mediating activity-dependent synaptic plasticity in the developing CNS (Fox andDaw, 1993; Bear, 1996). The physiological shift toward the openeye that occurs in monocularly deprived animals can be blockedby cortical APV infusion (Kleinschmidt et al., 1987; Gu et al.,1989; Bear et al., 1990). The shrinkage of LGN cells related tothe deprived eye is also blocked by APV infusion (Bear and Colman,1990). In frog optic tectum, infusion of APV initiates desegregationof eye-specific stripes (Cline and Constantine-Paton, 1990). Thesegregation of on-off sublaminae in ferret LGN is prevented byAPV infusion (Hahm et al., 1991). APV infusion into neonatal ratsomatosensory cortex alters both somatotopic rearrangements resultingfrom peripheral manipulations and physiological organization withinlayer 4 (Schlaggar et al., 1993; Fox et al., 1996). Finally, micelacking the NMDAR1 subunit fail to exhibit the whisker-relatedbarreloid pattern normally present in the trigeminal brainstemnuclei at birth (Li et al., 1994; Iwasato et al., 1997). Theseobservations suggest that NMDA receptors play a crucial role inanatomical and physiological activity-dependent pattern formationand plasticity during development.

Physiological evidence suggests that there is a developmental regulation of NMDA receptors coincident with periods of corticalplasticity (such as ocular dominance column formation) and thatthis regulation itself may be activity-dependent. In cat visualcortex, the percentage of the visual response of individual neuronsthat is NMDAR-mediated decreases between 3 and 6 weeks of age;dark-rearing prevents this decrease (Fox et al., 1989, 1991, 1992).One possible mechanism that might underlie the decrease in NMDA-mediatedresponses is a change in NMDA receptor kinetics. For instance,in rat visual cortex, the duration of the NMDA-mediated EPSC decreasesduring development, and dark-rearing prevents this decrease (Carmignotoand Vicini, 1992). This decrease could be caused by a shift inNMDA receptor subunit expression (Sheng et al., 1994; Flint etal., 1997). Another possibility, not mutually exclusive, is thatthe levels of NMDA receptors themselves change during developmentin association with periods of cortical plasticity. A number ofrecent studies suggest that NMDA receptors are regulated at thepost-transcriptional rather than the mRNA level (Sucher et al.,1993; Gazzaley et al., 1996). To investigate these possibilities,we examined the distribution of NMDA receptors during developmentusing an antibody directed against the R1 subunit. This subunitis essential for NMDA receptor function (Moriyoshi et al., 1991;Monyer et al., 1992; Nakanishi, 1992). We also examined whetherNMDAR1 levels are regulated in an activity-dependent manner byraising animals in the dark or blocking activity in one eye withtetrodotoxin (TTX) injections.

MATERIALS AND METHODS
Immunocytochemistry. A total of 27 normal ferrets ranging in age from embryonic day (E) 30 to adulthood and 32 normal catsfrom E42 through adult were studied. Additional cats were examinedafter dark-rearing (n = 7), dark-rearing followed by brief reexposureto light (n = 3), or monocular injections of TTX (n = 3). Onemonoclonal antibody (clone 54.1; PharMingen, San Diego, CA) andthree polyclonal antibodies (Chemicon, Temecula, CA; gift of Dr.M. Sheng, Howard Hughes Medical Institute Massachusetts GeneralHospital; gift of Dr. T. Dawson, Johns Hopkins University Schoolof Medicine) raised against different epitopes in the rat sequenceof the NMDAR1 subunit were assessed for their ability to staincat and ferret tissue and for specificity of staining. Antibodystaining of Western blots (see below) and tissue sections of cat,ferret, and NMDAR1 knock-out mouse brain were examined. Only themonoclonal antibody from PharMingen specifically recognized NMDAR1in cat and ferret tissue. This antibody was raised against a fusionprotein corresponding to the extracellular loop between transmembranedomains III and IV (Brose et al., 1994) of NMDAR1, a region thatis 100% homologous between mouse and human. This high degree ofconservation suggests that the carnivore and mustelid sequencesare likely to be similar in this region and probably underliesthe successful staining of cat and ferret tissue, as describedin Results.

Fetal ages were determined by timed breedings as described previously (Luskin and Shatz, 1985a); gestation is ~42 d in ferretand 65 d in cat. Timed pregnant ferrets were obtained from MarshallFarms (North Rose, NY). Fetuses were anesthetized transplacentallythrough maternal anesthesia with an isofluorane/O₂ mixture. Postnatalanimals were anesthetized deeply with sodium pentobarbitol (50mg/kg) injected intraperitoneally. Animals were perfused transcardiallywith 0.1 M sodium phosphate buffer followed by fresh 4% paraformaldehydein the same buffer. Brains were dissected and cryoprotected in30% sucrose in 0.1 M sodium phosphate buffer overnight at 4°C.

Frozen sections were cut at 30-40 µm on a sliding microtome, and free-floating sections were washed with PBS (0.1 M sodiumphosphate buffer, 0.9% NaCl, pH 7.4), blocked in normal horseserum (NHS) (Vector, Burlingame, CA) at a concentration of 5%in PBS for 1 hr, and then incubated overnight in primary antibody(1:500 or 1:50 in 1% NHS) (PharMingen). All reactions were performedat room temperature; primary, secondary, and avidin-biotin incubationswere performed with mild agitation, and washes were 3 × 10 minin PBS. Sections were incubated with biotin-coupled secondaryantibody and then avidin-HRP conjugate and reacted with DAB accordingto the Vector ABC kit protocol (Vector). All sections were developedfor the same time in DAB. The reaction was stopped by washing3 × 3 min in PBS. Sections were mounted onto slides from a gelatinsolution, dehydrated with alcohol, and coverslipped with Permount.

Controls included incubation of the sections (1) omitting primary antibody, (2) substituting generic mouse IgG protein atan equivalent concentration to the primary antibody, and (3) adsorptionof the primary antibody with the fusion protein immunogen (Kopkeet al., 1993). We would like to thank Dr. A. Kopke (Departmentof Molecular Neuroendocrinology, Max Planck Institute for ExperimentalMedicine, Gottingen, Germany) for his generous gift of fusionprotein.

Western analysis. Synaptic plasma membranes of rat, cat, and ferret neocortex and cell membranes of ferret liver were prepared(Brose et al., 1990), and constituent proteins were resolved by9% SDS-PAGE gels under reducing conditions (5 µg total protein/lane).Proteins were immobilized on nitrocellulose membranes (HybondECL), and blots were blocked for 1 hr at room temperature in PBSwith 5% nonfat dry milk, 5% normal donkey serum, and 0.1% Tween20 and then incubated with primary antibody at a concentrationof 1:500 in PBS with 5% nonfat dry milk, 0.1% Tween 20, and 3%bovine serum albumin (BSA) (Sigma, St. Louis, MO) overnight at4°C. Blots were then washed 4 × 15 min in PBS with 0.1% Tween20 and then incubated in secondary antibody [HRP-conjugated donkeyanti-mouse 1:8000 (Jackson ImmunoResearch, West Grove, PA)] inPBS with 0.1% Tween 20, 0.1% BSA, and 5% NHS, and then washed1 × 5 min in Tris-buffered saline (TBS) (0.1 M Tris with 0.9%NaCl, pH 7.4), 2 × 5 min in TBS with 1% Triton X-100, 1% SDS,0.5% deoxycholic acid in TBS, and then 2 × 5 min in PBS with 0.1%Tween 20. Antibody was then visualized by enhanced chemiluminescence(Amersham, Arlington Heights, IL). As a control, the primary antibodywas preadsorbed with NMDAR1 fusion protein (Kopke et al., 1993).

