 |
 Previous Article | Next Article 
Volume 16, Number 9,
Issue of May 1, 1996
pp. 2983-2994
Copyright ©1996 Society for Neuroscience
The Dynamics of Dendritic Structure in Developing Hippocampal
Slices
Michael E. Dailey and
Stephen J Smith
Department of Molecular and Cellular Physiology, Beckman Center,
Stanford University Medical School, Stanford, California 94305-5426
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Time-lapse fluorescence confocal microscopy was used to directly
visualize the formation and dynamics of postsynaptic target structures
(i.e., dendritic branches and spines) on pyramidal neurons within
developing hippocampal tissue slices. Within a 2 week period of time,
pyramidal neurons in cultured slices derived from early postnatal rat
(postnatal days 2-7) developed complex dendritic arbors bearing
numerous postsynaptic spines. At early stages (1-2 d in
vitro), many fine filopodial protrusions on dendrite shafts
rapidly extended (maximum rate ~2.5 µm/min) and retracted (median
filopodial lifetime, 10 min), but some filopodia transformed into
growth cones and nascent dendrite branches. As dendritic arbors
matured, the population of fleeting lateral filopodia was replaced by
spine-like structures having a low rate of turnover. This developmental
progression involved a transitional stage in which dendrites were
dominated by persistent (up to 22 hr) but dynamic spiny protrusions
(i.e., protospines) that showed substantial changes in length and shape
on a timescale of minutes. These observations reveal a highly dynamic
state of postsynaptic target structures that may actively contribute to
the formation and plasticity of synaptic connections during CNS
development.
Key words:
dendrite;
dendritic spine;
development;
pyramidal cell;
hippocampal slice;
DiI;
confocal imaging;
time-lapse
INTRODUCTION
Establishment of axodendritic synaptic connections
within the mammalian CNS necessarily involves growth and contact of
afferent axons and target cell dendrites. Growing axons often must
traverse long distances and complex pathways to arrive at appropriate
target regions, where individual axons subsequently engage a large
number of potential target cells. With the advent of vital fluorescence
staining and time-lapse imaging methodologies, the dynamics of axon
growth and guidance in situ has been investigated
intensively (Harris et al., 1987 ; O'Rourke and Fraser, 1990; Kaethner
and Stuermer, 1992; Mason and Godement, 1992; Chien et al., 1993;
Sretavan and Reichardt, 1993; Dailey et al., 1994; Halloran and Kalil,
1994; O'Rourke et al., 1994). Such studies have greatly elucidated the
dynamic behavior of axons, and especially their growing terminals
(i.e., growth cones), as they extend toward and grow into their target
regions. A common theme is that growing axons explore their pathways
and target regions by elaborating many dynamic, often transient
protrusive filopodia and branchlets. Such highly protrusive behavior
appears to be essential to the axon's ability to pathfind and locate
appropriate target cells (for review, see Bentley and O'Connor, 1994;
Kater and Rehder, 1995).
Much less is known about the dynamics of postsynaptic target structures
during developmental periods of targeting and synaptogenesis. Based on
analysis of static images of fixed tissue taken from various regions in
the nervous system, it is clear that target dendrites undergo a rather
stereotypical sequence of morphological maturation concomitant with
axon ingrowth and synaptogenesis (Morest, 1969a,b; Minkwitz and Holz,
1975; Minkwitz, 1976; Berry and Bradley, 1976a,b; Lund et al., 1977;
Miller and Peters, 1981; Pokorny and Yamamoto, 1981; Phelps et al.,
1983; Ramoa et al., 1987; Ulfhake and Cullheim, 1988). This dendritic
maturation typically involves appearance of growth cones and fine
lateral filopodia on dendrite shafts, coinciding with the elaboration
of new dendritic branches. Subsequently, spine-like protrusions appear
at virtually all sites of excitatory synaptic contact on dendrites. As
development proceeds, stage-dependent differences in the morphology of
dendritic spine-like protrusions are often observed (Purpura, 1975;
Harris et al., 1989; Papa et al., 1995). Although these studies
indicate that the structure of target dendrites evolves during
developmental periods of synaptogenesis, the precise structural changes
underlying the formation and plasticity of individual postsynaptic
elements, especially the specialized postsynaptic spines, have remained
poorly defined.
To elucidate in more detail the dynamics of dendrite growth and
differentiation as they occur within a CNS tissue environment, we
developed means for direct time-lapse visualization of growing neuronal
dendrites in live, developing brain slice preparations. We examined
hippocampal tissue derived from early postnatal rat at a stage when
dendritic arbors of pyramidal cells are increasing in complexity and
are studded with lateral filopodia and growth cones, but still lack
classical dendritic spines (Minkwitz and Holz, 1975; Minkwitz, 1976).
This stage is also characterized by a high rate of synaptogenesis
(Bliss et al., 1974; Amaral and Dent, 1981; Buchs et al., 1993). We
followed the progression of changes in dendrite structure and dynamics
over a 2 week period of time as synaptic connections were forming with
dendrites in developing brain slices in vitro. The
development of dendritic structure was found to involve dynamic
activities that varied with the state of differentiation. At early
developmental stages, many filopodia and protospines actively protruded
from dendrite shafts into the surrounding tissue. Postsynaptic
spine-like structures that appeared subsequently were more stable, but
there was nevertheless a low level of spine turnover. It seems likely
that the active protrusion of dendritic filopodia and protospines
during early synaptogenic periods may help initiate synaptic contacts,
and that turnover of relatively stable dendritic spines at later stages
may contribute to changes in the number or function of synaptic
connections.
MATERIALS AND METHODS
Preparation and labeling of tissue slices
Hippocampal tissue slices were prepared from postnatal day 2 (P2) to P7 rat pups and cultured briefly (1-2 d), or slices derived
from P5-P7 animals were cultured for up to 2 weeks, as described
previously (Gähwiler, 1984; Dailey et al., 1994). We confined our
observations to developing tissue slices prepared from neonates (P7 and
younger animals) because (1) hippocampal slices derived from older
animals do not remain viable for long periods of time under such
in vitro conditions (Gähwiler, 1988), and (2) at later
developmental stages, the tissue isolation procedure is likely to
significantly perturb target cells by deafferenting (i.e., removing
axonal inputs to) dendrites and thereby altering the dynamics of
postsynaptic structures. It is well established that axons of intrinsic
neurons continue to develop and form synaptic contacts with pyramidal
cell dendrites when hippocampal slices are derived from neonates
(LaVail and Wolf, 1973; Gähwiler, 1984; Buchs et al., 1993;
Muller et al., 1993; Dailey et al., 1994).
To prepare tissue slices, neonatal rats were killed according to
institutional guidelines, and hippocampi were removed and transversely
sliced (400 µm thick) using a manual tissue chopper (Stoelting).
Slices were attached to alcohol-cleaned glass coverslips (11 × 22 mm)
with a mixture of chicken plasma (10 µl; Cocalico) and bovine
thrombin (10 µl; Sigma, St. Louis, MO). The slices were adherent
within ~10 min, at which point the coverslips were placed in a test
tube with 1 ml of 25 mM HEPES-buffered culture
media containing 25% serum. The tubes were kept in a warm room
(37°C) and rotated at 12 revolutions/hr in a roller drum tilted at
5° with respect to horizontal (Gähwiler, 1984).
To label dendritic arbors of neurons in live tissue slices, cells were
stained with a long-carbon-chain fluorescent membrane dye,
DiIC18(3) [DiI] (Honig and Hume, 1986), or the
red-shifted DiIC18(5) [DiD] (Agmon et al.,
1995) (both dyes from Molecular Probes, Eugene, OR). Use of the longer
wavelength dye, DiD, provided superior images of cells and dendrites
located deep within the tissue, presumably because of reduced tissue
scatter of red light (see Pawley, 1995). For acutely prepared slices, a
0.5% solution of dye in N,N-dimethylformamide (Sigma) was
pressure-injected into the stratum oriens in area CA3 or CA1.
