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The Journal of Neuroscience, March 15, 1998, 18(6):2129-2146
Cell- and Lamina-Specific Expression and Activity-Dependent
Regulation of Type II Calcium/Calmodulin-Dependent Protein Kinase
Isoforms in Monkey Visual Cortex
Brahim
Tighilet1,
Tsutomu
Hashikawa2, and
Edward G.
Jones1
1 Department of Anatomy and Neurobiology, University of
California, Irvine, Irvine, California 92697-1280 and
2 Laboratory of Brain Structure and Function, Frontier
Research Program in Brain Mechanisms of Mind and Behavior, Institute of
Physical and Chemical Research, Wako, Saitama 351-01, Japan
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ABSTRACT |
In situ hybridization histochemistry and
immunocytochemistry were used to study localization and
activity-dependent regulation of  ,  ,  , and  isoforms of
type II calcium/calmodulin-dependent protein kinase (CaMKII) and their
mRNAs in areas 17 and 18 of normal and monocularly deprived adult
macaques. CaMKII- is expressed overall at levels three to four times
higher than that of CaMKII- and at least 15 times higher than that
of CaMKII- and -. All isoforms are expressed primarily in
pyramidal cells of both areas, especially those of layers II-III, IVA
(in area 17), and VI, but are also expressed in nonpyramidal,
non-GABAergic cells of layer IV of both areas and in interstitial
neurons of the white matter. CaMKII- and - are colocalized,
suggesting the formation of heteromers. There was no evidence of
expression in neuroglial cells. Each isoform has a unique pattern of
laminar and sublaminar distribution, but cortical layers or sublayers
enriched for one isoform do not correlate with layers receiving inputs
only from isoform-specific layers of the lateral geniculate nucleus.
CaMKII- and - mRNA and protein levels in layer IVC of area 17 are
subject to activity-dependent regulation, with brief periods of
monocular deprivation caused by intraocular injections of tetrodotoxin
leading to a 30% increase in CaMKII- mRNA and a comparable decrease
in CaMKII- mRNA in deprived ocular dominance columns, especially of
layer IVC. Expression in other layers and expression of CaMKII-
and were unaffected. Changes occurring in layer IVC may influence
the formation of heteromers and protect supragranular layers from
CaMKII-dependent plasticity in the adult.
Key words:
plasticity; , , , and isoforms; activity-dependent regulation; visual deprivation; pyramidal cells; GABA
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INTRODUCTION |
Type II
calcium/calmodulin-dependent protein kinase (CaMKII) is involved
in many aspects of neuronal function involving calcium signaling (Braun
and Schulman, 1995 ), including plasticity of the cerebral cortex
(Glazewski et al., 1996; Gordon et al., 1996; Kirkwood et al., 1997).
This kinase exists in four known isoforms, the products of separate
genes, , , , and (Bennett et al., 1983; Bennett and
Kennedy, 1987; Hanley et al., 1987; Lin et al., 1987; Tobimatsu et al.,
1988; Tobimatsu and Fujisawa, 1989). Alternative mRNA splicing results
in the production of additional isoforms (Bennett and Kennedy, 1987;
Benson et al., 1991a; Mayer et al., 1993; Nghiem et al., 1993; Schworer
et al., 1993; Edman and Schulman, 1994; Brocke et al., 1995). Native
CaMKII is thought to consist of heteromeric and homomeric combinations
of isomers, formed by interactions at the C-terminal end of the
molecule (Lin et al., 1987; Yamauchi et al., 1989). Unmasking of a
catalytic domain in the N-terminal half of all isoforms by
Ca2+/calmodulin permits interactions with a wide
variety of substrates.
CaMKII- and - genes are expressed only in nervous tissue (Erondu
and Kennedy, 1985), but CaMKII- and - are expressed in other
tissues as well (Tobimatsu and Fujisawa, 1989). Expression of and
is neuron-specific but varies across brain regions, CaMKII-
being highest in forebrain and CaMKII- being highest in brainstem
and cerebellum (Erondu and Kennedy, 1985; Benson et al., 1992). and
isoforms also show regional differences, but whether their
expression is restricted to neurons is not clear (Takaishi et al.,
1992; Sakagami and Kondo, 1993). CaMKII- in the forebrain is with
few exceptions restricted to excitatory, glutamatergic neurons and
absent from GABA-containing (GABAergic) neurons (Benson et al., 1991b,
1992; Jones et al., 1994a,b). CaMKII- forms a major component of
postsynaptic densities (Kennedy et al., 1983; Goldenring et al., 1984;
Kelly et al., 1984) and is exclusively located at glutamatergic
synapses in the neocortex, thalamus, and hippocampus (Liu and Jones,
1996, 1997). In the hippocampus, CaMKII- is associated with the
induction of long-term potentiation (LTP) and potentially with other
forms of synaptic plasticity (Malinow et al., 1988, 1989; Malenka et
al., 1989; Silva et al., 1992; Stevens et al., 1994; Stanton and Gage,
1996).
In monkey cerebral cortex and dorsal lateral geniculate nucleus,
expression of CaMKII- is restricted to subpopulations of cells with
specific laminar locations and connections (Jones, 1988; Benson et al.,
1991b; Jones et al., 1994a; Tighilet et al., 1998). The , , and
isoforms have less-restricted distributions in the lateral
geniculate nucleus (Tighilet et al., 1998) but have not been charted in
cerebral cortex.
CaMKII- expression in cortical neurons is uniquely sensitive to
levels of activity, being upregulated when neural activity is reduced
(Hendry and Kennedy, 1986; Benson et al., 1991a) and downregulated when
activity is increased (Bronstein et al., 1992; Murray et al., 1995;
Liang and Jones, 1997). This sensitivity may underlie the role of
CaMKII- in cortical plasticity. It is unknown whether the other
three isoforms are affected by manipulations that alter cortical
activity.
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MATERIALS AND METHODS |
Eleven macaque monkeys (three Macaca fascicularis,
four M. mulatta, and four M. fuscata) aged 2 or
more years were used. Two of the animals were normal. The remaining
nine were anesthetized with ketamine, and tetrodotoxin (TTX; 15 µg in
10 µl of normal saline) was injected into the vitreous cavity of one
eye every 4 d for 7, 14, or 16 d before death. Examination of
the direct and consensual light reflexes indicated that retinal
activity remained suppressed throughout the survival period. All
procedures were approved by the appropriate Institutional Animal Care
and Use committees.
All animals were given an overdose of Nembutal and perfused through the
heart with normal saline, followed by 4% paraformaldehyde and 0.2%
glutaraldehyde in 0.1 M phosphate buffer. The brains were
post-fixed overnight at 4°C in 4% paraformaldehyde in 0.1 M phosphate buffer. Thereafter, blocks containing the
occipital lobe were cryoprotected in 30% sucrose, frozen in dry ice,
and sectioned serially at 25 µm in the frontal plane or in a plane parallel to the cortex of the occipital lobe. Alternate groups of five
sections were collected in sterile 4% paraformaldehyde for in
situ hybridization histochemistry or in 0.1 M
phosphate buffer for immunocytochemical, Nissl, or cytochrome oxidase
(CO) staining. Every 24th or 25th section was used for hybridization with sense control riboprobes or for immunocytochemical controls.
In situ hybridization
Free-floating sections were rinsed twice in 0.75% glycine in
0.1 M phosphate buffer, pH 7.4, followed by a wash in 0.1 M phosphate buffer, pH 7.4. They were then digested with
proteinase K (0.5 µg/ml in 0.1 M Tris-HCl buffer, pH 8.0, containing 0.05 M EDTA) for 8-10 min at room temperature.
Digestion was stopped with 0.25% acetic anhydride in 0.1 M
triethanolamine, pH 8.0. After two washes in 2× SSC, pH 7.0 (1× SSC
consists of 0.88% NaCl and 0.44%
Na3C6H5O3·2H2O), the sections were incubated for 1 hr at 60°C in hybridization buffer
consisting of 50% deionized formamide, 10% dextran sulfate, 5% 2×
SSC, 0.9% Ficoll, 0.9% polyvinylpyrrolidone, and 0.9% bovine serum
albumin. Just before use, 0.3 mg/ml herring sperm DNA, 0.15 mg/ml wheat
germ tRNA, and 40 mM dithiothreitol (DTT) were added. Sections were then transferred to new hybridization buffer containing one of the following radiolabeled, cRNA probes.