Dark-rearing. Animals housed in conventional cat racks (2 feet × 4 feet) with their mothers were placed in a completely light-tightroom in total darkness within 3-4 d of birth (1 week before eyeopening). A total of seven cats were raised in complete darknessuntil they were killed (to P15, n = 1; P28, n = 1; P34, n = 1;P53, n = 2; P103, n = 2). We also studied two animals that wereraised in the dark until P53 and then reexposed to light (onefor 4 d, the other for 10 d) as well as one animal raised in thedark until P103 and then reexposed to light for 10 d. A contact-activatedelectric switch on the entrance to the dark-rearing room ensuredthat no accidental exposure to light could occur. Additionally,light within the room was monitored with photocells wired to arecording machine (Angus Electronics, Indianapolis, IN) that gavea continuous readout; no light was detected in the dark-rearingroom for the duration of this study. No changes in configurationof cage items such as food bowls and perches were made once theanimals were placed in the dark. An auto-reverse tape player providedan enriched auditory environment for 8-12 hr per day. Motherswere permitted to exercise in a lighted anteroom each day forat least 15 min. Animal care and feeding were performed by visuallymonitoring animals using an infrared headset. A registered veterinarytechnician checked the health of the kittens each day. Kittenweight gain was monitored every third day for the first threeweeks of life and then weekly until the animals were removed fromthe colony. No clinical health problems were observed in any ofthe animals raised in this environment. Animals reintroduced intothe light in identically configured cages did not show signs ofdistress.

TTX eye injections. P40 kittens were anesthetized with isofluorane and injected monocularly with either a sterile solutionof 3 mM TTX (Calbiochem, La Jolla, CA) in 18.6 mM citric acid-sodiumcitrate buffer, pH 4.8 (n = 2), or vehicle alone (n = 1). Injectionswere continued every other day for 2 weeks (dose 4-5 µl at P40,increasing gradually to 7.5-9 µl by 2 weeks). The absence of directand consensual pupillary response to light was taken as an indicationof effective TTX blockade of visual responses (Stryker and Harris,1986) and was monitored hourly for the first 3 hr after injectionand at least three times a day thereafter.

Image analysis. Digital images of immunostained tissue sections were acquired using a VE1000 video camera (Dage-MTI, MichiganCity, IN), allowing immunostaining intensity to be quantifiedin units of pixel gray scale value (8 bit). We measured the periodicvariation in NMDAR1 immunostaining intensity in layer 4 in themonocularly TTX-injected, citrate-injected, and normal age-matchedanimals in a direction parallel to the cortical surface (see Fig.9). A region within layer 4 measuring 2.5 mm long by 0.23 mm thick(long axis parallel to the pia) was sampled. This region coveredalmost all of the thickness of layer 4, as determined by inspectionof adjacent sections counterstained with cresyl violet. The averageimmunostaining intensity was averaged over each line of pixelsextending vertically through layer 4, and these average valueswere plotted as a function of distance along the length of layer4 parallel to the pia (National Institutes of Health Image). Thisplot was smoothed by averaging each value with its four nearestneighbors, and the resulting values are presented in Figure 9.This method was designed to be similar to the analysis used byLeVay et al. (1978) to determine the degree of ocular dominancecolumn segregation in layer 4 during development.
Fig. 9. Periodic fluctuations in NMDAR1 immunostaining intensity occur within layer 4 of two animals monocularly injected with TTXfrom P40-53 (A, B). No such fluctuations are present within layer4 of control citrate buffer-injected (C) or normal (D) age-matchedanimals, or within layers 2/3 and 6 of the TTX-injected animalshown in A (E) (see Materials and Methods for details).
[View Larger Version of this Image (25K GIF file)]

To compare relative levels of immunostaining across ages and different experimental conditions (see Fig. 10), the ratio ofthe average staining in layers 2/3 to the average staining inlayer 4 for a given animal was obtained in the following manner.The average immunostaining intensity in layers 2/3 was calculatedfrom pixel gray values in a region of the digitized images measuring0.25 mm in length (tangential to the pia) by 0.20 mm through thevertical dimension of cortex. This region was entirely confinedto layers 2/3 by comparison with adjacent Nissl-stained sections.Then the average immunostaining intensity in layer 4 was calculatedfrom an identically sized sample taken from a region of layer4 that was located immediately underneath the layers 2/3 samplein the same tissue section. The ratio of this pair of averagestaining values was then obtained. This procedure was repeatedfor 16 samples (eight pairs of samples), equivalent to 1.6 mm² of cortical area across tissue sections from a given animal.The ratio values from a given animal were then averaged and plottedin Figure 10. In the case of the TTX-treated animals, the sampleareas were taken from regions of maximal and minimal immunostainingin layer 4 as determined visually.
Fig. 10. Ratio of layers 2/3/layer 4 NMDAR1 immunostaining intensity compared across ages and experimental conditions in cats (±SD).Average immunostaining levels were calculated for each layer fromdigitized images, and ratios were determined. A, Comparison ofdevelopmental changes in the ratios for normally reared or dark-rearedanimals. Layers 2/3 are consistently darker than layer 4 at mostages except between P34 and 53, when the two layers are equivalentin intensity (A). There is no significant difference in immunostainingratios between normal animals and age-matched dark-reared animalsor dark-reared animals exposed to light. B, Ratios for normallyreared and monocularly TTX-treated cases shown in histogram form.Immunostaining intensity ratios do not vary significantly betweennormal P53 animals and control animals receiving monocular injectionsof citrate between P40 and P53 (p < 0.15) (B) or from the columnspertaining to the unblocked eye (p < 0.005). However, note thatimmunostaining ratios obtained from the columns of the TTX-injectedeye are significantly greater than those from normal animals (p< 0.00005; two-tailed t test).
[View Larger Version of this Image (18K GIF file)]

RESULTS
NMDAR1 subunit protein was detected immunocytochemically in the visual cortex of cats and ferrets. We examined the periodof development beginning at a time in fetal life before LGN axonshave grown into the visual cortical plate (E30 ferret, E42 cat)(Ghosh and Shatz, 1992) through the period of ocular dominancecolumn formation [cat P21-42 (LeVay et al., 1978) and ferret P36-49(Ruthazer et al., 1995; E. Finney and C.J. Shatz, unpublishedobservations)], through the critical period when abnormal experiencecan alter geniculocortical connectivity within layer 4, to adulthood.We then compared the immunocytochemical localization of NMDAR1of normal cats to that of age-matched animals raised in the darkfrom birth and animals in which retinal activity had been blockedfor 2 weeks by monocular injections of TTX. Finally, we comparedthe immunocytochemical localization of NMDAR1 in developing visualcortex with that of other nonvisual cortical areas.

Antibody specificity
Western analysis indicates that the monoclonal anti-NMDAR1 antibody (PharMingen 54.1) recognizes a band of the same molecularweight as NMDAR1 (M_r ~117 kDa) in synaptic plasma membranes preparedfrom rat, cat, and ferret brains (Fig. 1A1). This band is absentin membranes prepared from ferret liver (Fig. 1A1) or when theprimary antibody is preadsorbed with the NMDAR1 fusion protein(Fig. 1A2) or omitted (Fig. 1A3). To examine the specificity ofantibody staining, tissue sections stained with anti-NMDAR1 (Fig.1B1) were compared with sections incubated in either primary antibodypreadsorbed with the NMDAR1 fusion protein (Fig. 1B2) or nonimmunemouse IgG (Fig. 1B3). When the primary antibody is preadsorbedto the fusion protein against which it was raised, cellular stainingis absent (Fig. 1B2), indicating that the NMDAR1 epitope on thefusion protein can compete for binding of the primary antibodyin tissue sections. In sections incubated with mouse IgG (Fig.1B3), cellular staining is also absent. These two immunocytochemistrycontrols indicate that the immunostaining observed in tissue sectionswith the anti-NMDAR1 antibody is not caused by nonspecific bindingof either the primary or secondary antibody. Taken together, thisevidence strongly suggests that the anti-NMDAR1 antibody selectivelyrecognizes the R1 subunit of the NMDA receptor.
Fig. 1. A, Western blots show that the monoclonal antibody recognizes a band of the same molecular weight as NMDAR1. A1, Stainingof rat (R), ferret (F), and cat (C) synaptic plasma membranesand ferret liver membranes (L) with the primary anti-NMDAR1 antibodyyields a prominent band at M_r ~117 kDa. This band is no longerstained when the primary antibody is preadsorbed to its fusionprotein immunogen (A2), or omitted (A3). B, Controls for the specificityof NMDAR1 antibody immunostaining on tissue sections. Cellularstaining is intense in sections that have been incubated in primaryantibody (B1); however, preadsorbtion of the primary antibodywith the fusion protein that it was raised against (B2) or substitutionof the primary antibody with generic IgG protein from the samespecies as the primary (mouse IgG) (B3) protein results in thenear-absence of cellular staining. Scale bar (B1-3): 300 µm.
[View Larger Version of this Image (57K GIF file)]