Dye solution was delivered using a Picospritzer (General Valve,
Fairfield, NJ) to present a series of brief pressure pulses (1 msec
duration, 80 psi) to the back of a glass micropipette (2-3 µm tip
diameter). After dye injection, slices were returned to the roller drum
for a brief period to permit cellular uptake and diffusion of dye.
Slices were labeled and examined within 2-24 hr after isolation from
the brain, or they were cultured for 1-2 weeks to permit in
vitro tissue development (LaVail and Wolf, 1973; Gähwiler,
1984; Dailey et al., 1994) before labeling and imaging. The cultured
slices become somewhat thinner over time (~100 µm thick at 2 weeks), and such slices were labeled by inserting and breaking off the
tip of a glass micropipette coated with dye crystals. In some cases,
slices were chemically fixed (2% formaldehyde in PBS) after 2 weeks in
culture, then labeled with dye. Such fixed slices were maintained at
4°C for 4-8 weeks to permit adequate labeling and diffusion of the
dye.
Confocal fluorescence imaging
Confocal fluorescence microscopy permitted high-resolution,
three-dimensional imaging of neuronal structure up to 120 µm deep
within the tissue slices. For time-lapse microscopic observation (Smith
et al., 1990; Dailey, 1996), tissue was mounted in a perfusion chamber
with culture media or saline and placed on the stage of a confocal
microscope heated (35°C) with forced air. Tissue was continuously
superfused (10-20 ml/hr) with media or saline. Imaging was performed
using one of two custom-built, laser-scanning confocal microscopes
designed by S.J.S. The 514 nm line of a 25 mW argon ion laser (Ion
Laser Technology) was used for illumination when imaging the
conventional form of DiI. To image neurons labeled with the longer
wavelength dye, DiD, a 15 mW red helium/neon (HeNe) laser (HWK Laser)
was used. The detector was a gallium/arsenide photomultiplier tube with
a circular aperture placed in front to reject out-of-focus light.
Microscope objectives used were a dry 20× numerical aperture (NA) 0.75 (Nikon), an oil-water-glycerin 25× NA 0.8 (Zeiss, Thornwood, NY),
and an oil-immersion 40× NA 1.3 (Olympus). To clearly resolve small
dendritic filopodia and spines, image data typically were collected at
an additional electronic zoom factor of 2-3. The cells we examined
were located 15-120 µm below the surface of the tissue slice.
Because dendritic processes extended in three dimensions within the
thick tissue slices, we usually collected multiple (5-7) optical
sections spanning 10-30 µm in the Z-dimension to
accommodate focus drift and to ensure that small structures spanning
multiple confocal planes were fully captured. In most cases, stacks of
images were collected at 5 min intervals. In a few experiments,
individual confocal images were collected at 30 sec or 1 min intervals.
All images were stored digitally using a network file server, and image
stacks were later recombined using a maximum-brightness operation to
produce extended focus images.
Time-lapse imaging of live, fluorescently labeled cells can produce
phototoxic effects in the imaged cells. Indeed, when well stained cells
were imaged with very high incident illumination intensity, or imaged
too frequently, we invariably saw changes in the structure and dynamics
of dendritic branches and spines: dendrite shafts developed irregular
varicosities, branch points became triangulated, and both branches and
spiny structures consistently retracted (shortened or disappeared)
within a period of 1-2 hr. However, when the incident illumination was
sufficiently attenuated (typically <600 µJ/section over a 225 µm × 168 µm specimen field), labeled specimens could be imaged (1-5
min intervals) for many hours without signs of photodynamic damage.
Several lines of evidence indicate that the labeling and imaging
procedures we used did not have detrimental consequences on cell
structure and dynamics: (1) the structure of dendritic branches and
spines on live, vitally stained cells was essentially identical to that
of cells in age-matched slices fixed before labeling and imaging
(compare Figs. 1 and 5); (2) the structure of spiny
protrusions on live cells was very similar at the beginning and end of
time-lapse imaging sessions (see Fig. 6); and (3) the dynamic behavior
of dendrites remained relatively constant over the period of time-lapse
imaging: spine formation and resorption were evident throughout the
time-lapse sequences, and some spines became more stable while others
became more active along the same dendrite segment.
Fig. 1.
Dendrites of pyramidal cells grow and
differentiate in in vitro tissue slices. The structure of a
differentiated hippocampal CA1 pyramidal neuron is revealed by
postfixation labeling with DiI after 2 weeks in slice culture.
A, Low-magnification confocal image showing characteristic
polarized pyramidal shape. Emerging from the cell soma
(arrow) are several basal dendrites and a thick apical
dendrite with several oblique secondary branches
(arrowheads). B, Higher-magnification view of
distal apical dendrites within the stratum radiatum showing secondary
branches. Although their full extent is not evident in this single
confocal image plane, these branches course throughout the thickness of
the tissue slice. C, Dendritic branches are studded with
numerous spine-like projections (arrowheads), 1-3 µm in
length, presumed to be sites of synaptic contact. These features are
characteristic of pyramidal neurons in vivo.
[View Larger Version of this Image (69K GIF file)]
Fig. 5.
Dynamics of spine-like protrusions on well
developed pyramidal cell dendrites (12 d in vitro).
A, Single-focal-plane view of a CA1 neuron showing the
characteristic pyramidal shape with a primary apical dendrite
(arrow). The tissue was prepared from a P6 animal and
cultured for 12 d. B, Higher-magnification, extended-focus
view (combining 6 optical sections spanning 30 µm) of the distal
portion of the apical dendrites. Note the complexity of the dendritic
arbor and spiny appearance of the oblique dendrite branches
(arrows). C, Time-lapse sequence of a region
(top box) in B showing both stable,
spine-like structures and transient filopodial extensions. A short,
knobby spine-like protrusion (arrowhead 1) persists with
little change in length or shape. Directly adjacent to this spine, a
filopodia-like protrusion (arrowhead 2) extends transiently
from the dendrite shaft. Time is shown in minutes. D,
Time-lapse sequence of a region (lower box) in
B showing rapid formation of a knobby, spine-like protrusion
(arrowhead 5). The new spine forms and persists adjacent to
an existing spine (arrowhead 4). Note also another spine
(arrowhead 3) that persists for the entire observation
period but does not change shape or length significantly. Scale bar in
C also applies to D. The plots of length versus
time for spiny protrusions 1, 2, and 5 correspond
to traces 12, 9, and 11, respectively, in
Figure 7.
[View Larger Version of this Image (129K GIF file)]
Fig. 6.
Distribution of spine lengths in fixed or live
(time-lapse imaged) slices (2 weeks in vitro). The lengths
of all spiny protrusions on dendrites in a live slice were determined
at the beginning (PRE-TIME LAPSE) and end (POST-TIME
LAPSE) of a standard 3 hr time-lapse imaging sequence (experiment
shown in Fig. 5). There was no significant difference in the mean
length or length distribution of spines before or after the imaging
session, indicating that the time-lapse imaging did not induce changes
in spine structure. Also, the mean length of spines on live cells was
very similar to the distribution of spine lengths on dendrites in
comparable slices fixed before labeling and imaging (FIXED).
See Results for more details.
[View Larger Version of this Image (38K GIF file)]
Quantitation of the lengths and lifetimes of
spiny protrusions
Lengths. All clearly evident dendritic protrusions
greater than 0.5 µm and less than 10 µm in length were classified
as ``spiny protrusions'' and were included in these analyses. (On
live cells, discrimination of protrusions shorter than ~0.7 µm was
not reliable.) The lengths (base to tip) of spiny protrusions were
estimated from two-dimensional projections of three-dimensional image
stacks (i.e., from extended-focus images) to ensure that the full
lengths were captured. For quantitative analysis, the original
digitized images (single pixel dimension = ~0.3 µm in the specimen
plane) were electronically zoomed an additional twofold. Measurements
were made using custom-designed software using a mouse-controlled
cursor.