CaMKII riboprobes
CaMKII- riboprobes were transcribed from a cDNA encoding a
part of monkey CaMKII- that corresponds to bases 869-1185 of the
rat CaMKII- gene. The cDNA also contains a 33 base insert beginning
at nucleotide 984 of the rat sequence (Benson et al., 1991a). Antisense
riboprobes made from this cDNA recognize both CaMKII- and -33
mRNAs but do not recognize mRNAs for other kinase isoforms. Full
details of the procedures used for isolating this and other cDNAs using
synthetic oligonucleotide probes and PCR are given in Benson et al.
(1991a).
CaMKII- riboprobes were transcribed from a 770 bp human cDNA
(P. J. Isackson, unpublished) (see Tighilet et al., 1998) that corresponds to bases 550-1320 of rat CaMKII- (Bennett and Kennedy, 1987). Antisense riboprobes made from this cDNA recognize both CaMKII- and -' subunit mRNAs but do not recognize mRNAs for other
kinase isoforms.
CaMKII- riboprobes were transcribed from a 546 bp cDNA (P. J. Isackson and K. D. Murray, unpublished) (see Tighilet et al., 1998) that corresponds to bases 913-990 and 1060-1527 of the human c subunit (Nghiem et al., 1993).
CaMKII- riboprobes were transcribed from a 570 bp cDNA (K. D. Murray and P. J. Isackson, unpublished) (see Tighilet et al., 1998) that corresponds to bp 1213-1782 of the rat subunit
(Tobimatsu et al., 1988).
Sense and antisense riboprobes were transcribed in the presence of
[-33P]UTP or -35S-UTP. All riboprobes
had similar G/C ratios and similar specific activities. The
hybridization solution contained 1 × 104
cpm/µl of riboprobe. After a 20-36 hr incubation at 60°C, the sections were washed sequentially as follows: twice for 30 min each in
4× SSC at 60°C; for 45 min to 1 hr with ribonuclease A (0.02 mg/ml
in 0.01 M Tris-HCl buffer, pH 8.0, 1 mM EDTA,
and 2.9% NaCl) at 45°C; twice for 30 min each in 2× SSC at room
temperature; twice for 30 min each in 0.5× SSC at 60°C; and twice
for 15 min each in 0.1× SSC at room temperature.
Hybridized sections were mounted on gelatin-coated glass slides, dried,
placed in contact with Amersham -Max film, and exposed for 1-15 d.
Sections hybridized with CaMKII- riboprobes were in many cases
exposed for less time than were those hybridized with CaMKII-, -,
or - riboprobes (see Results). After development of the film, the
slides were lipid extracted in chloroform and ethanol, dipped in Kodak
NTB2 emulsion, and exposed at 4°C for 4-8 weeks. The emulsion
autoradiographs were developed in Kodak D-19, fixed, counterstained
with cresyl violet, dehydrated, cleared, and coverslipped in DPX.
Control sections hybridized with sense riboprobes showed no
hybridization above a weak background level.
Immunocytochemistry
The following monoclonal antibodies or polyclonal antisera
were used.
CaMKII-. Anti-CaMKII- is a well-characterized mouse
monoclonal antibody (Erondu and Kennedy, 1985) specific for the subunit. It was a gift from Dr. M. B. Kennedy and was also
obtained from Boehringer Mannheim (Indianapolis, IN).
CaMKII-. Two antibodies to CaMKII- were used. A rat
monoclonal antibody, cB -1, characterized in Scholz et al. (1988), was a gift from Dr. H. Schulman. A goat polyclonal antiserum raised against a peptide corresponding to amino acids 521-540 at the C-terminal end of mouse CaMKII- was obtained from Santa Cruz Biotechnology (Santa Cruz, CA).
CaMKII-. A goat polyclonal antiserum raised against a
peptide corresponding to amino acids 478-495 at the C-terminal end of
human CaMKII- was obtained from Santa Cruz Biotechnology.
CaMKII-. A goat polyclonal antiserum raised against a
peptide corresponding to amino acids 515-533 at the C-terminal end of
rat CaMKII- was obtained from Santa Cruz Biotechnology.
All antibodies were diluted 1:500, except anti-CaMKII- which was
diluted 1:1000. Sections were preincubated in 0.05% Triton X-100 and
3% normal serum in 0.1 M phosphate buffer. They were transferred to the same solution to which the diluted antibody or
antiserum had been added. After 36-48 hr at 4°C, the sections were
treated with avidin-biotin peroxidase kits (Vector Laboratories, Burlingame, CA) and reacted in 0.05%
3,3'-diaminobenzidine-tetrahydrochloride plus 0.01%
H2O2 to visualize bound antibodies. Control
sections were incubated in 0.1 M phosphate buffer, pH 7.4, containing normal serum instead of the primary antibody and showed no
staining above a weak, nonspecific background. The sections were
finally mounted on gelatin-coated slides, dehydrated, and coverslipped.
Adjacent sections were reacted for cytochrome oxidase or mounted and
stained with 0.25% thionin.
For double immunocytochemical staining, the indirect immunofluorescent
technique was used. To examine potential colocalization of CaMKII-
and CaMKII-, sections were incubated simultaneously in mouse
anti-CaMKII- and rat anti-CaMKII- at the same concentrations given above, in 0.1 M phosphate buffer containing 3% goat
serum, 3% rabbit serum, and 0.24% Triton X-100, for 24 hr at 4°C.
After washing, the sections were incubated in a mixture of 1:100
rhodamine-conjugated goat anti-mouse IgG (Chemicon, Temecula, CA) and
1:100 fluorescein-conjugated rabbit anti-rat IgG (Vector) in phosphate
buffer containing 3% goat serum, 3% rabbit serum, and 0.25% Triton
X-100. Sections were mounted under coverslips on glass slides in a 1:3
mixture of 0.1 M phosphate buffer and glycerol. To
demonstrate the lack of colocalization of CaMKII- or CaMKII- with
GABA, sections were incubated first for 24 hr at 4°C in a mixture of
1:3000 mouse anti-CaMKII- and 1:5000 rabbit anti-GABA antiserum
(Sigma, St. Louis, MO) in 0.1 M phosphate buffer containing
3% horse serum, 2% bovine serum albumin, and 0.25% Triton X-100.
After washing, sections were reincubated in a mixture of 1:100
fluorescein-conjugated horse anti-mouse (Vector) and 1:100
rhodamine-conjugated donkey anti-rabbit (Chemicon) IgGs in 0.1 M phosphate buffer containing 3% horse serum, 2% bovine
serum albumin, and 0.25% Triton X-100. Other sections were incubated
first in a mixture of 1:500 rat anti-CaMKII- and 1:500 rabbit
anti-GABA, followed by a mixture of 1:100 fluorescein-conjugated
rabbit anti-rat (Vector) and 1:100 rhodamine-conjugated donkey
anti-rabbit (Chemicon) IgGs in 0.1 M phosphate buffer
containing 3% rabbit serum, 2% bovine serum albumin, and 0.25%
Triton X-100. All sections were mounted in glycerol and phosphate
buffer as described above. Sections were then examined in an
epifluorescence microscope equipped with fluorescein- and
rhodamine-exciting filters. It was not possible to obtain double
staining for CaMKII- or CaMKII- and the other two isoforms or for
CaMKII- or CaMKII- and GABA.
Quantification
At least one film autoradiogram from each normal and monocularly
deprived animal, showing the results of hybridization with each probe,
was quantified by densitometry using a microcomputer imaging device
(MCID/M4; Imaging research, Inc., St. Catharines, Ontario, Canada).
Optical density readings were taken in scans of defined width across
the thickness of areas 17 or 18 from pia mater to white matter or in
tangential sections across several ocular dominance columns in layer
IVC. The laminae of the cortex were then identified by comparison with
digitized images of adjacent Nissl-stained sections, and ocular
dominance columns were identified by comparison with similarly
digitized images of the relevant parts of adjacent CO-stained sections.
Background readings were taken over the white matter subjacent to the
cortex and subtracted from readings taken over the cortex. Absolute
values of radioactivity were determined from 14C plastic
standards (Amersham, Arlington Heights, IL) exposed on the same sheet
of film. No attempt was made to quantify the immunocytochemical
preparations.