Developmental changes in pattern of protein expression
In ferret visual cortex, immunocytochemically detectable NMDAR1 is located in specific cellular compartments in the developingcerebral wall (Fig. 2). At 35 d of gestation (E35; birth is onE41-42), fibers within the marginal zone (future layer 1) andthe intermediate zone (future white matter) are immunostained(Fig. 2A). There was no detectable immunostaining of migratingneurons in the intermediate zone; however, the dense corticalplate, which contains neurons that are immediately postmigratory,is immunopositive. Subplate neurons, which are among the earliestcells of the cortex to be generated and thus to differentiate,are the first neurons of the cortex to exhibit intense NMDAR1immunoreactivity (Fig. 2A,B). By P3 (Fig. 2C), neurons withinlayer 6 have begun to differentiate from the dense cortical plateand are as intensely immunostained as the subplate neurons. Thedense cortical plate (which at this age contains neurons belongingto future layers 5 and 4) (Jackson et al., 1989) itself is alsoimmunoreactive. By P20, (Fig. 2D) all of the cortical layers havedifferentiated. Immunoreactivity within layers 4 and 6 has declined,but that of layers 2/3 and 5 remains relatively intense. By P49(Fig. 2E), NMDAR1 immunoreactivity in layer 5 has declined andis similar to that of layer 6. In contrast, immunostaining inlayer 4 has increased and is similar to that of layers 2/3. Layer1 is no longer immunoreactive. By P84 (Fig. 2F) and in adulthood(Fig. 2G), immunostaining in layer 4 has declined and is now similarto that seen in the lower cortical layers 5 and 6. Immunoreactivityremains relatively intense in the upper cortical layers 2/3.
Fig. 2. The pattern of NMDAR1 immunoreactivity during the development of the ferret visual cortex at E35 (A, B), P3 (C), P20 (D),P49 (E), P84 (F), and Adult (G). Laminar boundaries are indicatedby horizontal bars. CP, Cortical plate; SP, subplate; IZ, intermediatezone; VZ, ventricular zone; 1-6, cortical layers 1-6. Scale bar(bottom left in E): A, C, D, 110 µm; B, 55 µm; E-G, 200 µm.
[View Larger Version of this Image (147K GIF file)]

From these observations, a general pattern of developmental regulation of immunocytochemically detectable NMDAR1 in ferretvisual cortex can be discerned. Neurons exhibit intense immunoreactivityshortly after becoming postmigratory, and this level of immunoreactivitydeclines gradually over development. The exceptions to this arelayers 2/3, which remain intensely immunoreactive throughout developmentinto adulthood, and layer 4, which exhibits a more complex patternof staining: after the initial decline in immunoreactivity, thereis a subsequent increase in the level of NMDAR1 immunostainingin layer 4, followed by a second period of decline in immunoreactivity.

Similar changes in the laminar-specific patterns of NMDAR1 immunostaining are seen in the developing cat visual cortex (Fig.3). At E42, fibers within the intermediate zone and marginal zoneare immunopositive (Fig. 3A). The dense cortical plate and subplatecells are intensely immunoreactive. By birth (P0, equivalent toE65) (Fig. 3B), differentiated layer 6 is immunostained as intenselyas the dense cortical plate and subplate neurons. By P28 (Fig.3C), NMDAR1 immunoreactivity in layers 4 and 6 has declined, whereaslayers 2/3 and 5 remain intensely immunostained. At P34 (datanot shown) and P40, immunoreactivity in layer 5 has declined andis similar in intensity to that in layer 6 (Fig. 3D). Immunostainingin layer 4 has increased, is now similar to that of layers 2/3,and is uniform throughout both of these layers (but see Murphyet al., 1996). By P108, immunoreactivity in layers 2/3 remainsintense (Fig. 3E). NMDAR1 immunostaining in layer 4 has declinedand is now similar to that of layer 6. In adulthood, only layers2/3 remain intensely immunoreactive (Fig. 3F). A higher magnificationview of the border between layers 4 and 5 in cat visual cortexat P40 (Fig. 4A) highlights several key features of NMDAR1 immunoreactivity.Cells in layer 4 are more intensely immunostained than those inlayer 5. Both pyramidal and stellate cell types are immunoreactive,with the cell body and proximal dendrites being the most intenselyimmunostained. Glial cell staining is not observed at any age.The neuropil is also diffusely immunoreactive. This staining isspecific, as can be appreciated by noting the precipitous declinein diffuse staining in layer 5 (Fig. 4A) and also in the virtualabsence of staining in cortical layer 1 as compared with layers2/3 (Fig. 4B). At least some of this neuropil staining is alsolikely to be attributable to dendritic immunoreactivity (arrowsin Fig. 4A,B), which is as intense as that of the cell bodies.We consider it highly unlikely that the decline in immunostainingin layers 4-6 is caused by myelination, because layers 2/3 horizontalconnections are also myelinated and immunoreactivity within thislayer remains high into adulthood. Moreover, a good deal of thechange in immunostaining is caused by the loss of somatic staining,which obviously cannot be attributed to myelination-based problemsin antibody accessibility.
Fig. 3. NMDAR1 immunoreactivity in the developing cat visual cortex at E42 (A), P0 (B), P28 (C), P40 (D), P108 (E), and Adult (F).Note the progressive loss of staining from the deeper corticallayers at older ages. See Figure 2 for abbreviations. Scale bar(bottom left in D): A, C, 120 µm; B, 230 µm; D, E, F, 300 µm.
[View Larger Version of this Image (117K GIF file)]

Fig. 4. Photomicrograph at higher magnification showing NMDAR1 immunostained cells at the border between layers 4 and 5 (A) and layers2/3 and 1 (B) in a P40 cat. A, Many cells in layers 4 and 5 areimmunoreactive, but the cells in layer 5 are far less intenselystained than those in layer 4. Both pyramidal and stellate cellsare immunoreactive. B, The neuropil within layers 2/3 is moreintensely stained than that of layer 1. Apical dendrites (arrow)appear to be as intensely immunoreactive as their parent cellsoma. Scale bar (bottom left in A): 50 µm.
[View Larger Version of this Image (139K GIF file)]

Levels of immunocytochemically detectable NMDAR1 change in development with a laminar-specific time course. However, the transientincrease in layer 4 is noteworthy in that it coincides with majordevelopmental events in cat visual cortex. After the initial decreasein layer 4 immunostaining, which occurs between P0 and P15 inthe cat, NMDAR1 immunoreactivity is subsequently increased inlayer 4, and this increase occurs during the period of oculardominance column formation (P21-42) (LeVay et al., 1978). NMDAR1immunoreactivity then declines to adult-like levels by P76, whichis past the age when abnormal visual experience can lead to changesin the anatomical pattern of ocular dominance columns within layer4 (Mower et al., 1985). After this age, anatomical rearrangementsof thalamocortical axons can no longer be induced by alterationsof activity (such as lid suture). In contrast to layer 4, recentevidence suggests that anatomical rearrangements can occur inlayers 2/3 into adulthood in response to activity-dependent manipulations(Darian-Smith and Gilbert, 1994). The dramatic decline in immunostainingin layer 4 that occurs with increasing age is illustrated in Figure5. At younger ages (P53), layers 2/3 and 4 are stained with equalintensity. At older ages (P76), layer 4 is less intensely stainedthan layers 2/3.
Fig. 5. Decline in immunostaining for NMDAR1 in layer 4 with progressive development compared in cat (top) and ferret (bottom) visualcortex. Intensely immunoreactive cells are visible both in layers4 and 2/3 in P52 cat (A) and in P49 ferret (C). At these ages,cells in layers 5 and 6 are much less intensely immunoreactivethan cells in layers 2/3. By the end of the cat critical period(B) (P76) and in adult ferrets (D), this intense immunoreactivitypersists in layers 2/3 but is gone from layer 4; cells in layer4 exhibit staining similar to that found in the lower layers.Scale bar, 300 µm.
[View Larger Version of this Image (113K GIF file)]