Lifetimes. Lifetimes of spiny protrusions were
estimated from time-lapse movies by determining the number of time
points in which a given structure was evident, then multiplying that
number by the time interval. For structures present at the beginning
and/or end of the sequence, only a lower limit of lifetime could be
determined. At later developmental stages, most spiny protrusions were
evident for the entire observation period (3-22 hr). However, our
quantitative analyses were limited by the length of time we could
continuously observe any one dendrite segment, which varied from
experiment to experiment. Consequently, to compare systematically the
lifetime of spines between imaging sequences of different durations, it
was necessary to truncate spine lifetimes that were longer than the
shortest time-lapse sequence (e.g., 100 min for Fig. 8A and
180 min for Fig. 8B).
Fig. 8.
Stage-dependent differences in the lifetime and
fate of spiny protrusions. A, The lifetimes of spiny
protrusions increased progressively with time in vitro.
Distribution of lifetimes of 146 spiny protrusions from apical
dendrites of eight pyramidal cells in six tissue slices. B,
Fate of spiny protrusions in tissue slices. All spiny structures
observed during the first 3 hr of imaging were classified as
TRANSIENT (came and went during the 3 hr observation
period), DISAPPEARED (evident at the beginning but were
resorbed during the 3 hr observation), APPEARED (formed
de novo and persisted), or STABLE (evident
throughout the 3 hr observation period). Note that a greater fraction
of spines were stable on more mature (i.e., 12 d in vitro)
dendrites, but there remained a low level of spine turnover.
[View Larger Version of this Image (31K GIF file)]
RESULTS
Observations in fixed tissue slices
To obtain normative data free from possible biases of vital
imaging techniques, the structure of pyramidal cell dendrites in tissue
slices cultured for up to 14 d before fixation was visualized by
post-fixation labeling with the fluorescent membrane dye DiI (Honig and
Hume, 1986). Through-focus analysis with a confocal microscope
indicated that, by 2 weeks in vitro, pyramidal cells had
developed a complex, three-dimensional morphology with many oblique
dendritic branches extending from the primary apical and basal
processes (Fig. 1). At higher magnification, it was evident that
dendritic branches were studded with numerous spine-like protrusions of
varying shape and size (0.5-3 µm long). The morphological features
of these spiny structures are essentially identical to those previously
identified as sites of synaptic contact on hippocampal pyramidal cells
both in vivo (Westrum and Blackstad, 1962; Harris et al.,
1989) and in in vitro tissue slices (Deitch et al., 1991;
Stoppini et al., 1991; Buchs et al., 1993; Pozzo Miller et al., 1993).
Thus, within a 2 week period of time, dendrites of pyramidal cells in
in vitro tissue slices acquire many structural features
characteristic of their age-matched counterparts in vivo,
including complex dendritic arbors and numerous postsynaptic
spines.
Time-lapse imaging in live tissue slices
To examine directly the dynamics of dendrite structure during
neuronal differentiation and synaptogenesis, neurons in tissue slices
were labeled in the living state with a fluorescent membrane dye (DiI
or DiD), then imaged over time with the confocal microscope. To study
the development of single cells and subcellular structures, individual
tissue slices were maintained on the microscope stage and imaged at
intervals of 1-10 min for several hours. To test for stage-dependent
variations in dendrite dynamics spanning a longer developmental period,
we examined different slices cultured for progressively longer times
(up to 2 weeks). The present time-lapse observations are based on
imaging of 60 cells in 33 slices.
First days in culture
At early time points (1-2 d) in culture, dendrite branches were
often tipped with growth cone-like structures (Fig.
2A), suggesting active dendrite growth.
Indeed, direct time-lapse imaging revealed that the dendritic arbor was
highly dynamic. Branches of both apical and basal dendrites elongated
within the tissue by advance of the leading growth cone, which involved
cyclical protrusion and retraction of filopodia and lamellae. Growing
dendritic branches extended within the tissue at a rate of 18.4 ± 10.5 µm/hr (mean ± SD, n = 12), which is comparable with the
rate of axonal extension observed in these tissue slices
(Dailey et al., 1994). Surprisingly, even as some dendritic branches
elongated, other branches retracted (16.2 ± 6.6 µm/hr, n = 5) and were sometimes fully resorbed into the parent dendrite
trunk.
Fig. 2.
Sprouting of lateral filopodia, growth cones, and
collateral branches from pyramidal cell dendrites during early stages
of differentiation (1 d in vitro). A,
Low-magnification image of DiI-labeled CA1 pyramidal neuron somata
(P) and dendrites (arrows) in a live tissue slice
taken from a P2 animal. This is an extended-focus image made by
combining a stack of five optical sections spanning 15 µm in the
Z-dimension. At early developmental stages, dendrites are
often tipped by complex growth cones (arrowhead).
SR, Stratum radiatum; SP, stratum pyramidale.
B, Through-focus sequence of boxed region
in A showing a segment of an apical dendrite shaft
(arrow) having fine, lateral filopodial protrusions
(arrowhead). For time-lapse imaging, multiple optical
sections were collected to ensure that small dendritic protrusions were
captured in their entirety. C, Time-lapse sequence of the
same field as in B showing that numerous lateral filopodia
(arrowheads) extend from, and retract back to, the dendrite
shaft. Most filopodia are resorbed within a few minutes after first
appearing. These images are composites of two or three optical sections
from the middle of a five-image stack (shown in B).
D, Persisting lateral filopodia sometimes evolve into growth
cones. Time-lapse sequence shows a lateral filopodium
(arrowheads) sprouting from an apical dendrite shaft
(0-30 min), persisting for more than an hour (30-90
min), then rapidly developing into a complex, growth cone-like
structure (arrow; 90-100 min). E,
De novo sprouting of a growth cone leading to formation of a
collateral dendrite branch. A faint, filopodial structure is seen first
(40 min), then a growth cone develops (60-80 min)
and spins out a new branch that persisted and grew to a length of at
least 35 µm (120 min). For C-E,
elapsed time is shown in minutes.
[View Larger Version of this Image (147K GIF file)]
Motile protrusions were not confined to the tips of growing branches:
lateral filopodia and growth cone-like sprouts were commonly seen along
developing dendrite shafts. Most of the filopodial protrusions (up to
10 µm long) extended (maximal rate: ~2.5 µm/min) from dendrite
shafts, then retracted back to the shaft within 30 min or less (median
lifetime, 10 min) (Fig. 2B,C). Filopodia emerged
from many different sites along the longitudinal extent of the apical
and basal dendrites, although ``hot spots'' of filopodial protrusion
were occasionally seen where filopodia repeatedly emerged and retracted
from a localized site. Sometimes these hot spots of protrusive activity
moved rapidly (114 ± 44 µm/hr, n = 4) toward the growing
tip of the dendrite branch, giving the appearance of waves of activity
that covered distances of 100 µm or more. After reaching the tip, the
waves appeared to fuel rapid growth of the branch for several minutes
(see Ruthel and Banker, 1992). The frequency of filopodial protrusions
from the dendrite surface was highly variable from cell to cell and
from branch to branch: we saw as many as 36 protrusions along a 50 µm
dendrite segment within a 3 hr period of time. However, because the
filopodial lifetimes were short and our sampling rate was relatively
low (once every 5 min), the actual number of protrusive events is
likely to be substantially higher.
Growth cone-like sprouts were also observed to emerge de
novo from proximal regions of dendrite shafts. Formation of growth
cone sprouts typically involved transformation from a single lateral
filopodium (Fig. 2D). Although many of these sprouts were
resorbed within a few minutes, others continued extending and generated
new collateral branches (Fig. 2E). Thus, a common sequence
of events leading to collateral branch formation included: first,
emergence of a single filopodium; then, conversion of that filopodium
into a collateral growth cone; and finally, advance of the growth cone
and consolidation of the new outgrowth to form a cylindrical dendrite
branch.