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RESULTS |
Levels of CaMKII mRNAs in normal visual cortex
In both areas 17 and 18, the highest levels of expression were
observed for CaMKII- mRNA. CaMKII-, -, and - mRNAs were more weakly expressed, with being stronger than and .
Autoradiograms for the latter two commonly had to be exposed for longer
times to visualize patterns of laminar distribution. Optical density measurements made on sections from the same brains hybridized at the
same time and exposed for the same period on the same piece of film
gave the following mean figures for levels of each mRNA (in nCi per
gm): for CaMKII- in area 17, 2007.53 ± 109.17, and in area 18, 1510.71 ± 93.67; for CaMKII- in area 17, 635.18 ± 18.13, and in area 18, 599.71 ± 3.88; for CaMKII- in area 17, 149.68 ± 2.95, and in area 18, 138.02 ± 8.97; and for
CaMKII- in area 17, 157.08 ± 9.12, and in area 18, 131.07 ± 7.12.
Apart from different densities overall, patterns of labeling in
relation to cortical layers and sublayers in areas 17 and 18 were
unique for each subunit mRNA (Figs.
1A,
2) and will be described sequentially
below. For CaMKII- mRNA, intense autoradiographic labeling was seen
on film autoradiograms after an exposure of only 2-3 d. Effective
labeling could be detected for CaMKII- after 2-3 d, but more
intense labeling was obtained after 5-8 d. Effective laminar labeling
for CaMKII- and CaMKII- mRNAs required exposure times of 11-15
d.
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Figure 1.
Autoradiograms of surface parallel sections near
the occipital pole of the same M. fuscata brain that
were hybridized to radioactive RNA probes complementary to CaMKII-
(CAM-), CaMKII- (CAM-), CaMKII- (CAM-), and CaMKII-
(CAM-) mRNAs. A is more superficial than B-D which are closely adjacent to one another.
Arrows indicate the border between areas 17 and 18. A was exposed for 3 d, B was exposed
for 5 d, and C and D were exposed
for 11 d to reveal laminar densities of hybridization. For true
relative differences in overall densities of expression, see Figure 2.
Scale bar, 1 mm.
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Figure 2.
Integrated optical density readings (IOD)
converted to measures of radioactivity (nCi/gm) by reference to
standards exposed on the same sheet of film and taken in traverses of
constant width across the thickness of areas 17 and 18 in
autoradiograms similar to those of Figure 1 but exposed for the same
time on the same sheet of film. These reveal laminar patterns of
expression as well as relative levels of expression of the four CaMKII
isoforms. Note that the scales of the y axes differ.
Roman numerals on the x axes of the
top graphs represent positions of cortical layers in all
scans, as determined from optical density readings of adjacent Nissl-stained sections.
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Laminar distribution of CaMKII mRNAs in normal visual cortex
Localization of CaMKII- mRNA across layers of areas 17 and 18 was in conformity with previous descriptions (Benson et al., 1991a),
but patterns of expression of CaMKII-, -, and - were quite
unlike that of CaMKII-. CaMKII- is expressed most highly in cells
of layers II-III, IVA, and VI in area 17 and in cells of layers
II-III and VI in area 18. CaMKII- in area 17 was expressed most
heavily in cells of layers IVA, IVC, and VI and less heavily in cells
of layers II-III. In area 18, CaMKII- was expressed mainly in
layers IIIB and VI. CaMKII-, although much less densely expressed,
had a laminar pattern more similar to that of CaMKII- than of
CaMKII-, whereas CaMKII- was more similar to CaMKII- in
laminar pattern but with the relative densities in layers II-III and
layer VI reversed. In the sections that follow, areas 17 and 18 will be
described serially, and their layers will be given in order of highest
to lowest density of labeling.
CaMKII-
Area 17. Autoradiographic labeling for CaMKII- mRNA
was densest in layer II and in the upper two-thirds of layer III (Figs. 1A, 3A).
Superficial to the dense band of labeling corresponding to these
layers, layer I was unlabeled. A zone of relatively weaker labeling
characterized the deepest aspect of layer III; this was replaced deeply
by a dense band of labeling corresponding to layer IVA. Layer IVB was
weakly labeled; then labeling increased somewhat in layer IVC and
increased further in layer IVC, forming a thin dense band in which
hybridization intensity was approximately the same as that observed in
deep layer III. The weakest density of labeling, apart from layer I,
was found in layer V. Labeling began to increase in the deep part of
layer V and became intense again in layer VI, particularly in its
superficial part. The border between layer VI and the underlying white
matter was not sharply defined, labeling falling off gradually into the
superficial 100 µm of the white matter. In this region, a large
number of individually labeled cells could be detected.
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Figure 3.
Pairs of dark-field (left) and
bright-field (right) photomicrographs from the same
counterstained emulsion autoradiograms showing relative densities and
laminar patterns of expression of the four CaMKII mRNAs in areas 17 (A, C, E,
G) and 18 (B, D, F, H). More diffuse labeling for
CaMKII-, tending to obscure borders between layers at this
magnification, reflects the high levels of the mRNA in dendrites of
pyramidal cells (Benson et al., 1991a). Scale bar, 100 µm.
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When examined in dark field in emulsion autoradiographs (Fig.
3A), the labeling pattern for CaMKII- mRNA was
characteristically diffuse, as reported previously (Burgin et al.,
1990; Benson et al., 1991a; Jones et al., 1994b). The presence of large
amounts of the mRNA in dendrites obscures the labeling of individual
cell somata, except when inspected at high magnification (Fig.
4A). Only the labeling
of large somata in layer IVA was distinct at low magnification (Fig.
3A).
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Figure 4.
High-magnification photomicrographs from emulsion
autoradiograms showing hybridization of cRNAs specific for each of the
CaMKII mRNAs to neurons in layer VI of area 17 (A), layer V of area 18 (B), layer III of area 18 (C), and layer VI of area 17 (D). Arrows indicate nuclei of
neuroglial cells which are not labeled. Scale bar, 10 µm.
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Area 18. Labeling with CaMKII- riboprobes was
distinguished by the presence of two major bands of hybridization, one
corresponding to deep layer III and the other to layer VI (Figs.
1A, 3B). Large labeled cell somata could
be detected in both bands, but labeling was, as in area 17, generally
diffuse.
CaMKII-
Area 17. The densest labeling was observed in layer VI
(Fig. 1B). A high density was also detected in layer
IVC, and there was a thin band of relatively high density in layer IVA.
A moderate density of labeling was present in layers II and III. The
weakest labeling was in layers I, IVB, and V, although a thin line of slightly enhanced labeling could be detected in deep layer V. Labeling
was not diffuse like that observed with CaMKII- mRNA labeling, and
individual cell somata were clearly defined by overlying silver grains,
the labeling of the neuropil being much less than that with CaMKII-
riboprobes (Figs. 3C, 4B).
Area 18. Two peaks of denser labeling corresponded to deep
layer III and layer VI (Figs. 1B, 3D). In
these layers, large neuronal somata were clearly labeled. Labeling was
relatively weak in layer II and the remainder of layer III and in
layers IV and V, although a thin band of enhanced labeling could be
seen at the border of layers IV and V. This contained a line of
interrupted large, labeled cell somata.
CaMKII-
Area 17. Labeling for CaMKII- mRNA was weak, but
there was one band of heightened labeling that corresponded to layer
VI, especially to its superficial half (Fig. 1C). Here,
labeled cell somata could be seen. Other faintly enhanced bands of
labeling could be detected in layers IVA and IVC (Figs. 1C,
3E). Layers II and superficial III showed some enhancement
of labeling, and there was a thin line of label in the middle of layer
V, corresponding to an interrupted line of labeled large cell
somata.
Area 18. Labeling for CaMKII- mRNA was extremely weak but
showed a band of slightly enhanced hybridization corresponding to deep
layer III (Fig. 3F) and a thin similarly enhanced
band corresponding to layer VI (Fig. 1C). In deep layer III,
many large neuronal somata were labeled.
CaMKII-
Area 17. Labeling for CaMKII- mRNA showed a unique
pattern of laminar distribution quite unlike that for the other three mRNAs (Fig. 1D). Layer VI, especially its superficial
half, was labeled most densely. A band of relatively intense
hybridization was found in layer II and superficial layer III. Layers
IVC and IVA appeared as two bands of moderately dense labeling with
large neuronal somata labeled in layer IVA (Fig. 3G).