Activity-dependent regulation of NMDAR1
Raising animals in the dark leads to a diminution, but not complete absence, of optic nerve activity and causes changes inboth NMDA receptor-mediated responses and channel activation kineticswithin the cortex (Carmignoto and Vicini, 1992; Fox et al., 1992).Raising animals in the dark also extends the period during whichabnormal visual experience can cause anatomical and physiologicalchanges in cortical connectivity (Cynader and Mitchell, 1980;Mower et al., 1985; Stryker and Harris, 1986; Swindale, 1988).This period, known as the critical period, differs somewhat fordifferent layers and for developmental changes occurring at theanatomical level (e.g., the development of ocular dominance columns)versus physiologically assessed changes in synaptic connectivity(e.g., shifts in ocular dominance caused by monocular deprivation).To examine whether levels of NMDAR1 immunoreactivity are alsoregulated by dark-rearing, we raised cats in the dark from shortlyafter birth to various ages (see Materials and Methods). We weresurprised to find that dark-rearing had no effect whatsoever oneither the adult pattern or the time course of laminar changesin NMDAR1 immunostaining. For example, as shown in Figure 6, theloss of NMDAR1 immunostaining in layers 4-6 still occurred indark-reared animals by P103 (Fig. 6E,F). We also examined dark-rearedanimals at P15 (Fig. 6A,B), P28, P34, and P52, and in no casewas the pattern of immunostaining different from that of normalanimals at the same age. Even the transient increase in layer4 immunostaining appeared to occur at the appropriate time (Fig.6C,D).
Fig. 6. Dark-rearing does not alter the laminar pattern of immunostaining in primary visual cortex. At P15 in both normal cats (A)and after 2 weeks of dark-rearing beginning at P1 (B), layers2/3 and 5 are stained most intensely. At P53, layer 4 is equallyas intensely stained as layers 2/3 in both normal (C) and dark-reared(D) animals. At P104, the visual cortex of normal animals (E)and animals dark-reared from shortly after birth (F) exhibit highlevels of immunostaining in layers 2/3, whereas layers 4-6 arestained less intensely. Scale bar, 300 µm.
[View Larger Version of this Image (86K GIF file)]

To obtain a direct, quantitative comparison of patterns of immunostaining between the dark-reared and normally reared animals,we computed the ratio of the average intensity of immunostainingwithin layers 2/3 to layer 4 at each age (see Fig. 10A). Duringnormal development at young ages, layers 2/3 are ~20% darker thanlayer 4; by P34, staining in both layers is equivalent in intensity.At older ages, layers 2/3 is almost 50% more intensely stainedthan layer 4. The maximal laminar difference occurs at P76, whenstaining in layers 2/3 is still relatively intense but stainingin layer 4 has declined. Thereafter, the difference in stainingbetween layers 2/3 and 4 is less dramatic. The developmental curveof dark-reared animals is almost identical. Finally, dark-rearingfollowed by brief periods of exposure to the light (4 or 10 d)also had no effect on immunostaining (Fig. 10A). Thus visual experienceapparently is not essential for the progressive laminar changesin levels of NMDAR1 immunoreactivity.

For comparison, developmental changes in the laminar-specific pattern of immunostaining were also examined in other areasof the neocortex in the normally reared and dark-reared cats inwhich primary visual cortex had been studied. There were no discernibledifferences in the laminar patterns of immunostaining betweenvisual cortex and other cortical areas in either normal or dark-rearedanimals. In normal animals the time course of the laminar-specificchanges in levels of NMDAR1 was the same over the entire neocorticalmantle. For example, in primary auditory cortex of a normal P53cat (Fig. 7A), layers 4 and 2/3 are more intensely immunoreactivethan the lower layers, and this pattern of immunostaining is identicalto that seen at this age in visual cortex (compare with Fig. 5A).Similarly, staining patterns in primary somatosensory cortex ofa P104 animal (Fig. 7C) are virtually indistinguishable from thosein visual cortex at the same age (compare with Fig. 6E). Primaryauditory and somatosensory cortices of dark-reared animals (Fig.7B,D) are also indistinguishable from these same areas in normalanimals (compare with Fig. 7A,C). Thus, the developmental changesin the laminar-specific pattern of NMDAR1 immunostaining appearto be synchronized throughout neocortex.
Fig. 7. Developmental changes in laminar patterns of NMDAR1 immunostaining occur over the same time period throughout cat neocortex.A, Primary auditory cortex at P53. B, Primary auditory cortexat P53 in an animal dark-reared from shortly after birth to P53.Layers 4 and 2/3 are more intensely immunoreactive than the lowerlayers, and dark-rearing does not affect this pattern of staining.C, Primary somatosensory cortex of normal animal aged P104. D,Primary somatosensory cortex in an animal dark-reared to P104.At this age, somatosensory cortex exhibits relatively intensestaining for NMDAR1 in layers 2/3 but not in the other layers.These same laminar-specific patterns of immunostaining are seenin visual cortex at the same ages (compare with Figs. 5A, 6E).Scale bar, 300 µm.
[View Larger Version of this Image (79K GIF file)]

The fact that dark-rearing had no obvious effect on the developmental changes in laminar-specific levels of NMDAR1 immunostainingraised the question of whether neural activity per se can regulateNMDAR1 protein levels. Dark-rearing does not block the spontaneousdischarges of retinal ganglion cells (Mastronarde, 1989), so itis quite likely that spontaneous, retinally driven activity isstill present in dark-reared animals. To block retinal activityentirely, and to have a means of comparing the effects of sucha blockade directly within the same animal, we performed an experimentin which TTX, a blocker of voltage-sensitive Na⁺ channels, was injected intraocularly into one eye for 2 weeksfrom P40-53. At P40, the ocular dominance columns have just formedwithin layer 4 (LeVay et al., 1978), making it possible to examinewhether activity blockade in one eye can alter the levels of immunostainingfor NMDAR1 in cortical columns associated with that eye.

The pattern of NMDAR1 immunostaining after monocular TTX injections was dramatically different from that seen in untreatedanimals of the same age (compare Fig. 8A with Fig. 5A). In theTTX-treated animals, there was a distinct waxing and waning ofimmunostaining in cortical layer 4. To determine whether the zoneof relatively high-intensity NMDAR1 immunostaining correspondedto the untreated versus the treated eye, adjacent sections werereacted for cytochrome oxidase (CO) histochemistry. A declinein CO staining within layer 4 is known to be associated with thecolumns of the blocked eye (Wong-Riley, 1979; Murphy et al., 1995).As shown in Figure 8A,B, there is a clear association betweenzones of diminished CO staining and regions of lighter NMDAR1immunostaining. This indicates that TTX treatment resulted ina decrease in levels of NMDAR1 within layer 4 relative to NMDAR1levels in layer 4 patches associated with the uninjected eye.In contrast, there was no effect of TTX injections on immunostainingwithin layers 2/3, which remained uniform (but see Murphy et al.,1996). Similarly, immunostaining of other cortical areas in thesesame animals was uniform, as was immunostaining of layer 4 inan animal that received an intraocular injection of citrate vehiclealone (Fig. 9). This result suggests that retinal activity canindeed regulate levels of NMDAR1 immunoreactivity, chiefly withincortical layer 4.
Fig. 8. Monocular TTX injection from P40 to P53 decreases NMDAR1 immunostaining in injected eye columns of layer 4 in cat visual cortex.Adjacent sections stained for NMDAR1 immunocytochemistry (A) orfor CO histochemistry (B). Note higher levels of NMDAR1 immunostaining(A) and CO activity (B) in patches (arrows) in layer 4 correspondingto the uninjected eye. Scale bar (shown in A): 500 µm.
[View Larger Version of this Image (98K GIF file)]