These observations indicate that the developing dendritic arbor is
highly dynamic, and that some of the lateral dendritic filopodia and
growth cones are precursors to new dendrite branches. However, most
lateral dendritic filopodia extend transiently and are fully resorbed
within a few minutes. We found little change in the dynamic properties
of dendrites in slices prepared from animals during the first postnatal
week: over the first few days in culture, slices from P2-P7 animals
were all dominated by highly dynamic, transient filopodia.
One week in culture
When slices of developing hippocampus (derived from P5-P7
animals) were cultured for several more days (i.e., 6-8 d total) to
allow synaptogenesis and dendritic differentiation to proceed in
vitro (Gähwiler, 1984; Buchs et al., 1989; Muller et al.,
1993), dendritic arbors were found to have increased in complexity
(Fig. 3A). Many more oblique branches
had extended from primary dendrite trunks. In addition, dendrite
branches bore numerous spiny protrusions (1.8 ± 0.9 µm) having
simple filiform or complex shapes (Fig. 3B). Some of
these lateral ``spine-like'' protrusions had short (~1 µm) stalks
and knobby heads, features that are characteristic of postsynaptic
spines on mature dendrites (Harris et al., 1992; Papa et al., 1995;
Trommald et al., 1995).
Fig. 3.
Dynamics of spiny protrusions on differentiating
pyramidal cell dendrites (7 d in vitro). Tissue was taken
from a P5 rat and cultured for 1 week. A, Low-magnification
image of a live, DiI-labeled CA1 pyramidal cell (arrow)
showing extensive apical dendrite arbors that have developed in
vitro. This image is a Z-axis composite of 15 separate
confocal images spanning a tissue depth of 45 µm. Because of the
greater volume of tissue sampled, dendritic arbors appear more complex
in Z-axis composite images than in single focal plane
images. The complexity of dendritic arbors at 7 d in
vitro was intermediate to that of neurons at 1 d (compare Fig.
2A) and 12 d (compare Figs. 1A, 5A)
in vitro. B, Higher-magnification image of boxed
region in A showing many simple and branched
(arrows) filopodia as well as spine-like protrusions with
bulbous tips (arrowheads). Schaffer axons from CA3 pyramidal
cells, which are retained in the tissue slices, normally synaptically
terminate on spines in this region of the dendrite. Scale bar in
B applies to B-D. C, Selected images of a
time-lapse sequence of a region in B (right
box) showing extension and partial retraction of a
filopodium (arrow). By contrast, the length of a spine-like
protrusion with a bulbous tip (arrowhead) is stable over the
same time period. D, Time-lapse sequence of a region in
B (left box) showing dynamic changes in structure
of a spine-like protrusion. The protrusion starts with a bulbous head
(arrow) that appears to bifurcate (arrowheads).
Images in C and D, shown at 1 min intervals, are
single-focal-plane scans selected from an original data set taken at 30 sec intervals.
[View Larger Version of this Image (65K GIF file)]
Time-lapse imaging revealed that both filopodia- and spine-like
protrusions on dendrites were structurally very dynamic at 1 week
in vitro. Filopodial protrusions (without knobby heads)
often exhibited rounds of rapid extension and retraction (Fig.
3C). The spine-like protrusions (with heads) generally
persisted for longer periods of time and were more stable in length
than filopodia (Fig. 3C), although some spines elongated and
retracted, and spine heads were observed to change shape from minute to
minute (Fig. 3D). A few spines showed no detectable change
in length or shape over a several hour period of observation. Thus,
with regard to both morphology and structural dynamics, there was a
heterogeneous population of spiny structures on developing dendrites at
this stage.
To assess better the long-term stability and dynamics of the various
spiny protrusions, we collected confocal images of single dendrite
branches for lengthy periods of time (up to 22 hr). In contrast to
earlier time points in vitro, many of the spiny
protrusions at this stage were not transient but instead persisted
for long periods of time. The time-lapse observations also revealed a
variety of dynamic behaviors on individual dendrite branches (Fig.
4A,B), including: (1) de
novo formation of spiny structures (Fig.
4B3,C3); (2) resorption of some spiny
structures; (3) persistence of some spiny structures in a dynamic state
(Fig. 4A2,C2); and (4)
conversion of some dynamic spiny structures to a more stable state
(Fig. 4C1,C3). Analysis of the length
of individual spiny protrusions over time revealed that many of the
persisting structures had a dynamic distal segment that protruded
rapidly (up to 35 µm/hr) and cyclically from a relatively stable,
proximal stump (0.5-4 µm) (Fig. 4C). The apparent length
of the short persisting stump also changed somewhat over time, but at a
much slower rate (generally <1 µm/hr). These observations are in
contrast to earlier developmental time points at which transient
filopodia appeared to protrude directly from, and to be fully resorbed
back to, the surface of the dendrite shaft.
Fig. 4.
Dynamics of long-lived, spiny protrusions on
differentiating dendrites (7 d in vitro). These extended
time-lapse sequences show changes in length and shape of spiny
protrusions (arrowheads) over a period of up to 18.6 hr. All
images are composites of two adjacent focal planes selected from a
five-image stack to ensure that the full lengths of the structures were
captured. Images were selected from an original data set collected at 5 min intervals. Elapsed time is shown in hours. A, Two of the
spiny protrusions (1 and 2) were highly dynamic
but persisted for the entire observation period. Length plots for these
protrusions are shown in C (traces 1 and
2). B, De novo appearance of a spiny
protrusion (arrowhead) that persisted after being formed.
Length plot for this protrusion is shown in C (trace
3). C, Plots of length versus time for spiny
protrusions shown above. Measurements of protrusion length were made at
each time point (5 min intervals). Traces 1 and
2 correspond to the protrusions indicated in A. Note that transient length excursions (arrows), which can
effectively double or triple the length of the protrusion, are made
from relatively stable bases (arrowheads). Reduction in the
transient length excursions of protrusions 1 and
3 near the end of the sequences suggests a further
stabilization of these protrusions. In contrast, the transient length
excursions persist in trace 2.
[View Larger Version of this Image (65K GIF file)]
Two weeks in culture
When tissue slices were cultured for ~2 weeks (12-14 d) before
observation, dendrites had very elaborate arbors that were more
uniformly covered with short (0.5-2 µm), spiny protrusions (Fig.
5A,B). Time-lapse observations
revealed that the structure of these well differentiated dendrites was
more stable than at earlier times in vitro. We observed
neither substantial elongation or retraction of existing branches, nor
formation of new branches. Moreover, many of the spine-like protrusions
persisted for the entire observation period and did not exhibit
detectable changes in shape or length (Fig. 5D).
Nevertheless, we occasionally observed filopodia-like protrusions
transiently extending to a length of 2-3 µm before retracting (Fig.
5C), and some spines rapidly emerged de novo
(Fig. 5D) while others appeared to be entirely resorbed.
These observations indicate that some stable spines can form on more
mature dendrites in the absence of dynamic filopodial and protospine
precursors, and that even at the latest stage examined (2 weeks
in vitro) there is turnover of some spine-like
protrusions.
Quantitative analysis of spine structure and dynamics
Spines on live versus fixed dendrites
The structure of spiny protrusions on dendrites in the live,
2-week-old tissue slices looked very similar to those previously
observed in fixed (nonimaged), age-matched slice cultures (compare
Figs. 1 and 5). To assess and compare spine structure in the living and
fixed states quantitatively, we measured the length of all spiny
protrusions on dendrites in fixed tissue and at two time points in live
tissue slices (both before and after time-lapse imaging). Although the
distribution of spine lengths for live and fixed dendrites was quite
similar (Fig. 6), statistical analysis revealed a
significant difference (p = 0.017; Mann-Whitney rank sum
test) between these groups when the minimum threshold length for spine
detection was set at 0.5 µm. The mean length of spines on live
dendrites (before imaging) was 1.30 ± 0.41 µm (mean ± SD;
n = 98), and for spines on fixed cells, 1.18 ± 0.40 µm
(n = 99). This difference was attributable to the greater
number of spines scored in the 0.5-0.7 µm range on fixed cells
compared with live cells. The apparent increase in the frequency of the
shortest spines (0.5-0.7 µm) on fixed dendrites could be
attributable to tissue shrinkage associated with fixation (Deutsch and
Hillman, 1977), or to the different imaging conditions. Our ability to
reliably detect the shortest spines was dependent in part on the
intensity of the illuminating laser light (i.e., higher laser intensity
increases the signal-to-noise ratio and improves spatial resolution).