Labeling of layer IVC was weak, although not quite as weak as
that of layer IVB.
Area 18. There were very low levels of hybridization in area
18. Weakly enhanced bands of labeling corresponded to layers II and VI.
Large cell somata were clearly labeled in deep layer III (Fig.
3 H).
Laminar and cellular distribution of CaMKII immunostaining in
normal visual cortex
Immunocytochemistry for each of the four isoforms revealed
staining densities comparable to those seen with in situ
hybridization histochemistry. In some cases, especially for CaMKII-,
bands of neuropil staining indicating stained axonal ramifications did not match the locations of cell somata labeled by cRNA probes.
For all four isoforms, by far the most prominent immunostained cells
were pyramidal, but closer inspection revealed the presence of
significant numbers of stained small, round neuronal somata as well,
primarily in layer IV of each area. This reflected the staining of
nonpyramidal cells, shown in a later section to be non-GABAergic.
Although no counts were done, qualitatively only a subpopulation of
pyramidal cells in any layer was labeled for CaMKII-, -, -, or
-. This was also observed for CaMKII- in the sensory-motor areas
in which <50% of the total cell population was labeled (Jones et al.,
1994b).
CaMKII-
Immunoreactivity for CaMKII- was similar to that briefly
described by Hendry and Kennedy (1986). Staining was particularly dense
in areas 17 and 18 and included both cell and neuropil staining (Fig.
5A,B). Many cells were stained
in both areas (Fig.
6 A-E).
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Figure 5.
Photomicrographs from pairs of adjacent sections
stained immunocytochemically (left) for one of the four
CaMKII isoforms or with thionin (right) and showing the
laminar patterns of immunostaining in areas 17 (A,
C, E, G) and 18 (B, D, F,
H). Dense neuropil staining in the absence of
somal staining (e.g., layers IVA and V of area 17) reflects
immunostaining of axons and dendrites. Scale bar, 100 µm.
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Figure 6.
High-magnification photomicrographs showing
immunostaining of cells in different layers of areas 17 or 18 for
CaMKII- (A-E) or CaMKII-
(F, G). (These are different sections
from those shown in Fig. 5.) Note the staining of pyramidal cells in
all layers and the staining of small round cell somata in layers IVC
(area 17) and IV (area 18). WM, White matter. Scale bar,
150 µm.
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Area 17. Cells were stained in all layers except layer I and
the greater part of layer V. There were many stained cells in the white
matter subjacent to layer VI. Neuropil staining did not always reflect
cell staining patterns. For example, there was a dense neuropil band
corresponding to layer V. This probably reflected staining of
collateral branches of the axons of pyramidal cells in supragranular
layers, the collaterals of which contribute to the inner band of
Baillarger (Lund et al., 1994). Other dense bands were coextensive with
layers I and II, IVA, IVC, and the deeper half of layer VI. Although
at low magnification layer IV appeared weakly stained (Fig.
5A), there were many well-stained, small round cell somata
in layers IVC and IVC, with fewer in layer IVB (Fig.
6A). Large cells, many of them pyramidal in shape, their stained apical dendrites giving layers IVC through VI a pattern
of radial striping, were stained in layers III, IVA, and VI. Smaller
pyramidal cells were stained in layers II and III.
Area 18. Immunostaining was also characterized by heavy
staining of many cells except in layers I and V. The latter, as in area
17, was coextensive with a band of neuropil staining, although this was
much weaker than was seen in area 17. Although containing fewer stained
cells than other layers, layer V at intervals contained a number of
very well-stained large pyramidal cells. Pyramidal cells were also
stained in layers II, III, and VI, and many small round neuronal somata
were lightly stained in layer IV. There was dense staining of the
neuropil in layers I and II.
CaMKII-
Immunostaining for CaMKII- was also dense and included staining
of many neuronal somata (Figs. 5C,
6F).
Area 17. There was denser neuropil staining in bands
corresponding to layers IVA and IVC. The band in layer IVA was
broken at intervals in a manner similar to that seen with cytochrome oxidase staining of this layer. The band in layers IVC and IVC contained many stained small cells. There were concentrations of
well-stained larger cells in layers II, IVB, and upper VI. Fewer were
found in layer V, and none in layer I. Many of the cells were pyramidal
in shape with well-stained apical dendrites, giving the deeper layers a
radially striped appearance. There were many stained cells in the
superficial white matter.
Area 18. Immunostaining was relatively weak in layer IV
(Figs. 5D, 6G). There were bands of enhanced
neuropil staining in the upper part of layer V as well as in layers II
and VI. There were many stained cells throughout all layers, except
layer I, and in the superficial white matter. The staining of large
pyramidal cells in deep layer III was especially prominent. Stained
dendrites of pyramidal cells located in deeper layers gave the cortex a radially striped appearance.
CaMKII-
Area 17. Cells were clearly stained for CaMKII-, but
neuropil staining was particularly weak (Fig. 5E), and the
staining of cells was characterized by an unusual, fragmented
appearance (Fig. 7A), the
profiles of the stained cells not being continuous as was seen with
CaMKII- and CaMKII- immunostaining. The neuropil staining was
weakest in layers I and IVB, although occasional stained cells were
found in the latter. There were prominent bands of stained cells in
layers IVB and IVC and in the superficial half of layer VI. The
smallest number of stained cells was in layer V, although some very
large, heavily stained cells occasionally appeared in its deepest
aspect (Fig. 7A). The radial staining of the deeper layers
found with CaMKII- and CaMKII- immunostaining was absent. Many
small cell somata were outlined by neuropil staining in layer IVC,
but the somata themselves lacked staining. No cells were stained in the
white matter.
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Figure 7.
A-D, Bright-field photomicrographs
showing immunostaining of cells for CaMKII- or CaMKII- in deeper
layers of areas 17 and 18. The isolated large neuronal somata stained
in layer V of area 17 are those of Meynert cells. Scale bars, 150 µm.
E, F, Fluorescence micrographs from the
same microscopic field showing double staining of cells in layer III of
area 17 for CaMKII- (E, rhodamine immunofluorescence) and CaMKII- (F, fluorescein immunofluorescence).
Scale bar, 10 µm.
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Area 18. Many pyramidal cells were stained against a
background of relatively weak neuropil staining (Fig.
5F). There were scattered but well-stained pyramidal
cells in layer V (Fig. 7B), and more weakly stained cells
were found in all layers, except layer I, and in the superficial white
matter.
CaMKII-
Immunoreactivity for CaMKII- was weakest of the four isoforms,
but staining of neuronal somata was more distinct than for CaMKII-.
Many neuronal somata were stained in both areas, including the
superficial white matter. Many were pyramidal in shape, but small round
somata were also stained in layer IVC of area 17. There were also a few
rather well-stained larger pyramidal cells in deep layer V of both
areas (Fig. 7C,D), and there was an enhancement of neuropil
staining in bands in both areas 17 and 18 (Figs. 5G,H, 7C,D).
Area 17. Bands corresponded to layers IVA and IVB, the
middle of layer V, and layer VI. There was very weak staining of layers I through III.
Area 18. Neuropil staining was even weaker in area 18 than
in area 17, although there was enhancement in deep layer III and in
layer VI (Fig. 5H). Layers I and IV were weakest of
all.
Colocalization of CaMKII- and CaMKII- in non-GABA cells
Immunofluorescent staining revealed localization of CaMKII- and
CaMKII- in pyramidal cells (Fig.
8A-D) of all layers of areas 17 and 18, as well as in small round cells (Fig.
8A,C) of layer IVC in area 17 and of layer IV in area
18. No CaMKII-- or CaMKII--immunoreactive neuron showed
colocalization of GABA immunoreactivity (Fig. 8A-D)
in any layer or in the subcortical white matter. In layer IVC of area
17 or layer IV of area 18, small round CaMKII-immunoreactive somata
were significantly smaller in diameter than were the largest
GABA-immunoreactive somata, as reported previously (Jones et al.,
1994a,b).
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Figure 8.
Paired fluorescence photomicrographs from the same
microscopic fields stained for CaMKII- (CAM-) and
GABA (A-D) or for CaMKII- (CAM-) and GABA (E-H).
A, B, E, F,
From layer III of area 17 and showing CaMKII- and -
immunoreactivity in pyramidal cells but not in GABA cells.