To characterize these changes further, digital images of tissue sections were obtained using a video camera, and immunostainingintensity was expressed as units of pixel gray values. The averageimmunostaining intensity within layer 4 over a span of 2.5 mmwas then plotted (Fig. 9). In sections from animals that had receivedmonocular TTX injections between P40 and P52, fluctuations inthe intensity of NMDAR1 immunostaining within layer 4 are clearlyvisible (Fig. 9A,B). The peak-to-trough periodicity of these fluctuationsis ~0.5 mm, which roughly corresponds in the cat to the dimensionsof ocular dominance columns (Shatz et al., 1977; LeVay et al.,1978). No such periodicity in NMDAR1 immunoreactivity is presentwithin layer 4 of either a control animal monocularly injectedwith citrate buffer vehicle (Fig. 9C) or a normal untreated animalof the same age (Fig. 9D). Similarly, no such fluctuations inimmunostaining intensity are present in superficial layers 2/3or layer 6 of TTX-treated animals (Fig. 9E). Finally, as shownin the histograms of Figure 10B, there is no significant differencein the ratio of layers 2/3/layer 4 staining between normal animalsand animals in which citrate vehicle was injected into one eye(p < 0.15; two-tailed t test) (Fig. 10B). There is also no significantdifference in the ratio of layers 2/3/layer 4 staining betweennormal animals and columns in the noninjected eye in animals thatreceived monocular injections of TTX (p < 0.005). In contrast,the ratios between layers 2/3 and layer 4 in the columns of theinjected eye in the TTX-treated animals is significantly differentfrom normal (p < 0.00005), reflecting the large decrease in immunostainingintensity within layer 4 pertaining to the TTX-treated eye. Theseobservations lend quantitative support to the conclusion thatretinal activity blockade can indeed dramatically modulate levelsof NMDAR1 within developing visual cortex.

DISCUSSION
Here we have used an antibody to the R1 subunit of the NMDA receptor to monitor immunohistochemical changes in the distributionof NMDA receptors in the development of the cat and ferret visualcortex. Results indicate that there are sequential changes inthe laminar pattern of immunostaining; these are summarized schematicallyin Figure 11. The most striking of these changes includes a permanentdecrease in immunoreactivity within cortical layers 5 and 6, atransient developmental increase in layer 4 immunostaining, anda persistence of immunostaining in layers 2/3 into adulthood.
Fig. 11. Summary of developmental changes in the laminar pattern of NMDAR1 immunoreactivity in cat neocortex. Ages at the top correspondto those examined in this study. Each cortical layer is representedby its most prominent cell type (large or small pyramidal or stellatecells). Black cells indicate high levels of NMDAR1 immunostaining;gray cells are stained less intensely. The bar at the bottom offigure is a timeline of the major anatomical events in cat visualcortex development. Note gradual decline in immunostaining ofdeep cortical layers (5 and 6) with age, transient elevation ofstaining in layer 4 between P34 and P53, and maintenance of highlevels of immunostaining in layers 2/3 into adulthood.
[View Larger Version of this Image (42K GIF file)]

Developmental changes in NMDAR1 immunoreactivity correlate with periods of synaptic remodeling
Levels of NMDAR1 immunoreactivity are high in layer 4 during the period of development when geniculocortical axons are remodelingtheir terminal arbors to form columnar patterns of connections.In the cat visual cortex, segregation of initially overlappinggeniculocortical axon terminals representing each eye within layer4 into ocular dominance columns begins at approximately 3 weeksof age and is nearly adult-like by 6 weeks (LeVay et al., 1978;Antonini and Stryker, 1993b). R1 levels peak in layer 4 by approximately4 weeks (P35) and fall to adult levels by 11 weeks (P76), whenanatomical rearrangements of geniculocortical axons can no longerbe induced (Mower et al., 1985). Physiologically, NMDA receptorsmake a similar contribution to the visually driven activity ofneurons in all cortical layers initially; however, between 3 and6 weeks, this contribution declines in layers 4-6 and remainshigh in layers 2/3 (Tsumoto et al., 1987; Fox et al., 1989). Thus,our immunocytochemistry observations of laminar patterns of R1levels correlate with the physiological changes, albeit at a slighttemporal lag.

There is also a clear correlation in layers 2/3 between high levels of NMDAR1 immunoreactivity and known periods of axonalgrowth and synaptic plasticity. In these superficial layers, thepattern of lateral axonal connections develops over the same timecourse as that for the geniculocortical axons (Callaway and Katz,1990; Ruthazer and Stryker, 1996). However, unlike layer 4, inwhich major axonal remodeling appears to end with the close ofthe critical period, evidence suggests that the capacity for axonalremodeling of horizontal connections persists in layers 2/3 intoadulthood (Darian-Smith and Gilbert, 1994). Physiologically, theeffects of monocular deprivation on the ocular dominance preferenceof neurons in the superficial layers can be demonstrated in animalsas old as 1 year, long after eye dominance in layer 4 can no longerbe altered (Daw et al., 1992), and there is accumulating evidencethat the receptive fields of neurons in layers 2/3, but not layers4-6, can be altered dynamically in adults by certain patternsof visual stimulation (Das and Gilbert, 1995). The finding herethat the levels of NMDAR1 immunostaining remain high within layers2/3 into adulthood is entirely consistent with an ongoing rolefor NMDA receptors in modulating plasticity within these specificsuperficial layers.

Taken together, our data suggest that high levels of NMDAR1 immunoreactivity within the visual cortex are correlated withperiods in development (or in the adult) when the capacity foranatomical and physiological synaptic plasticity is possible,depending on cortical layer. In addition, we observed that developmentalchanges in the laminar pattern of NMDAR1 immunoreactivity occurwith the same time course in all cortical areas examined. Severalother aspects of cortical development appear to be synchronizedacross all areas of cortex. For example, the time course of bothsynaptogenesis and the development of relative proportions ofdifferent types of synapses are the same in visual, motor, somatosensory,and prefrontal cortical areas of monkeys (Bourgeois et al., 1994).As these authors suggest, synchronous maturation of certain aspectsof cortical development may be required to coordinate the developmentof particular cortical features such as the network of intracorticalconnections. If NMDA receptors play a crucial role in synapticremodeling in cortex, it may be important to synchronize theirexpression throughout cortex, and if so, then the changes seenhere in NMDAR1 immunostaining could reflect this synchrony.

The distribution of NMDA receptors has been studied previously using autoradiographic ligand binding on tissue sections ofboth developing cat (Bode-Greuel and Singer, 1989) and adult ferretvisual cortex (Smith and Thompson, 1994). Contrary to the presentresults, the cat study concluded that layers 4 and 5/6 exhibitedsimilar levels of binding sites throughout development, and thatbinding sites in all layers increased gradually to a peak at 12weeks and then declined into adulthood. The ligand binding studyin adult ferrets suggests that NMDA receptors are expressed equallyin all layers of cortex, with binding in layers 4 and 1 slightlyhigher than in other layers. Methodological differences such asthe increased spatial resolution provided here by immunocytochemistryand the dependence of ligand binding on the physiological stateof the receptor may account for the differences seen between thesestudies and the present results.

A temporal correlation exists between the period of high levels of NMDAR1 immunostaining in the visual cortex and the presenceof neocortical long-term potentiation (LTP) and long-term depression(LTD). NMDA receptor-dependent LTP and LTD can be evoked in slicesof cat and rat visual cortex and rat somatosensory cortex fromyoung animals. At older ages and in adulthood, LTP and LTD canno longer be induced in layer 4 but can still be induced in layers2/3 (Komatsu et al., 1988; Perkins and Teyler, 1988; Kirkwoodand Bear, 1994; Castro-Alamancos et al., 1995; Crair and Malenka,1995; Dudek and Friedlander, 1996; Isaac et al., 1997; for review,see Bear and Malenka, 1994). Changing levels of NMDAR1 seen heremay partially account for the changing capacity for LTP and LTDduring development.

Regulation of NMDAR1 immunoreactivity by vision and activity
Dark-rearing did not alter either the time course or the laminar pattern of immunostaining for NMDAR1 in visual cortex, andthis observation was surprising in view of the results of severalprevious physiological studies. Normally, the duration of theNMDA receptor-mediated EPSC shortens over development, but dark-rearingor TTX administration can prevent this shortening (Carmingnotoand Vicini, 1992). Similarly, the normal developmental decreasein the percentage of the visually driven response mediated byNMDA receptors is prevented when cats are raised in the dark andresumes when dark-reared animals are subsequently exposed to light(Fox et al., 1989, 1991, 1992). Our results suggest that the physiologicalalterations that occur during dark-rearing do not result frommajor changes in the amount of NMDAR1 protein. However, NMDA receptorsubunit composition (Sheng et al., 1994; Flint et al., 1997) and/orphosphorylation state (Roche et al., 1994; Tingley et al., 1997)may change with dark-rearing, because both have also been shownto affect channel function.