Because we used a lower intensity on the live cells to minimize
phototoxic effects, we were not able to resolve clearly the shortest
spines on live cells as well as we could on fixed cells. It is likely,
then, that we could not detect reliably some of the shortest spines
(<0.7 µm) on the live dendrites under the imaging conditions we
used. Indeed, when the minimum spine length threshold was set to a more
conservative value (0.7 µm), there was no statistical difference
between spine lengths on the live and fixed cells (p = 0.091).
Before and after imaging
We also compared spine lengths on individual live dendrites before
and after time-lapse imaging sessions (see Fig. 6). The lengths of
spines after a standard 3 hr imaging session (mean spine length, 1.30 ± 0.47 µm; n = 95) were found to be not statistically
different (p = 0.598) from that at the beginning of the
imaging session. This supports the idea that the labeling and
time-lapse imaging procedures we used did not have detrimental effects
on dendrite structure in the live brain slices.
Developmental differences in spine dynamics
Our time-lapse observations on dendrites at different
developmental times suggested stage-dependent differences in the
dynamic properties of spiny structures. To more systematically assess
and compare the dynamics of spiny protrusions, the lengths of
individual spiny structures were determined and plotted for every time
point during the first 3 hr of observation on cells cultured for 1, 7, and 12 d. These plots clearly demonstrated the various motile behaviors
of spiny structures, including transient protrusion, resorption,
de novo formation, and stable persistence (Fig.
7). They also illustrated that transient
spiny protrusions were found at all developmental stages examined, and
that persisting spiny structures were significantly more
dynamic at 7 versus 12 d in vitro. In particular, at 7 d
in vitro many spiny structures made transient length changes
(compare Fig. 4), whereas at 12 d in vitro persisting spines
generally lacked such length changes. These observations thus reveal a
transient developmental period in which individual spiny structures
embody features characteristic of both fleeting filopodia and stable
spines.
Fig. 7.
Stage-dependent differences in the dynamics of
spiny protrusions. Representative plots of length versus time for spiny
dendritic protrusions at 1 d (traces 1-4), 7 d
(traces 5-8), and 12 d (traces 9-12) in
vitro. The traces illustrate a range of behaviors, including
transient protrusion (1, 2, 4, 5, 9), resorption of
preexisting structures (6, 10), de novo formation
and persistence (3, 7, 11), and persistence of preexisting
structures (8, 12). Transient filopodia-like protrusions
(1, 2, 5, 9) were observed at all times in vitro
but were most prominent at early stages (i.e., 1 d in
vitro). At 7 d in vitro, persisting spiny protrusions
often showed transient length excursions (arrows) from
short, stable bases (arrowheads) (compare trace 8 and Fig. 4C). Most persisting spines at 12 d in
vitro showed little change in length (e.g., trace 12),
although there was some turnover of spines (e.g., traces 10, 11). (Note different time base of Figs. 4C and
7.)
[View Larger Version of this Image (27K GIF file)]
Although a variety of protrusive structures was evident at the various
developmental stages we examined, the persisting (>30 min)
spiny structures appeared to predominate at later stages. Indeed,
analysis of the lifetimes of spiny protrusions revealed that the
fraction of persisting protrusions progressively increased over time
in vitro (Fig. 8). On the first day in
vitro, most (94%) of the spiny protrusions had a lifetime of
<100 min. However, by 12 d in vitro, 81% of the spiny
protrusions persisted for longer than 100 min, and over half (64%)
persisted for 3 hr or more. Thus, as dendritic arbors matured and
synaptic connections were established, spiny dendritic protrusions
became progressively more stable.
DISCUSSION
The present observations revealed a high level of structural
dynamics of dendrites during development, including both active growth
and dynamic turnover (resorption) of dendritic branches and spiny
protrusions. A striking feature of developing dendrites was the high
level of protrusive activity along proximal dendrite shafts. Many
lateral dendritic growth cones and filopodia were transitory, whereas
others were precursors to more stable dendritic branches and spine-like
projections. This suggests that much of dendritic structure (i.e.,
branches and spines) in developing CNS tissue is generated by the
selective stabilization of highly motile protrusive structures.
Dynamics of spine formation
Our time-lapse observations revealed several features of spine
formation and dynamics that could not be determined from static images
of dendrite structure, including: (1) the highly dynamic nature (i.e.,
rapid appearance and disappearance) of filopodial protrusions on
developing dendrites in CNS tissue; (2) a transitional developmental
phase involving conversion of dynamic filopodia to more stable,
spine-like protrusions; and (3) turnover (addition and resorption) of
some spine-like protrusions on more fully differentiated dendrite
branches.
Time-lapse analysis revealed a heterogeneous population of spiny
dendritic protrusions with regard to structural dynamics. Based on
their dynamic properties, we propose a threefold classification of
spiny dendritic protrusions: (1) transient filopodia that show rapid
changes in length and shape but are short-lived (generally <0.5 hr);
(2) metastable protospines that persist for longer periods of time (0.5 to >22 hr) but remain structurally dynamic; and (3) stable spines that
have a low rate of turnover and show relatively little change in
structure. Fine spiny protrusions from each of the different classes
can coexist on single dendrite branches, but there is a clear
developmental progression. At early stages of differentiation,
dendrites predominately bear the filopodia, whereas the mature
dendrites are dominated by spines. The protospines appear at an
intermediate stage and are transient developmental structures that
share properties of both the filopodia and spines: they persist
like the spines but also show rapid changes in length like the
filopodia.
The three spiny populations may represent separate structures that are
ontogenetically unrelated. Alternatively, dynamic structures may evolve
into progressively more stable structures. This latter idea is
consistent with the transient appearance of protospines, which share
features of both the filopodia and spines, at an intermediate
developmental stage preceded by a filopodia-dominated stage and
followed by a spine-dominated stage. Moreover, our time-lapse
observations revealed that individual spiny structures can make
transitions from a relatively dynamic state to a more stable
configuration (compare Fig. 4C). However, in our older
cultures we also observed rapid appearance of stable spines without
dynamic filopodia or protospines immediately preceding the spines
(e.g., Fig. 5D). Thus, stable spines may emerge on
developing dendrites via two different mechanisms: (1) conversion from
more dynamic spiny structures, and (2) rapid and de novo
extension of a stable spine directly from dendrite shafts.
The stability of spiny protrusions on well differentiated dendrites in
our older slice cultures is consistent with previous time-lapse
observations of more mature dendrites in acutely isolated hippocampal
tissue (Hosokawa et al., 1992, 1994). In slices prepared from
3-week-old animals, spiny structures likely to be postsynaptic elements
often persisted for >5 hr, although a small proportion of spines
appeared or disappeared over the course of the 5 hr observations
(Hosokawa et al., 1992). The present observations extend the lower
limit of spine lifetime to at least 22 hr, and additionally indicate
that long-lived spines can rapidly (<5 min) appear and disappear, and
reversibly change shape, at least during developmental periods.