C, D, G, H,
From layer IVC of area 17 and showing CaMKII- and -
immunoreactivity in small, presumably spiny stellate cells and not in
GABA cells. In the CaMKII-- or CaMKII--immunostained member of
each pair of micrographs, the unstained GABA cells are indicated by
asterisks. Scale bar, 10 µm.
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Double immunofluorescent staining for CaMKII- and CaMKII- showed
virtually complete colocalization (Fig. 7E,F) of the
two isoforms in all layers of both areas, including in the interstitial cells of the white matter.
It was not possible to obtain satisfactory double staining using the
CaMKII- or CaMKII- antibodies, because of the low levels of these
antigens.
Response to monocular deprivation
In area 17, both immunoreactivity and mRNA levels for CaMKII-
and CaMKII- were affected by monocular deprivation induced by TTX
injections (Figs.
9-11).
No changes were detected for CaMKII-, and CaMKII- showed
inconsistent equivocal changes (Fig.
12). For CaMKII- and CaMKII-,
effects were most pronounced in layer IVC. The pattern of
localization, from its normal homogeneity in that layer, became one of
alternating lightly and densely immunostained or cRNA-labeled stripes
(Figs. 9, 10). Comparison with adjacent sections stained for CO showed
that unilateral deprivation induced opposite effects on CaMKII- and
CaMKII-. For CaMKII-, the darkly immunostained or more intensely
hybridized stripes were almost exactly coextensive with lightly
CO-stained stripes that corresponded to the deprived eye, and the
lightly immunostained or hybridized stripes were coextensive with the
darkly CO-stained stripes corresponding to the undeprived eye. In all
cases, the denser immunostained or hybridized stripes were more
intensely labeled in layer IVC then in layer IVC of the deprived
ocular dominance stripes. For CaMKII-, lightly immunostained or
hybridized stripes in layer IVC corresponded to deprived ocular
dominance stripes when matched to the adjacent, CO-stained sections
(Fig. 11) but mainly to the central parts of the deprived stripes.
There were hints of a deprivation effect in striped immunostaining in
layer VI for CaMKII-.
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Figure 9.
Pairs (A, B;
C, D) of adjacent sections from area 17 stained immunocytochemically for CaMKII- (A)
or CaMKII- (C) or for CO (B,
D). Sections are from a M. fascicularis
(A, B) and a M. fuscata
(C, D) monkey subjected to monocular TTX
injections for 7 d. Zones of reduced CO staining in layer IVC
represent ocular dominance columns related to the deprived eye.
CaMKII- immunostaining is enhanced and CaMKII- immunostaining is
reduced in regions corresponding to the deprived columns, especially in
layer IVC. Arrows in A and
B and circles in C and
D indicate the same blood vessels. Scale bars:
A, B, 250 µm; C,
D, 500 µm.
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Figure 10.
A, Autoradiogram from a surface
parallel section through area 17 of a M. fuscata monkey
monocularly deprived for 7 d. The section was hybridized with a
CaMKII- riboprobe. B, An adjacent section stained for
CO. C, D, Enlargements of upper
parts of A and B.
Circles indicate the same blood vessels. Scale bars:
A, B, 2 mm; C,
D, 1 mm. E, F, Optical
density scans made across layer IVC in regions indicated by the
lines between the arrows in
C and D converted to measures of
radioactivity to show enhancement of CaMKII- mRNA levels in deprived
ocular dominance columns, the positions of which can be determined by
matching to the zones showing reduced CO staining and lowered optical
density.
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Figure 11.
A, Autoradiogram from a surface
parallel section through area 17 of a M. fuscata monkey
monocularly deprived for 16 d. The section was hybridized with a
CaMKII- riboprobe. B, An adjacent section stained for
CO. C, D, Enlargements of middle
regions of A and B.
Circles indicate the same blood vessels, and
arrows indicate the same deprived ocular dominance
columns in layer IVC. E, F, Optical
density scans made along the lines indicated in
C and D and showing decreased CaMKII-
mRNA levels in the deprived ocular dominance columns. Scale bars:
A, B, 2 mm; C,
D, 500 µm.
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Figure 12.
A, C,
Autoradiograms of sections through area 17 of a M.
fuscata monkey monocularly deprived for 7 d.
A, Section hybridized to a CaMKII- riboprobe.
C, Section hybridized to a CaMKII- riboprobe. Sections have been exposed for 15 d. B,
D, The adjacent CO-stained sections. No deprivation
effect can be detected for either mRNA. Scale bar, 2 mm.
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Optical density measurements indicated that there was an enhancement of
CaMKII- mRNA by ~30% in deprived ocular dominance stripes of
layer IVC (Fig. 10E,F) and a decrease of
CaMKII- mRNA of ~25% (Fig. 11E,F). No
changes in the distribution or density of mRNA labeling could be
detected in layers other than layer IVC. The CO-rich blobs of layers II
and III appeared unaffected. No changes were detected in area 18. No
quantitative changes could be detected in CaMKII- or - mRNAs.
| |
DISCUSSION |
CaMKII and neuron-specific expression
Expression of CaMKII-, -, and - isoforms was
exclusively neuronal. CaMKII- is also neuronal, but its additional
expression in neuroglial cells could not be excluded because of very
low levels of CaMKII- mRNA and protein. For all four isoforms,
pyramidal cells are the predominant expressing cell, but CaMKII- and
CaMKII- and probably CaMKII- and - are expressed in
nonpyramidal cells as well, especially in layer IVC of area 17 and in
layer IV of area 18. Although CaMKII- is expressed at much higher
levels overall than is CaMKII-, the in situ pattern
suggests that layer IVC cells may express CaMKII- at higher levels
relative to pyramidal cells of layers II-III than CaMKII- (Fig.
1).
Nonpyramidal cells expressing CaMKII- or - were non-GABAergic.
This and laminar localization suggest expression in spiny stellate
cells, the second major form of cortical excitatory cell. Interstitial
cells of the white matter labeled for CaMKII-, -, and - are
another form of non-GABAergic, nonpyramidal cell. It could not be
proven conclusively, because of low immunostaining levels, that
CaMKII- and - are also expressed only in pyramidal and
non-GABAergic nonpyramidal cells. Because CaMKII- and -, unlike
CaMKII- and -, are expressed in many tissues outside the nervous
system, the possibility of their less-restricted neuronal expression
should be considered.
Relative laminar densities of hybridization in areas 17 and 18 varied
for each isoform, but for all, the major pyramidal cell populations
labeled were in layers II-III, IVA (in area 17), and VI. Smaller
numbers of large pyramidal cells in deep layer V and of modified
pyramidal cells in layer IVB of area 17 were also labeled for all
isoforms. This may indicate that a very specific subpopulation of
pyramidal cells expresses the CaMKII isoforms. A similar staining
pattern occurs with other markers, e.g., nonphosphorylated neurofilament protein (Hof and Morrison, 1995, Hof et al., 1995), and
seems to reflect staining of pyramidal cells with particular connectional relationships. This may be the most likely relevance of
the preferential labeling of the pyramidal cell subpopulations in the
present study (see below). However, strong activity-dependent regulation of CaMKII- (Bronstein et al., 1992; Liang et al., 1996;
Liang and Jones, 1997; see below) raises the possibility of an
activity-dependent effect. Compensation for lack of expression of one
isoform by upregulation of another seems unlikely from the consistency
of the subpopulation labeled for each isoform and by the almost
complete coexpression of CaMKII- and - that may imply formation
of heteromeric combinations of the two.
CaMKII and cortical connectivity
High levels of expression of CaMKII- in supragranular pyramidal
cells-the sources of the majority of corticocortical and commissural
fibers (for review, see Casagrande and Kaas, 1994)-imply that cortical
plasticity dependent on CaMKII- will be reflected directly onto
other areas of the cortex. In area 17, consistent expression of all
four isoforms in layer IVA implies association with the large pyramidal
cells that project selectively to cytochrome oxidase-stained thick
stripes of layer III in area 18 (Livingstone and Hubel, 1987a; Levitt
et al., 1994), part of a pathway dominated by inputs from
broad-band-sensitive cells of the magnocellular layers in the dorsal
lateral geniculate nucleus (Livingstone and Hubel, 1987b, 1988). High
levels of expression in layer VI cells from which the majority of
corticothalamic projections arise and the particular association of
CaMKII- with corticothalamic synapses (Liu and Jones, 1996) imply
that the thalamus will also be influenced. Higher expression in upper
layer VI, from which fibers to the parvocellular geniculate layers
arise (Lund et al., 1975), suggests a particular association with those
layers.