Because the normal developmental loss of NMDAR1 immunostaining from layer 4 is not prevented by dark-rearing, vision evidentlyis not required for this sequential maturational change. Visionis also not required for the progressive segregation of LGN axonsto form the system of ocular dominance columns in layer 4 (Moweret al., 1985; Stryker and Harris, 1986). Dark-rearing, however,does not abolish all retinal activity. What remains is spontaneousactivity generated among retinal ganglion cells (Meister et al.,1991; Wong et al., 1993, 1995; Feller et al., 1996). These considerationssuggest that spontaneous retinal activity may be sufficient todrive the laminar changes in distribution of NMDAR1. On the otherhand, the synchronous changes observed here in laminar patternsof NMDAR1 immunoreactivity across many neocortical areas implythat changes in neural activity would have to be coordinated acrossmany different functional modalities. Thus, an alternative possibilityis that intrinsic activity-independent mechanisms, or neural activitynot necessarily related to sensory stimulation, is responsiblefor the sequential changes in the laminar distribution of NMDAR1within neocortex.

Although dark-rearing does not alter developmental changes in the pattern of NMDAR1 immunostaining, monocular TTX injectionsbetween P40 and P53 result in a profound alteration in levelsof NMDAR1 in layer 4 of the visual cortex. Normally at P40 andP53, the levels of NMDAR1 immunostaining in layer 4 are relativelyhigh and fall thereafter to adult levels. Monocular blockade ofactivity caused a dramatic decrease in immunostaining in layer4 ocular dominance columns receiving input from the blocked eye.Thus it would seem that NMDAR1 levels can indeed be regulatedby alterations in neural activity under some circumstances: whenretinal activity is eliminated entirely.

It should be noted that monocular blockade has very different consequences from dark-rearing or even binocular TTX blockadefor spatial patterns of neural activity within cortex. At P40,at the onset of the monocular TTX blockade, segregation of LGNaxons into ocular dominance columns is well on the way to completion,and most layer 4 neurons are already monocularly driven (LeVayet al., 1978). Consequently, layer 4 neurons receiving input fromthe blocked eye will not only be silenced because of lack of functionalgeniculocortical inputs, but they may also receive strong localinhibition from adjacent unblocked eye columns. This profoundimbalance of activity may be necessary to cause a decrease inNMDAR1 levels. Such an imbalance of activity between blocked andunblocked columns in layer 4 could also explain why monocularTTX injections failed to produce alterations in NMDAR1 immunostainingin layers 2/3. Neurons in these cortical layers are normally binocularlydriven (Shatz and Stryker, 1978) and would be expected to continueto receive powerful synaptic drive from layer 4 neurons belongingto the unblocked eye. Future experiments in which cortical activityis manipulated directly could help unravel the extent to whichactivity-dependent versus activity-independent processes contributeto the regulation of NMDAR1. Suffice it to say that our experimentprovides clear evidence that profound alterations in the balanceof afferent activity from the two eyes can indeed alter NMDAR1levels in layer 4 of the visual cortex.

FOOTNOTES

Received June 23, 1997; revised Aug. 13, 1997; accepted Aug. 20, 1997.

This research was supported by National Institutes of Health Grant R32 EY02858 to C.J.S. and National Research Service AwardEY06491 to S.M.C. C.J.S. is an investigator of the Howard HughesMedical Institute. We thank Denise Escontrias and Alma Raymondfor invaluable assistance with animal husbandry and surgeries.

Correspondence should be addressed to Dr. Susan M. Catalano, Life Sciences Addition 221, University of California, Berkeley,CA 94720.