The morphological characteristics of the stable spiny protrusions we
observed (i.e., the protospines and spines) are very similar to
spine-like protrusions observed on mature pyramidal cell dendrites from
fixed hippocampal tissue (Harris et al., 1989, 1992; Trommald et al.,
1995). Previous ultrastructural studies have shown that such spine-like
protrusions, both in vivo and in in vitro
tissue slices, are virtually always postsynaptic elements (Westrum
and Blackstad, 1962; Gottlieb and Cowan, 1972; Harris et al., 1989,
1992; Deitch et al., 1991; Stoppini et al., 1991; Buchs et al., 1993;
Pozzo Miller et al., 1993). Indeed, the time course of emergence of
stable spines in our slices is consistent with the known course of
synapse formation and accumulation on dendritic spines in comparable
slice cultures (LeVail and Wolf, 1973; Gähwiler, 1984; Dailey et
al., 1994; Buchs et al., 1993; Muller et al., 1993). In stratum
radiatum of area CA1, there is a 15-fold increase in the density
of synapses over the first 2 weeks in culture, and virtually all of the
new synapses that appear are located on synaptic spines (Buchs et al.,
1993). Taken together, these observations strongly suggest that the
stable spiny protrusions we observed are sites of synaptic contact.
However, in the future it will be important to develop methods to
determine definitively which of the dynamic or stable dendritic
protrusions described here correspond to, or evolve into, actual
postsynaptic spines bearing synaptic contacts.
Possible relation of dendritic growth and protrusion to
synapse formation
If, as we suspect, many or all of the stable spiny structures bear
synaptic contacts, our observations would be consistent with either of
two scenarios of synaptogenesis: (1) synapses are first formed on
dendrite shafts, then emerge with spines as they extend from dendrite
shafts; or (2) synapses are first formed on protruding filopodia that
then retract back to the dendrite or transform into stable,
synapse-bearing spines. If synaptogenic contacts are in fact made by
protrusive dendritic filopodia, the active resorption of some of these
protrusions during early stages of differentiation may serve to draw
nascent synaptic contacts onto dendritic shafts (Povlishock, 1974;
Ulfhake and Cullheim, 1988; Saito et al., 1992). Alternatively, those
filopodia that do not synaptogenically engage axons may be resorbed,
whereas those that synaptogenically interact with axons may be
stabilized and remain extended.
The different classes of spiny protrusions thus may represent
progressive stages in synaptogenesis. We propose the following model of
synapse formation: (1) protrusive filopodia make the initial
synaptogenic interactions with axons; (2) filopodia with nascent
synaptic contacts may be drawn back to the dendrite shaft, or may be
converted to metastable protospines that could hold developing synapses
off the dendrite shafts in a structurally and functionally plastic
configuration; and (3) relatively stable spine synapses appear as shaft
synapses reemerge with stable spines, or by conversion (further
stabilization) of protospines bearing physiologically validated
synapses. This model does not exclude the possibility that stable
spines (with synapses) may emerge from shafts by mechanisms unrelated
to dynamic filopodia and protospines (Juraska and Fifkova, 1979; Miller
and Peters, 1981; Steward et al., 1988; Harris et al., 1989),
especially at later developmental stages (Papa et al., 1995). However,
during peak periods of axonal ingrowth and synaptogenesis, dendritic
filopodia may serve to enhance the ability of target cells to attract
and compete for axonal inputs (Cooper and Smith, 1992).
The idea that dendritic filopodia may be specialized sites of
synaptogenic interaction with axons has a long history (see Vaughn,
1989). Dendritic filopodia are known to be abundant during periods of
synaptogenesis (Morest, 1969a,b; Minkwitz and Holz, 1975; Berry and
Bradley, 1976a,b; Minkwitz, 1976; Miller and Peters, 1981; Phelps et
al., 1983; Ramoa et al., 1987; Ulfhake and Cullheim, 1988), and they
are often found by electron microscopy to be postsynaptic elements
(Hinds and Hinds, 1972; Hayes and Roberts, 1973; Skoff and Hamburger,
1974; Vaughn et al., 1974; Pappas et al., 1975; Saito et al., 1992).
Moreover, time-lapse studies indicate that filopodial interactions
precede formation of stable contacts between neuronal processes
(O'Connor et al., 1990; Baird et al., 1992; Cooper and Smith, 1992).
Together, these observations suggest that synaptic contacts are
initiated at actively growing regions on target cells. This idea is
consistent with a synaptogenic filopodial theory (Vaughn et al., 1974;
Berry and Bradley, 1976a,b; Vaughn, 1989), which posits that synaptic
contacts between neurons in the CNS are initiated predominantly between
filopodia on the growing distal tips of axonal and dendritic branches.
However, in many CNS regions including the hippocampus, the
spatiotemporal pattern of afferent axon ingrowth and dendrogenesis has
seemed incompatible with such an interaction between distal
tips (Andersen, 1979): later generated afferents often contact
progressively more proximal dendrite segments on target cells (Bayer,
1980; Bayer and Altman, 1987). Our observations may resolve this
apparent difficulty, because they indicate that even proximal dendritic
segments can exhibit abundant outgrowth of lateral growth cones and
filopodia during synaptogenic periods.
The abundance of dendritic protrusive motions observed in our
studies supports the hypothesis (Saito et al., 1992) that dendrites are
active partners in the initiation of synaptogenic cell-cell contacts,
not merely passive targets for axonal exploration. The relatively short
lifetimes (~10 min) of most of the filopodia at early stages in
development also suggest that any single image (e.g., from a fixed
tissue specimen) would drastically under-represent the total number of
filopodial eruptions that would occur during a typical developmental
synaptogenesis period extending over several days. This consideration
might reconcile the relatively small number of filopodia classically
observed on a given, fixed dendrite (e.g., Morest, 1969a,b) with a much
larger number of synapses eventually formed per dendrite. This
reconciliation, in turn, permits a hypothesis that dendritic filopodia
might actually be involved in establishing all axo-dendritic
synaptic contacts. In the future, it will be important to learn much
more about how the motility of the developing dendrite is generated and
regulated, and how protrusive motility relates to the array of
dendritic surface molecules necessary to permit the recognition of
appropriate axonal partners and the initiation of synaptogenesis.
FOOTNOTES
Received Nov. 27, 1995; revised Feb. 8, 1996; accepted Feb. 14, 1996.
This work was supported by grants from the National Institutes of
Health (NS28587, NS09027) and the National Institute of Mental Health
Silvio Conte Center for Neuroscience Research (MH48108). We thank Drs.
Nancy O'Rourke and Noam Ziv for discussion and critical comments on
this manuscript.
Correspondence should be addressed to Dr. Michael E. Dailey,
Department of Molecular and Cellular Physiology, Beckman Center,
Stanford University Medical Center, Stanford, CA
94305-5426.
REFERENCES
-
Agmon A,
Yang LT,
Jones EG,
O'Dowd DK
(1995)
Topological
precision in the thalamic projection to neonatal mouse barrel
cortex.
J Neurosci
15:549-561 .
[Abstract]
-
Amaral D,
Dent JA
(1981)
Development of the mossy fibers of
the dentate gyrus. I. A light and electron microscopic study of the
mossy fibers and their expansions.
J Comp Neurol
195:51-86 .
[Web of Science][Medline]
-
Andersen P
(1979)
Factors influencing functional connectivity
during hippocampal development.
Prog Brain Res
51:139-147 .
[Medline]
-
Baird DH,
Hatten ME,
Mason CA
(1992)
Cerebellar target
neurons provide a stop signal for afferent neurite extension in vitro.
J Neurosci
12:619-634 .
[Abstract]
-
Bayer SA
(1980)
The development of the hippocampal region in
the rat. I. Neurogenesis examined with
[3H]thymidine autoradiography.
J Comp Neurol
190:87-114 .
[Web of Science][Medline]
-
Bayer S,
Altman J
(1987)
Directions in neurogenetic gradients
and patterns of anatomical connections in the telencephalon.
Prog Neurobiol
29:57-106 .
[Web of Science][Medline]
-
Bentley D,
O'Connor TP
(1994)
Cytoskeletal events in growth
cone steering.
Curr Opin Neurobiol
4:43-48 .