The relative absence of expression of all four isoforms in layer V was
a striking feature, but equally striking was the intense immunostaining
of a few large pyramidal cells and a corresponding thin line of mRNA
labeling in the middle or deep aspect of that layer, especially for
CaMKII-, -, and -. The large pyramidal cells are likely to be
cells the axons of which descend to the pulvinar, pretectum, and tectum
(Lund et al., 1975; Trojanowski and Jacobson, 1976), but they may also
represent Meynert cells with projections to extrastriate cortical
fields (Fries et al., 1985).
There was no particular correlation between enhanced expression in
layers or sublayers of area 17 and that in laminae of the dorsal
lateral geniculate nucleus projecting to those layers. In the lateral
geniculate nucleus, CaMKII- is specifically expressed in neurons of
the S laminae and interlaminar zones (Benson et al., 1991b; Tighilet et
al., 1998) that project to superficial layers of areas 17 and 18, including the CO-rich blobs of area 17 (Yukie and Iwai, 1981;
Livingstone and Hubel, 1982; Fitzpatrick et al., 1983; Weber et al.,
1983; Hendry and Yoshioka, 1994). Blobs in area 17 are enriched in
CaMKII- but to no greater extent than the rest of layers II-III.
The other three isoforms are expressed in relay cells of the parvo- and
magnocellular laminae of the lateral geniculate nucleus, as well as in
the S laminae and interlaminar zones (Tighilet et al., 1998). The
parvocellular laminae project to layers IVA and IVC of area 17, whereas the magnocellular layers project to layer IVC (Hubel and
Wiesel, 1972; Blasdel and Lund, 1983). CaMKII- and - are enriched
in layers IVA and IVC, whereas CaMKII- and - are enriched in
layers IVA, IVC, and IVC. There is no obvious correlation here,
except that parvocellular geniculate cells gain access to cells
enriched for CaMKII-, -, -, and -, whereas magnocellular
geniculate cells gain access primarily to cells enriched for CaMKII-
and -.
CaMKII and cortical plasticity
Upregulation of CaMKII- expression in deprived ocular dominance
columns of layer IVC in area 17 confirmed previous reports at protein
(Hendry and Kennedy, 1986) and mRNA (Benson et al., 1991a) levels. The
equally striking downregulation of CaMKII- in the same columns is a
new finding. Both effects are considerable; at the mRNA level, deprived
columns change by ~30% in each case. The most robust effects were on
layer IVC, implying that the major group of recipient cells in the
wavelength-specific thalamocortical pathway is most affected in the
cortex.
CaMKII- is involved in induction of LTP at hippocampal synapses
(Malenka et al., 1989; Malinow et al., 1989) and in
experience-dependent plasticity of adult somatosensory cortex
(Glazewski et al., 1996). In visual cortex, it is essential for
induction of LTP in supragranular layers of adult but not infant
animals (Kirkwood et al., 1997) and is partially involved in ocular
dominance plasticity of the same layers during the neonatal critical
period (Gordon et al., 1996). In these layers, CaMKII- is highly
expressed, but only in the non-GABAergic pyramidal cells (Jones et al.,
1994b; present study). In these cells, it is concentrated at
postsynaptic densities of glutamatergic synapses (Liu and Jones, 1996),
undoubtedly reflecting the association of CaMKII- and NMDA receptors
in cortical LTP (Artola and Singer, 1987). Despite the involvement of
CaMKII- in adult, experience-dependent plasticity at these synapses,
monocular deprivation in the present study did not affect CaMKII-
gene expression in layers II-III. This is surprising, given that
deprivation for the same period results in effects on GABA, GAD,
tachykinin, and GABAA receptor gene expression in layers
II-III that parallel those in layer IVC, especially in the CO-rich
blobs (Hendry and Jones, 1986; Hendry et al., 1988, 1994; Benson et
al., 1994; Huntsman et al., 1994). Induction of LTP in supragranular
neurons of cat and rat visual cortex by stimulation of afferent fibers
depends on reduction of intracortical inhibition (e.g., Artola et al., 1990; Bear et al., 1992; Tsumoto, 1992), but LTP can be induced without
disinhibition if layer IV is stimulated directly (Kirkwood and Bear,
1994). This implies that layer IV may normally exert a gating effect
over afferent-induced plasticity in the supragranular layers.
In the present study, inhibition should be reduced in the deprived
ocular dominance columns because GABA production and GABAA receptors will be markedly downregulated in layer IVC (see above). The
complementary effects on CaMKII- and - may therefore be part of a
response to restore the balance of excitation and inhibition to layer
IV, serving to protect the supragranular layers from the consequences
of deprivation in adults. Upregulation of CaMKII- can be seen as an
attempt to compensate for reduced input by engaging cellular mechanisms
that should enhance excitatory transmission. This could be a key
feature in protecting the cortex from the consequences of deprivation.
By also engaging intracellular mechanisms that inhibit neuronal growth,
the upregulated CaMKII- could limit potential sprouting that would
be maladaptive. Until more is known about CaMKII-, it is difficult
to predict the extent to which downregulation of this isoform also
represents a compensatory response in the same cells. This would be
likely if the two isoforms, shown here to be colocalized, normally form
heteromers in layer IVC cells. There is, however, increasing evidence
of differential intracellular localization and trafficking of
CaMKII- isoforms (Brocke et al., 1995). In this case, the opposite
effects on CaMKII- and and the lack of effects on CaMKII- or
may reflect responses of entirely different intracellular signaling
systems.
| |
FOOTNOTES |
Received Nov. 11, 1997; revised Jan. 7, 1998; accepted Jan. 12, 1998.
This work was supported by Grant NS21377 from the National Institutes
of Health, United States Public Health Service, and by the Frontier
Research Program, Japan. B.T. was supported by a grant from Fondation
Fyssen (Paris, France). We thank Drs. P. J. Isackson and K. D. Murray for providing the , , and cDNAs, Drs. M. B. Kennedy and H. Schulman for providing and antibodies, respectively, and Phong Nguyen, Clyde King Jr, and Hao Truong for
expert technical assistance.
Correspondence should be addressed to Dr. Edward G. Jones, Department
of Anatomy and Neurobiology, University of California, Irvine, Irvine,
CA 92697-1280.
Dr. Tighilet's present address: Laboratoire de Neurobiologie des
Restaurations Functionelles, University of Provence, Marseilles 20, France.
| |
REFERENCES |
-
Artola A,
Singer W
(1987)
Long-term potentiation and NMDA receptors in rat visual cortex.
Nature
330:649-652[Medline].
-
Artola A,
Brocher S,
Singer W
(1990)
Different voltage-dependent thresholds for inducing long-term depression and long-term potentiation in slices of rat visual cortex.
Nature
347:69-72[Medline].
-
Bear MF,
Press WA,
Connors BW
(1992)
Long-term potentiation in slices of kitten visual cortex and the effects of NMDA receptor blockade.
J Neurophysiol
67:841-851[Abstract/Free Full Text].
-
Bennett MK,
Kennedy MB
(1987)
Deduced primary structure of the subunit of brain type II Ca2+/calmodulin-dependent protein kinase determined by molecular cloning.
Proc Natl Acad Sci USA
84:1794-1798[Abstract/Free Full Text].
-
Bennett MK,
Erondu NE,
Kennedy MB
(1983)
Purification and characterization of a calmodulin-dependent protein kinase that is highly concentrated in brain.
J Biol Chem
258:12735-12744[Abstract/Free Full Text].
-
Benson DL,
Isackson PJ,
Gall CM,
Jones EG
(1991a)
Differential effects of monocular deprivation on glutamic acid decarboxylase and type II calcium-calmodulin-dependent protein kinase gene expression in the adult monkey visual cortex.
J Neurosci
11:31-47[Abstract].
-
Benson DL,
Isackson PJ,
Hendry SHC,
Jones EG
(1991b)
Differential gene expression for glutamic acid decarboxylase and type II calcium-calmodulin-dependent protein kinase in basal ganglia, thalamus, and hypothalamus of the monkey.