REFERENCES

Antonini A, Stryker MP (1993a) Rapid remodeling of axonal arbors in the visual cortex. Science 260:1819-1821[Abstract/Free Full Text].
Antonini A, Stryker MP (1993b) Development of individual geniculocortical arbors in cat striate cortex and effects of binocular impulse blockade. J Neurosci 13:3549-3573[Abstract].
Bear MF (1996) NMDA-receptor-dependent synaptic plasticity in the visual cortex. Prog Brain Res 108:205-218[Web of Science][Medline].
Bear MF, Colman H (1990) Binocular competition in the control of geniculate size depends upon visual cortical N-methyl-D-aspartate receptor activation. Proc Natl Acad Sci USA 87:9246-9249[Abstract/Free Full Text].
Bear MF, Malenka RC (1994) Synaptic plasticity: LTP and LTD. Curr Opin Neurobiol 4:389-399[Medline].
Bear MF, Kleinschmidt A, Gu Q, Singer W (1990) Disruption of experience-dependent synaptic modifications in striate cortex by infusion of an NMDA receptor antagonist. J Neurosci 10:909-925[Abstract].
Bode-Greuel K, Singer W (1989) The development of N-methyl-D-aspartate receptors in cat visual cortex. Dev Brain Res 46:197-204[Medline].
Bourgeois J-P, Goldman-Rakic PS, Rakic P (1994) Synaptogenesis in the prefrontal cortex of rhesus monkeys. Cereb Cortex 4:78-96[Abstract/Free Full Text].
Brose N, Thomas A, Weber MG, Jahn R (1990) A chloride- and calcium-dependent glutamate-binding protein from rat brain. Identification as a ubiquitous constituent of the inner mitochondrial membrane. J Biol Chem 265:10604-10610[Abstract/Free Full Text].
Brose N, Huntley GW, Stern-Bach Y, Sharma G, Morrison JH, Heinemann SF (1994) Differential assembly of coexpressed glutamate receptor subunits in neurons of rat cerebral cortex. J Biol Chem 269:16780-16784[Abstract/Free Full Text].
Callaway EM, Katz LC (1990) Emergence and refinement of clustered horizontal connections in cat striate cortex. J Neurosci 10:1134-1153[Abstract].
Callaway EM, Katz LC (1991) Effects of binocular deprivation on the development of clustered horizontal connections in cat striate cortex. Proc Natl Acad Sci USA 88:745-749[Abstract/Free Full Text].
Carmignoto G, Vicini S (1992) Activity-dependent decrease in NMDA receptor responses during development of the visual cortex. Science 258:1007-1011[Abstract/Free Full Text].
Castro-Alamancos MA, Donoghue JP, Connors B (1995) Different forms of synaptic plasticity in somatosensory and motor areas of the neocortex. J Neurosci 15:5324-5333[Abstract].
Cline H, Constantine-Paton M (1990) NMDA receptor agonist and antagonists alter RGC terminal morphology in the frog retinotectal projection. J Neurosci 10:1197-1216[Abstract].
Crair MC, Malenka RC (1995) A critical period for long-term potentiation at thalamocortical synapses. Nature 375:325-328[Medline].
Cynader M, Mitchell DE (1980) Prolonged sensitivity to monocular deprivation in dark-reared cats. J Neurophysiol 43:1026-1040[Free Full Text].
Darian-Smith C, Gilbert CD (1994) Axonal sprouting accompanies functional reorganization in adult cat striate cortex. Nature 368:737-740[Medline].
Das A, Gilbert CD (1995) Receptive field expansion in adult visual cortex is linked to dynamic changes in strength of cortical connections. J Neurophysiol 74:779-792[Abstract/Free Full Text].
Daw NW, Fox K, Sato H, Czepita D (1992) Critical period for monocular deprivation in the cat visual cortex. J Neurophysiol 67:197-202[Abstract/Free Full Text].
Dudek SM, Friedlander MJ (1996) Developmental down-regulation of LTD in cortical layer IV and its independence of modulation by inhibition. Neuron 16:1097-1106[Web of Science][Medline].
Feller MB, Wellis DP, Stellwagen D, Werblin FS, Shatz CJ (1996) Requirement for cholinergic synaptic transmission in the propagation of spontaneous retinal waves. Science 272:1182-1187[Abstract].
Flint AC, Maisch US, Weishaupt JH, Kriegstein AR, Monyer H (1997) NR2A subunit expression shortens NMDA receptor synaptic currents in developing neocortex. J Neurosci 17:2469-2476[Abstract/Free Full Text].
Fox K, Daw NW (1993) Do NMDA receptors have a critical function in visual cortical plasticity? Trends Neurosci 16:116-122[Web of Science][Medline].
Fox K, Sato H, Daw N (1989) The location and function of NMDA receptors in cat and kitten visual cortex. J Neurosci 9:2443-2454[Abstract].
Fox K, Daw N, Sato H, Czepita D (1991) Dark-rearing delays the loss of NMDA-receptor function in kitten visual cortex. Nature 350:342-344[Medline].
Fox K, Daw N, Sato H, Czepita D (1992) The effect of visual experience on development of NMDA receptor synaptic transmission in kitten visual cortex. J Neurosci 12:2672-2684[Abstract].
Fox K, Schlaggar BL, Glazewski S, O'Leary DDM (1996) Glutamate receptor blockade at cortical synapses disrupts development of thalamocortical and columnar organization in somatosensory cortex. Proc Natl Acad Sci USA 93:5584-5589[Abstract/Free Full Text].
Gazzaley AH, Weiland NG, McEwen BS, Morrison JH (1996) Differential regulation of NMDAR1 mRNA and protein by estradiol in the rat hippocampus. J Neurosci 16:6830-6838[Abstract/Free Full Text].
Ghosh A, Shatz CJ (1992) Pathfinding and target selection by developing geniculocortical axons. J Neurosci 12:39-55[Abstract].
Gu Q, Bear MF, Singer W (1989) Blockade of NMDA-receptors prevents ocularity changes in kitten visual cortex after reversed monocular deprivation. Dev Brain Res 47:281-288[Medline].
Hahm J-O, Langdon RB, Sur M (1991) Disruption of retinogeniculate afferent segregation by antagonists to NMDA receptors. Nature 351:568-570[Medline].
Hubel DH, Wiesel TN, LeVay S (1977) Plasticity of ocular dominance columns in monkey striate cortex. Philos Trans R Soc Lond [Biol] 278:377-409[Abstract/Free Full Text].
Isaac JT, Crair MC, Nicoll RA, Malenka RC (1997) Silent synapses during development of thalamocortical inputs. Neuron 18:269-280[Web of Science][Medline].
Iwasato T, Erzurumlu RS, Chen DF, Huerta PT, Sasaoka T, Ulupinar E, Tonegawa S (1997) NMDA receptor dependent refinement of body maps in the somatosensory systems. Soc Neurosci Abstr 23:74.
Jackson CA, Peduzzi JD, Hickey TL (1989) Visual cortex development in the ferret. I. Genesis and migration of visual cortical neurons. J Neurosci 9:1242-1253[Abstract].
Katz LC, Shatz CJ (1996) Synaptic activity and the construction of cortical circuits. Science 274:1133-1138[Abstract/Free Full Text].
Kirkwood A, Bear M (1994) Hebbian synapses in visual cortex. J Neurosci 14:1634-1645[Abstract].
Kleinschmidt A, Bear M, Singer W (1987) Blockade of "NMDA" receptors disrupts experience-dependent plasticity of kitten striate cortex. Science 238:355[Abstract/Free Full Text].
Komatsu Y, Fuji K, Maeda J, Sakaguchi H, Toyama K (1988) Long-term potentiation of synaptic transmission in kitten visual cortex. J Neurophysiol 59:124-141[Abstract/Free Full Text].
Kopke AKE, Bonk I, Sydow S, Menke H, Spiess J (1993) Characterization of the NR1, NR2A and NR2C receptor proteins. Protein Sci 2:2066-2076[Web of Science][Medline].
LeVay S, Stryker MP, Shatz CJ (1978) Ocular dominance columns and their development in layer IV of the cat's visual cortex: a quantitative study. J Comp Neurol 179:223-244[Web of Science][Medline].
Li Y, Erzurumlu RS, Chen C, Jhaveri S, Tonegawa S (1994) Whisker-related neuronal patterns fail to develop in the trigeminal brainstem nuclei of NMDAR1 knockout mice. Cell 76:427-437[Web of Science][Medline].
Luskin MB, Shatz CJ (1985a) Cogeneration of subplate and marginal zone cells in the cat's primary visual cortex. J Neurosci 5:1062-1075[Abstract].
Mastronarde DN (1989) Correlated firing of retinal ganglion cells. Trends Neurosci 12:75-80[Web of Science][Medline].
Meister M, Wong ROL, Baylor DA, Shatz CJ (1991) Synchronous bursts of action potentials in ganglion cells of the developing mammalian retina. Science 252:939-943[Abstract/Free Full Text].
Monyer H, Sprengel R, Schoepfer R, Herb A, Higuchi M, Lomeli H, Burnashev N, Sakmann B, Seeburg PH (1992) Heteromeric NMDA receptors: molecular and functional distinction of subtypes. Science 256:1217-1221[Abstract/Free Full Text].
Moriyoshi K, Masu M, Ishii T, Shigemoto R, Mizuno N, Nakanishi S (1991) Molecular cloning and characterization of the rat NMDA receptor. Nature 354:31-37[Medline].
Mower GD, Caplan CJ, Christen WG, Duffy FH (1985) Dark rearing prolongs physiological but not anatomical plasticity of the cat visual cortex. J Comp Neurol 235:448-466[Web of Science][Medline].
Murphy KM, Jones DG, Van Sluyters RC (1995) Cytochrome-oxidase blobs in cat primary visual cortex. J Neurosci 15:4196-4208[Abstract].
Murphy KM, Trepel C, Pegado VD (1996) Non-uniform distribution of the NMDAR1 receptor subunit in kitten visual cortex at the peak of the critical period. Mol Vision 2:9.[Medline]
Nakanishi S (1992) Molecular diversity of glutamate receptors and implications for brain function. Science 258:579-603.
Perkins AT, Teyler TJ (1988) A critical period for long-term potentiation in the developing rat visual cortex. Brain Res 439:222-229[Web of Science][Medline].
Roche KW, Tingley WG, Huganir RL (1994) Glutamate receptor phosphorylation and synaptic plasticity. Curr Opin Neurobiol 4:383-388[Medline].
Ruthazer ES, Stryker MP (1996) The role of activity in the development of long-range horizontal connections in area 17 of the ferret. J Neurosci 16:7253-7269[Abstract/Free Full Text].
Ruthazer ES, Baker GE, Stryker MP (1995) Development and pattern of ocular dominance columns in ferret visual cortex. Soc Neurosci Abstr 21:1795.
Schlaggar BL, Fox K, O'Leary DDM (1993) Postsynaptic control of plasticity in developing somatosensory cortex. Nature 364:623-626[Medline].
Shatz CJ, Stryker MP (1978) Ocular dominance in layer IV of the cat's visual cortex and the effects of monocular deprivation. J Physiol (Lond) 281:267-283[Abstract/Free Full Text].
Shatz CJ, Lindstrom SH, Wiesel TN (1977) The distribution of afferents representing the right and left eyes in the cat's visual cortex. Brain Res 131:103-116[Web of Science][Medline].
Sheng M, Cummings J, Roldan LA, Jan YN, Jan LY (1994) Changing subunit composition of heteromeric NMDA receptors during development of rat cortex. Nature 368:144-147[Medline].
Smith AL, Thompson ID (1994) Distinct laminar differences in the distribution of excitatory amino acid receptors in adult ferret primary visual cortex. Neuroscience 61:467-479[Web of Science][Medline].
Stryker MP, Harris WA (1986) Binocular impulse blockade prevents the formation of ocular dominance columns in cat visual cortex. J Neurosci 6:2117-2133[Abstract].
Sucher NJ, Brose N, Deitcher DL, Awobuluyi M, Gasic G, Bading H, Cepko C, Greenburg M, Jahn J, Heinemann S (1993) Expression of endogenous NMDAR1 transcripts without receptor protein suggests post-transcriptional control in PC12 cells. J Biol Chem 268:22299-22304[Abstract/Free Full Text].
Swindale NV (1988) Role of visual experience in promoting segregation of eye dominance patches in the visual cortex of the cat. J Comp Neurol 267:472-488[Web of Science][Medline].
Tingley WG, Ehlers MD, Kameyama K, Doherty D, Ptak JB, Riley CT, Huganir RL (1997) Characterization of protein kinase A and protein kinase C phosphorylation of the N-methyl-D-aspartate receptor NR1 subunit using phosphorylation site-specific antibodies. J Biol Chem 272:5157-5166[Abstract/Free Full Text].
Tsumoto T, Hagihara K, Sato H, Hata Y (1987) NMDA receptors in the visual cortex of young kittens are more effective than those of adult cats. Nature 327:513-514[Medline].
Wong ROL, Meister M, Shatz CJ (1993) Transient period of correlated bursting activity during development of the mammalian retina. Neuron 11:923-938[Web of Science][Medline].
Wong ROL, Chernjavsky A, Smith SJ, Shatz CJ (1995) Early functional neural networks in the developing retina. Nature 374:716-718[Medline].
Wong-Riley M (1979) Changes in the visual system of monocularly sutured or enucleated cats demonstrable with cytochrome oxidase histochemistry. Brain Res 171:11-28[Web of Science][Medline].