[Medline]
-
Berry M,
Bradley PM
(1976a)
The application of network
analysis to the study of branching patterns of large dendritic fields.
Brain Res
109:111-132 .
[Web of Science][Medline]
-
Berry M,
Bradley P
(1976b)
The growth of the dendritic trees
of Purkinje cells in the cerebellum of the rat.
Brain Res
112:1-35 .
[Web of Science][Medline]
-
Bliss TVP, Chung SH, Stirling RV (1974) Structural and
functional development of the mossy fibre system in the hippocampus of
the post-natal rat. J Physiol (Lond) 239:92P-94P.
-
Buchs P-A,
Stoppini L,
Muller D
(1993)
Structural
modifications associated with synaptic development in area CA1 of rat
hippocampal organotypic cultures.
Dev Brain Res
71:81-91 .
[Medline]
-
Chien C-B,
Rosenthal DE,
Harris WA,
Holt CE
(1993)
Navigational errors made by growth cones without
filopodia in the embryonic Xenopus brain.
Neuron
11:237-251 .
[Web of Science][Medline]
-
Cooper MW,
Smith SJ
(1992)
A real-time analysis of growth
cone-target cell interactions during the formation of stable contacts
between hippocampal neurons in culture.
J Neurobiol
23:814-828 .
[Web of Science][Medline]
-
Dailey ME
(1996)
Dynamic optical imaging of neuronal
structure and physiology: confocal fluorescence microscopy in living
brain slices.
In: Brain mapping: the Methods
(Toga, A,
Mazziotta, J,
eds)
, p. 29. San Diego: Academic.
-
Dailey ME,
Buchanan J,
Bergles DE,
Smith SJ
(1994)
Mossy
fiber growth and synaptogenesis in rat hippocampal slices in
vitro.
J Neurosci
14:1060-1078 .
[Abstract]
-
Deitch JS,
Smith KL,
Swann JW,
Turner JN
(1991)
Ultrastructural investigation of neurons identified
and localized using the confocal scanning laser microscope.
J Electron Microsc Tech
18:82-90 .
[Web of Science][Medline]
-
Deutsch K,
Hillman H
(1977)
The effect of six fixatives on
the areas of rabbit neurons and rabbit and rat cerebral slices.
J Microsc
109:303-309 .
[Web of Science][Medline]
-
Gähwiler BH
(1984)
Development of the hippocampus
in vitro: cell types, synapses, and receptors.
Neuroscience
11:751-760 .
[Web of Science][Medline]
-
Gähwiler BH
(1988)
Organotypic cultures of neural
tissue.
Trends Neurosci
11:484-489 .
[Web of Science][Medline]
-
Godement P,
Wang LC,
Mason CA
(1994)
Retinal axon divergence
in the optic chiasm: dynamics of growth cone behavior at the midline.
J Neurosci
14:7024-7039 .
[Abstract]
-
Gottlieb DI,
Cowan WM
(1972)
On the distribution of axonal
terminals containing spheroidal and flattened synaptic vesicles in the
hippocampus and dentate gyrus of the rat and cat.
Z Zellforsch
129:413-429.[Web of Science][Medline]
-
Halloran MC,
Kalil K
(1994)
Dynamic behaviors of growth cones
extending in the corpus callosum of living cortical brain slices
observed with video microscopy.
J Neurosci
14:2161-2177 .
[Abstract]
-
Harris KM,
Jensen FE,
Tsao BH
(1989)
Ultrastructure,
development, and plasticity of dendritic spine synapses in area CA1 of
the rat hippocampus: extending our vision with serial electron
microscopy and three-dimensional analyses.
In: The hippocampus
 new vistas
(Chan-Palay, V,
Köhler, C,
eds)
, p. 33. New York: Liss. -
Harris KM,
Jensen FE,
Tsao BH
(1992)
Three-dimensional
structure of dendritic spines and synapses in rat hippocampus (CA1) at
postnatal day 15 and adult ages: implications for the maturation of
synaptic plasticity and long-term potentiation.
J Neurosci
12:2685-2705 .
[Abstract]
-
Harris WA,
Holt CE,
Bonhoeffer F
(1987)
Retinal axons with
and without their somata, growing to and arborizing in the tectum of
Xenopus embryos: a time-lapse video study of single fibres
in vivo.
Development
101:123-133 .
[Abstract]
-
Hayes BP, Roberts A (1973) Synaptic junction development in
the spinal cord of an amphibian embryo: an electron microscope study. Z
Zellforsch. 137:251-269.
-
Hinds JW,
Hinds PL
(1972)
Reconstruction of dendritic growth
cones in neonatal mouse olfactory bulb.
J Neurocytol
1:169-187 .
[Web of Science][Medline]
-
Honig MG,
Hume RI
(1986)
Fluorescent carbocyanine dyes allow
living neurons of identified origin to be studied in long-term culture.
J Cell Biol
103:171-186 .
[Abstract/Free Full Text]
-
Hosokawa T,
Bliss TVP,
Fine A
(1992)
Persistence of
individual dendritic spines in living brain slices.
NeuroReport
3:477-480 .
[Web of Science][Medline]
-
Hosokawa T,
Bliss TVP,
Fine A
(1994)
Quantitative
three-dimensional confocal microscopy of synaptic structures in living
brain tissue.
Microsc Res Tech
29:290-296 .
[Web of Science][Medline]
-
Juraska JM,
Fifkova E
(1979)
A Golgi study of the early
postnatal development of the visual cortex of the hooded rat.
J Comp Neurol
183:247-256 .
[Web of Science][Medline]
-
Kaethner RJ,
Stuermer CAO
(1992)
Dynamics of terminal arbor
formation and target approach of retinotectal axons in living zebrafish
embryos: a time-lapse study of single axons.
J Neurosci
12:3257-3271 .
[Abstract]
-
Kater SB,
Rehder V
(1995)
The sensory-motor role of growth
cone filopodia.
Curr Opin Neurobiol
5:68-74 .
[Medline]
-
LaVail JH,
Wolf MK
(1973)
Postnatal development of the mouse
dentate gyrus in organotypic cultures of the hippocampal formation.
Am J Anat
137:47-66 .
[Web of Science][Medline]
-
Lund JS,
Boothe RG,
Lund RD
(1977)
Development of neurons in
the visual cortex (area 17) of the monkey (Macaca
nemestrina): a Golgi study from fetal day 127 to postnatal
maturity.
J Comp Neurol
176:149-188 .
[Web of Science][Medline]
-
Mason CA,
Godement P
(1992)
Growth cone form reflects
interactions in visual pathways and cerebellar targets.
In: The nerve growth cone
(Letourneau, PC,
Kater, SB,
Macagno, ER,
eds)
, p. 405. New York: Raven.
-
Miller M,
Peters A
(1981)
Maturation of rat visual cortex.
II. A combined Golgi-electron microscope study of pyramidal neurons.
J Comp Neurol
203:555-573 .
[Web of Science][Medline]
-
Minkwitz H-G,
Holz L
(1975)
Die ontogenetische entwicklung
von pyramidenneuronen aus dem hippocampus (CA1) der ratte.
J Hirnforsch
16:37-54 .
[Medline]
-
Minkwitz H-G
(1976)
Zur entwicklung der neuronenstruktur des
hippocampus wahrend der pra- und postnatalen ontogenese der
albinoratte. I. Mitteilung: neurohistologische darstellung der
entwicklung langaxoniger neurone aus den regionen CA3 und CA4.
J Hirnforsch
17:213-231 .
[Medline]
-
Morest DK
(1969a)
The differentiation of cerebral dendrites:
a study of the post-migratory neuroblast in the medial nucleus of the
trapezoid body.
Z Anat Entwicklung-Gesch
128:271-289 .
-
Morest DK
(1969b)
The growth of dendrites in the mammalian
brain.
Z Anat Entwicklung-Gesch
128:290-317 .
-
Muller D,
Buchs P-A,
Stoppini L
(1993)
Time course of
synaptic development in hippocampal organotypic cultures.