J Neurosci
11:1540-1564[Abstract].
-
Benson DL,
Isackson PJ,
Gall CM,
Jones EG
(1992)
Contrasting patterns in the localization of glutamic acid decarboxylase and Ca2+/calmodulin protein kinase gene expression in the rat central nervous system.
Neuroscience
46:825-850[Web of Science][Medline].
-
Benson DL,
Huntsman MM,
Jones EG
(1994)
Activity-dependent changes in GAD and preprotachykinin mRNAs in visual cortex of adult monkeys.
Cereb Cortex
4:40-51[Abstract/Free Full Text].
-
Blasdel GG,
Lund JS
(1983)
Termination of afferent axons in macaque striate cortex.
J Neurosci
3:1389-1413[Abstract].
-
Braun AP,
Schulman H
(1995)
The multifunctional calcium/calmodulin-dependent protein kinase: from form to function.
Annu Rev Neurosci
57:417-445.
-
Brocke L,
Srinivasan M,
Schulman H
(1995)
Developmental and regional expression of multifunctional Ca2+/calmodulin-dependent protein kinase isoforms in rat brain.
J Neurosci
15:6797-6808[Abstract/Free Full Text].
-
Bronstein JM,
Micevych P,
Popper P,
Huez G,
Farber DB,
Wasterlain CG
(1992)
Long-lasting decreases of type II calmodulin kinase expression in kindled rat brains.
Brain Res
584:257-260[Web of Science][Medline].
-
Burgin KE,
Waxham MN,
Rickling S,
Westgate SA,
Mobley WC,
Kelly PT
(1990)
In situ hybridization histochemistry of Ca2+/calmodulin-dependent protein kinase in developing rat brain.
J Neurosci
10:1788-1798[Abstract].
-
Casagrande VA,
Kaas JH
(1994)
The afferent, intrinsic, and efferent connections of primary visual cortex in primates.
In: Cerebral cortex, Vol 10, Primary visual cortex in primates (Peters A,
Rockland K,
eds), pp 201-260. New York: Plenum.
-
Edman CF,
Schulman H
(1994)
Identification and characterization of delta B-CaM kinase and delta C-CaM kinase from rat heart, two new multifunctional Ca2+/calmodulin-dependent protein kinase isoforms.
Biochim Biophys Acta
1221:89-101[Medline].
-
Erondu NE,
Kennedy MB
(1985)
Regional distribution of type II Ca2+/calmodulin-dependent protein kinase in rat brain.
J Neurosci
5:3270-3277[Abstract].
-
Fitzpatrick D,
Itoh K,
Diamond IT
(1983)
The laminar organization of the lateral geniculate body and the striate cortex in the squirrel monkey (Saimiri sciureus).
J Neurosci
3:673-702[Abstract].
-
Fries W,
Keizer K,
Kuypers HGJM
(1985)
Large layer VI cells in macaque striate cortex (Meynert cells) project to both superior colliculus and prestriate visual area V5.
Exp Brain Res
58:613-616[Web of Science][Medline].
-
Glazewski S,
Chen C-M,
Silva A,
Fox K
(1996)
Requirement for -CaMKII in experience-dependent plasticity of the barrel cortex.
Science
272:421-423[Abstract].
-
Goldenring JR,
McGuire Jr JS,
DeLorenzo RJ
(1984)
Identification of the major postsynaptic density protein as homologous with the major calmodulin-binding subunit of a calmodulin-dependent protein kinase.
J Neurochem
42:1077-1084[Web of Science][Medline].
-
Gordon JA,
Cioffi D,
Silva AJ,
Stryker MP
(1996)
Deficient plasticity in the primary visual cortex of -calcium/calmodulin-dependent protein kinase II mutant mice.
Neuron
17:491-499[Web of Science][Medline].
-
Hanley RM,
Means AR,
Ono T,
Kemp BE,
Burgin K,
Waxham EN,
Kelly PT
(1987)
Functional analysis of a complementary DNA for the 50-kilodalton subunit of calmodulin kinase II.
Science
237:293-297[Abstract/Free Full Text].
-
Hendry SHC,
Jones EG
(1986)
Reduction in number of immunostained GABAergic neurones in deprived-eye dominance columns of monkey area 17.
Nature
320:750-753[Medline].
-
Hendry SHC,
Kennedy MB
(1986)
Immunoreactivity for a calmodulin-dependent protein kinase is selectively increased in macaque striate cortex after monocular deprivation.
Proc Natl Acad Sci USA
83:1536-1540[Abstract/Free Full Text].
-
Hendry SHC,
Yoshioka T
(1994)
A neurochemically distinct third channel in the macaque dorsal lateral geniculate nucleus.
Science
264:575-577[Abstract/Free Full Text].
-
Hendry SHC,
Jones EG,
Burstein N
(1988)
Activity-dependent regulation of tachykinin-like immunoreactivity in neurons of monkey visual cortex.
J Neurosci
8:1225-1238[Abstract].
-
Hendry SHC,
Huntsman MM,
Vinuela A,
Mohler H,
deBlas AL,
Jones EG
(1994)
GABAA receptor subunit immunoreactivity in primate visual cortex: distribution in macaques and humans and regulation by visual input in adulthood.
J Neurosci
14:2383-2401[Abstract].
-
Hof PR,
Morrison JH
(1995)
Neurofilament protein defines regional patterns of cortical organization in the macaque monkey visual system: a quantitative immunohistochemical analysis.
J Comp Neurol
352:161-186[Web of Science][Medline].
-
Hof PR,
Nimchinsky EA,
Morrison JH
(1995)
Neurochemical phenotype of corticocortical connections in the macaque monkey: quantitative analysis of a subset of neurofilament protein-immunoreactive projection neurons in frontal, parietal, temporal, and cingulate cortices.
J Comp Neurol
362:109-133[Web of Science][Medline].
-
Hubel DH,
Wiesel TN
(1972)
Laminar and columnar distribution of geniculo-cortical fibers in the macaque monkey.
J Comp Neurol
146:421-450[Web of Science][Medline].
-
Huntsman MM,
Isackson PJ,
Jones EG
(1994)
Lamina-specific expression and activity-dependent regulation of seven GABAA receptor subunit mRNAs in monkey visual cortex.
J Neurosci
14:2236-2259[Abstract].
-
Jones EG
(1988)
Modern views of cellular thalamic mechanisms.
In: Cellular thalamic mechanisms (Bentivoglio M,
Spreafico R,
eds), pp 1-22. Amsterdam: Elsevier.
-
Jones EG,
Hendry SHC,
DeFelipe J,
Benson DL
(1994a)
GABA neurons and their role in activity-dependent plasticity of adult primate visual cortex.
In: Cerebral cortex, Vol 10, Primary visual cortex in primates (Peters A,
Rockland K,
eds), pp 61-140. New York: Plenum.
-
Jones EG,
Huntley GW,
Benson DL
(1994b)
Alpha calcium/calmodulin-dependent protein kinase II selectively expressed in a subpopulation of excitatory neurons in monkey sensory-motor cortex: comparison with GAD-67 expression.
J Neurosci
14:611-629[Abstract].
-
Kelly PT,
McGuinness TL,
Greengard P
(1984)
Evidence that the major postsynaptic density protein is a component of a Ca2+/calmodulin-dependent protein kinase.
Proc Natl Acad Sci USA
81:945-949[Abstract/Free Full Text].
-
Kennedy MB,
Bennett MK,
Erondu NE
(1983)
Biochemical and immunochemical evidence that the "major postsynaptic density protein" is a subunit of a calmodulin-dependent protein kinase.
Proc Natl Acad Sci USA
80:7357-7361[Abstract/Free Full Text].
-
Kirkwood A,
Bear MF
(1994)
Hebbian synapses in visual cortex.
J Neurosci
14:1634-1645[Abstract].
-
Kirkwood A,
Silva A,
Bear MF
(1997)
Age-dependent decrease of synaptic plasticity in the neocortex of a CaMKII mutant mice.
Proc Natl Acad Sci USA
94:3380-3383[Abstract/Free Full Text].
-
Levitt JB,
Yoshioka T,
Lund JS
(1994)
Intrinsic cortical connections in macaque visual area V2: evidence for interaction between different functional streams.
J Comp Neurol
342:551-570[Web of Science][Medline].