Copyright ©1997 Society for Neuroscience   0270-6474/1997/178376-15$05.00/0

This article has been cited by other articles:

J. C. Dahmen, D. E. H. Hartley, and A. J. King
Stimulus-Timing-Dependent Plasticity of Cortical Frequency Representation
J. Neurosci., December 10, 2008; 28(50): 13629 - 13639.
[Abstract] [Full Text] [PDF]

N. C Spitzer and L. N Borodinsky
Implications of activity-dependent neurotransmitter-receptor matching
Phil Trans R Soc B, April 12, 2008; 363(1495): 1393 - 1399.
[Abstract] [Full Text] [PDF]

L. N. Borodinsky and N. C. Spitzer
Activity-dependent neurotransmitter-receptor matching at the neuromuscular junction
PNAS, January 2, 2007; 104(1): 335 - 340.
[Abstract] [Full Text] [PDF]

S. Oray, A. Majewska, and M. Sur
Effects of Synaptic Activity on Dendritic Spine Motility of Developing Cortical Layer V Pyramidal Neurons
Cereb Cortex, May 1, 2006; 16(5): 730 - 741.
[Abstract] [Full Text] [PDF]

R. H. Dyck, A. Chaudhuri, and M. S. Cynader
Experience-dependent Regulation of the Zincergic Innervation of Visual Cortex in Adult Monkeys
Cereb Cortex, October 1, 2003; 13(10): 1094 - 1109.
[Abstract] [Full Text] [PDF]

T. P. Doubell, I. Skaliora, J. Baron, and A. J. King
Functional Connectivity between the Superficial and Deeper Layers of the Superior Colliculus: An Anatomical Substrate for Sensorimotor Integration
J. Neurosci., July 23, 2003; 23(16): 6596 - 6607.
[Abstract] [Full Text] [PDF]

P. S. McQuillen, R. A. Sheldon, C. J. Shatz, and D. M. Ferriero
Selective Vulnerability of Subplate Neurons after Early Neonatal Hypoxia-Ischemia
J. Neurosci., April 15, 2003; 23(8): 3308 - 3315.
[Abstract] [Full Text] [PDF]

H. L. Picken Bahrey and W. J. Moody
Early Development of Voltage-Gated Ion Currents and Firing Properties in Neurons of the Mouse Cerebral Cortex
J Neurophysiol, April 1, 2003; 89(4): 1761 - 1773.
[Abstract] [Full Text] [PDF]

M. Fagiolini, H. Katagiri, H. Miyamoto, H. Mori, S. G. N. Grant, M. Mishina, and T. K. Hensch
Separable features of visual cortical plasticity revealed by N-methyl-D-aspartate receptor 2A signaling
PNAS, March 4, 2003; 100(5): 2854 - 2859.
[Abstract] [Full Text] [PDF]

H. L. P. Bahrey and W. J. Moody
Voltage-gated Currents, Dye and Electrical Coupling in the Embryonic Mouse Neocortex
Cereb Cortex, March 1, 2003; 13(3): 239 - 251.
[Abstract] [Full Text] [PDF]

I. L. Hanganu, W. Kilb, and H. J. Luhmann
Functional Synaptic Projections onto Subplate Neurons in Neonatal Rat Somatosensory Cortex
J. Neurosci., August 15, 2002; 22(16): 7165 - 7176.
[Abstract] [Full Text] [PDF]

C. E. Brown and R. H. Dyck
Rapid, Experience-Dependent Changes in Levels of Synaptic Zinc in Primary Somatosensory Cortex of the Adult Mouse
J. Neurosci., April 1, 2002; 22(7): 2617 - 2625.
[Abstract] [Full Text] [PDF]

K. Futai, M. Okada, K. Matsuyama, and T. Takahashi
High-Fidelity Transmission Acquired via a Developmental Decrease in NMDA Receptor Expression at an Auditory Synapse
J. Neurosci., May 15, 2001; 21(10): 3342 - 3349.
[Abstract] [Full Text] [PDF]

I. L. Hanganu, W. Kilb, and H. J. Luhmann
Spontaneous Synaptic Activity of Subplate Neurons in Neonatal Rat Somatosensory Cortex
Cereb Cortex, May 1, 2001; 11(5): 400 - 410.
[Abstract] [Full Text] [PDF]

C. D. Galvan, R. A. Hrachovy, K. L. Smith, and J. W. Swann
Blockade of Neuronal Activity During Hippocampal Development Produces a Chronic Focal Epilepsy in the Rat
J. Neurosci., April 15, 2000; 20(8): 2904 - 2916.
[Abstract] [Full Text] [PDF]

T. Gorba, O. Klostermann, and P. Wahle
Development of Neuronal Activity and Activity-dependent Expression of Brain-derived Neurotrophic Factor mRNA in Organotypic Cultures of Rat Visual Cortex
Cereb Cortex, December 1, 1999; 9(8): 864 - 877.
[Abstract] [Full Text] [PDF]

N. P. Issa, J. T. Trachtenberg, B. Chapman, K. R. Zahs, and M. P. Stryker
The Critical Period for Ocular Dominance Plasticity in the Ferret's Visual Cortex
J. Neurosci., August 15, 1999; 19(16): 6965 - 6978.
[Abstract] [Full Text] [PDF]

E. B. Roberts and A. S. Ramoa
Enhanced NR2A Subunit Expression and Decreased NMDA Receptor Decay Time at the Onset of Ocular Dominance Plasticity in the Ferret
J Neurophysiol, May 1, 1999; 81(5): 2587 - 2591.
[Abstract] [Full Text] [PDF]

F. Conti, P. Barbaresi, M. Melone, and A. Ducati
Neuronal and Glial Localization of NR1 and NR2A/B Subunits of the NMDA Receptor in the Human Cerebral Cortex
Cereb Cortex, March 1, 1999; 9(2): 110 - 120.
[Abstract] [Full Text] [PDF]

W. Danysz and C. G. Parsons
Glycine and N-Methyl-D-Aspartate Receptors: Physiological Significance and Possible Therapeutic Applications
Pharmacol. Rev., December 1, 1998; 50(4): 597 - 664.
[Abstract] [Full Text] [PDF]

E. B. Roberts, M. A. Meredith, and A. S. Ramoa
Suppression of NMDA Receptor Function Using Antisense DNA Blocks Ocular Dominance Plasticity While Preserving Visual Responses
J Neurophysiol, September 1, 1998; 80(3): 1021 - 1032.
[Abstract] [Full Text] [PDF]

C. Trepel, K. R. Duffy, V. D. Pegado, and K. M. Murphy
Patchy Distribution of NMDAR1 Subunit Immunoreactivity in Developing Visual Cortex
J. Neurosci., May 1, 1998; 18(9): 3404 - 3415.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (60)

Citing Articles via Google Scholar

Google Scholar

Articles by Catalano, S. M.

Articles by Shatz, C. J.

Search for Related Content

PubMed

PubMed Citation

Articles by Catalano, S. M.

Articles by Shatz, C. J.