-
Liang F,
Isackson PJ,
Jones EG
(1996)
Stimulus-dependent, reciprocal up- and down-regulation of glutamic acid decarboxylase and Ca2+/calmodulin-dependent protein kinase II gene expression in rat cerebral cortex.
Exp Brain Res
110:163-174[Web of Science][Medline].
-
Liang FY,
Jones EG
(1997)
Differential and time-dependent changes in gene expression for type II calcium/calmodulin-dependent protein kinase, 67 kDa glutamic acid decarboxylase, and glutamate receptor subunits in tetanus toxin-induced focal epilepsy.
J Neurosci
17:2168-2180[Abstract/Free Full Text].
-
Lin CR,
Kapiloff MS,
Durgerian S,
Tatemoto SK,
Russo AF,
Hanson P,
Schulman H,
Rosenfeld MG
(1987)
Molecular cloning of a brain-specific calcium/calmodulin-dependent protein kinase.
Proc Natl Acad Sci USA
84:5962-5966[Abstract/Free Full Text].
-
Livingstone M,
Hubel D
(1988)
Segregation of form, color, movement, and depth: anatomy, physiology, and perception.
Science
240:740-749[Abstract/Free Full Text].
-
Livingstone MS,
Hubel DH
(1982)
Thalamic inputs to cytochrome oxidase-rich regions in monkey visual cortex.
Proc Natl Acad Sci USA
779:6098-6101.
-
Livingstone MS,
Hubel DH
(1987a)
Connections between layer 4B of area 17 and thick cytochrome oxidase stripes of area 18 in the squirrel monkey.
J Neurosci
7:3371-3377[Abstract].
-
Livingstone MS,
Hubel DH
(1987b)
Psychophysical evidence for separate channels for the perception of form, color, movement, and depth.
J Neurosci
7:3416-3468[Abstract].
-
Liu X-B,
Jones EG
(1996)
Localization of alpha type II calcium calmodulin-dependent protein kinase at glutamatergic but not gamma-N-butyric acid (GABAergic) synapses in thalamus and cerebral cortex.
Proc Natl Acad Sci USA
93:7332-7336[Abstract/Free Full Text].
-
Liu X-B,
Jones EG
(1997)
Localization of -type II calcium/calmodulin-dependent protein kinase specifically at glutamatergic synapses in rat hippocampus.
NeuroReport
8:1475-1479[Web of Science][Medline].
-
Lund JS,
Lund RD,
Hendrickson AE,
Bunt AH,
Fuchs AF
(1975)
The origin of efferent pathways from the primary visual cortex, area 17, of the macaque monkey as shown by retrograde transport of horseradish peroxidase.
J Comp Neurol
164:287-304[Web of Science][Medline].
-
Lund JS,
Yoshioka T,
Levitt JB
(1994)
Substrates for interlaminar connections in area VI of macaque monkey cerebral cortex.
In: Cerebral cortex, Vol 10, Primary visual cortex in primates (Peters A,
Rockland K,
eds), pp 37-60. New York: Plenum.
-
Malenka RC,
Kauer JA,
Perkel DJ,
Mauk MD,
Kelly PT,
Nicoll RA,
Waxham MN
(1989)
An essential role for postsynaptic calmodulin and protein kinase activity in long-term potentiation.
Nature
340:554-557[Medline].
-
Malinow R,
Madison DV,
Tsien RW
(1988)
Persistent protein kinase activity underlying long-term potentiation.
Nature
335:820-824[Medline].
-
Malinow R,
Schulman H,
Tsien RW
(1989)
Inhibition of postsynaptic PKC or CaMKII blocks induction but not expression of LTP.
Science
245:862-866[Abstract/Free Full Text].
-
Mayer P,
Mohlig M,
Schatz H,
Pfeiffer A
(1993)
New isoforms of multifunctional calcium/calmodulin-dependent protein kinase II.
FEBS Lett
333:3185-3188.
-
Murray KD,
Gall CM,
Benson DL,
Jones EG,
Isackson PJ
(1995)
Decreased expression of the alpha subunit of Ca2+/calmodulin-dependent protein kinase type II mRNA in the adult rat CNS following recurrent limbic seizures.
Mol Brain Res
32:221-232[Medline].
-
Nghiem P,
Saati SM,
Martens CL,
Gardner P,
Schulman H
(1993)
Cloning and analysis of two new isoforms of multifunctional Ca2+/calmodulin-dependent protein kinase. Expression in multiple human tissues.
J Biol Chem
268:5471-5479[Abstract/Free Full Text].
-
Sakagami H,
Kondo H
(1993)
Differential expression of mRNAs encoding gamma and delta subunits of Ca2+/calmodulin-dependent protein kinase type II (CaM kinase II) in the mature and postnatally developing rat brain.
Mol Brain Res
20:51-63[Medline].
-
Scholz WK,
Baitinger C,
Schulman H,
Kelly PT
(1988)
Developmental changes in Ca2+/calmodulin-dependent protein kinase II in cultures of hippocampal pyramidal neurons and astrocytes.
J Neurosci
8:1039-1051[Abstract].
-
Schworer CM,
Rothblum LI,
Thekkumkara TJ,
Singer HA
(1993)
Identification of novel isoforms of the d subunit of Ca2+/calmodulin-dependent protein kinase II. Differential expression in rat brain and aorta.
J Biol Chem
268:14443-14449[Abstract/Free Full Text].
-
Silva AJ,
Stevens CF,
Tonegawa S,
Wang Y
(1992)
Deficient hippocampal long-term potentiation in -calcium-calmodulin kinase II mutant mice.
Science
257:201-205[Abstract/Free Full Text].
-
Stanton PK,
Gage AT
(1996)
Distinct synaptic loci of Ca2+/calmodulin-dependent protein kinase II necessary for long-term potentiation and depression.
J Neurophysiol
76:2097-2101[Abstract/Free Full Text].
-
Stevens CF,
Tonegawa S,
Wang Y
(1994)
The role of calcium-calmodulin kinase II in three forms of synaptic plasticity.
Curr Biol
4:687-693[Web of Science][Medline].
-
Takaishi T,
Saito N,
Tanaka C
(1992)
Evidence for distinct neuronal localization of gamma and delta subunits of Ca2+/calmodulin-dependent protein kinase II in the rat brain.
J Neurochem
58:1971-1974[Web of Science][Medline].
-
Tighilet B,
Huntsman MM,
Hashikawa T,
Murray KD,
Isackson PJ,
Jones EG
(1998)
Cell-specific expression of type II calcium/dependent protein kinase isoforms and glutamate receptors in normal and visually deprived lateral geniculate nucleus of monkeys.
J Comp Neurol
390:278-296[Web of Science][Medline].
-
Tobimatsu T,
Fujisawa H
(1989)
Tissue-specific expression of four types of rat calmodulin-dependent protein kinase II mRNAs.
J Biol Chem
264:17907-17912[Abstract/Free Full Text].
-
Tobimatsu T,
Kameshita I,
Fujisawa H
(1988)
Molecular cloning of the cDNA encoding the third polypeptide (gamma) of brain calmodulin-dependent protein kinase II.
J Biol Chem
263:16082-16086[Abstract/Free Full Text].
-
Trojanowski JQ,
Jacobson S
(1976)
Area and laminar distribution of some pulvinar cortical efferents in rhesus monkey.
J Comp Neurol
169:371-391[Web of Science][Medline].
-
Tsumoto T
(1992)
Long-term potentiation and long-term depression in the neocortex.
Prog Neurobiol
209:209-228.
-
Weber JT,
Huerta MF,
Kaas JH,
Harting JK
(1983)
The projections of the lateral geniculate nucleus of the squirrel monkey: studies of the interlaminar zones and the S layers.
J Comp Neurol
213:135-145[Web of Science][Medline].
-
Yamauchi T,
Ohsako S,
Deguchi T
(1989)
Expression and characterization of calmodulin-dependent protein kinase II from cloned cDNAs in Chinese hamster ovary cells.
J Biol Chem
264:19108-19116[Abstract/Free Full Text].
-
Yukie M,
Iwai E
(1981)
Direct projection from the dorsal lateral geniculate nucleus to the prestriate cortex in macaque monkeys.
J Comp Neurol
201:1-14[Web of Science][Medline].
Copyright © 1998 Society for Neuroscience 0270-6474/98/1862129-18$05.00/0
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Abstract
Introduction