Dev Brain Res
71:93-100 .
[Medline]
-
O'Connor TP,
Duerr JS,
Bentley D
(1990)
Pioneer growth cone
steering decisions mediated by single filopodial contacts in situ.
J Neurosci
10:3935-3946.
[Abstract]
-
O'Rourke NA,
Fraser SE
(1990)
Dynamic changes in optic fiber
terminal arbors lead to retinotypic map formation: an in
vivo confocal microscopic study.
Neuron
5:159-171.
[Web of Science][Medline]
-
O'Rourke NA,
Cline HT,
Fraser SE
(1994)
Rapid remodeling of
retinal arbors in the tectum with and without blockade of synaptic
transmission.
Neuron
12:921-934.
[Web of Science][Medline]
-
Papa M,
Bundman MC,
Greenberger V,
Segal M
(1995)
Morphological analysis of dendritic spine
development in primary cultures of hippocampal neurons.
J Neurosci
15:1-11 .
[Abstract]
-
Pappas GD,
Fox GQ,
Masurovsky EB,
Peterson ER,
Crain SM
(1975)
Neuronal growth cone relationships and their role
in synaptogenesis in the mammalian central nervous system.
Adv Neurol
12:163-180 .
[Web of Science][Medline]
-
Pawley J
(1995)
Handbook of biological confocal microscopy,
2nd Ed.
.
-
Phelps PE,
Adinolfi AM,
Levine MS
(1983)
Development of the
kitten substantia nigra: a rapid Golgi study of the early postnatal
period.
Brain Res
312:1-19 .
[Medline]
-
Pokorny J,
Yamamoto T
(1981)
Postnatal ontogenesis of
hippocampal CA1 area in rats. I. Development of dendritic arborisation
in pyramidal neurons.
Brain Res Bull
7:113-120 .
[Web of Science][Medline]
-
Povlishock JT
(1974)
The presence of perisomatic processes
during maturation of the hypoglossal, vagal and red nuclei of the rat.
Brain Res
1:272-278.
-
Pozzo Miller LD,
Petrozzino JJ,
Mahanty NK,
Connor JA
(1993)
Optical imaging of cytosolic calcium,
electrophysiology, and ultrastructure in pyramidal neurons of
organotypic slice cultures from rat hippocampus.
NeuroImage
1:109-120.[Medline]
-
Purpura D
(1975)
Dendritic differentiation in human cerebral
cortex: normal and aberrant developmental patterns.
Adv Neurol
12:91-116 .
[Web of Science][Medline]
-
Ramoa AS,
Campbell G,
Shatz CJ
(1987)
Transient morphological
features of identified ganglion cells in living fetal and neonatal
retina.
Science
237:522-525 .
[Abstract/Free Full Text]
-
Ruthel G,
Banker G
(1992)
``Waves'': growth cone-like
structures that travel down the processes of cultured hippocampal
neurons.
Soc Neurosci Abstr
18:1286.
-
Saito Y,
Murakami F,
Song W-J,
Okawa K,
Shimono K,
Katsumaru H
(1992)
Developing corticorubral axons of the cat form
synapses on filopodial dendritic protrusions.
Neurosci Lett
147:81-84 .
[Web of Science][Medline]
-
Skoff RP,
Hamburger V
(1974)
Fine structure of dendritic and
axonal growth cones in embryonic chick spinal cord.
J Comp Neurol
153:107-148 .
[Web of Science][Medline]
-
Smith SJ,
Cooper M,
Waxman A
(1990)
Laser microscopy of
subcellular structure in living neocortex: Can one see dendritic spines
twitch? XXIII Symposia Medica Hoechst: The Biology of Memory (Squire
LR, Lindenlaub E, eds), pp 49-71.
.
-
Sretavan D,
Reichardt LF
(1993)
Time-lapse video analysis of
retinal ganglion cell axon pathfinding at the mammalian optic chiasm:
growth cone guidance using intrinsic chiasm cues.
Neuron
10:761-777 .
[Web of Science][Medline]
-
Steward O,
Davis L,
Dotti C,
Phillips LL,
Rao A,
Banker G
(1988)
Protein synthesis and processing in cytoplasmic
microdomains beneath postsynaptic sites on CNS neurons. A mechanism for
establishing and maintaining a mosaic postsynaptic receptive surface.
Mol Neurobiol
2:227-261 .
[Web of Science][Medline]
-
Stoppini L,
Buchs P-A,
Muller D
(1991)
A simple method for
organotypic cultures of nervous tissue.
J Neurosci Methods
37:173-182 .
[Web of Science][Medline]
-
Terasaki M,
Dailey ME
(1995)
Confocal microscopy of living
cells.
In: Handbook of biological confocal microscopy,
(Pawley, JB,
eds)
, 2nd Ed
, p. 327. New York: Plenum.
-
Trommald M,
Jensen V,
Andersen P
(1995)
Analysis of dendritic
spines in rat CA1 pyramidal cells intracellularly filled with a
fluorescent dye.
J Comp Neurol
353:260-274 .
[Web of Science][Medline]
-
Ulfhake B,
Cullheim S
(1988)
Postnatal development of the cat
hind limb motoneurons. II. In vivo morphology of dendritic growth cones
and the maturation of dendrite morphology.
J Comp Neurol
278:88-102 .
[Web of Science][Medline]
-
Vaughn JE
(1989)
Fine structure of synaptogenesis in the
vertebrate central nervous system.
Synapse
3:255-285 .
[Web of Science][Medline]
-
Vaughn JE,
Henrikson CK,
Grieshaber JA
(1974)
A quantitative
study of synapses on motor neuron dendritic growth cones in developing
mouse spinal cord.
J Cell Biol
60:664-672 .
[Abstract/Free Full Text]
-
Westrum LE,
Blackstad TW
(1962)
An electron microscope study
of the stratum radiatum of the rat hippocampus (regio superior, CA1)
with particular emphasis on synaptology.
J Comp Neurol
119:281-292.
[Web of Science][Medline]
This article has been cited by other articles:
|
|
|
|
 
E. Porten, B. Seliger, V. A. Schneider, S. Woll, D. Stangel, R. Ramseger, and S. Kroger
The Process-inducing Activity of Transmembrane Agrin Requires Follistatin-like Domains
J. Biol. Chem.,
January 29, 2010;
285(5):
3114 - 3125.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. A. McKinney
Excitatory amino acid involvement in dendritic spine formation, maintenance and remodelling
J. Physiol.,
January 1, 2010;
588(1):
107 - 116.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Korobova and T. Svitkina
Molecular Architecture of Synaptic Actin Cytoskeleton in Hippocampal Neurons Reveals a Mechanism of Dendritic Spine Morphogenesis
Mol. Biol. Cell,
January 1, 2010;
21(1):
165 - 176.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. H. Kim, S. K. Park, S. T. Hong, Y. S. Jo, E. J. Kim, E. H. Park, S. B. Han, H.-S. Shin, W. Sun, H. T. Kim, et al.
Inositol 1,4,5-Trisphosphate 3-Kinase A Functions As a Scaffold for Synaptic Rac Signaling
J. Neurosci.,
November 4, 2009;
29(44):
14039 - 14049.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Takahashi, H. Yamazaki, K. Hanamura, Y. Sekino, and T. Shirao
Activity of the AMPA receptor regulates drebrin stabilization in dendritic spine morphogenesis
J. Cell Sci.,
April 15, 2009;
122(8):
1211 - 1219.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Li, G. Chen, B. Zhou, and S. Duan
Actin Filament Assembly by Myristoylated, Alanine-rich C Kinase Substrate-Phosphatidylinositol-4,5-diphosphate Signaling Is Critical for Dendrite Branching
Mol. Biol. Cell,
November 1, 2008;
19(11):
4804 - 4813.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. W. Luikart, W. Zhang, G. A. Wayman, C.-H. Kwon, G. L. Westbrook, and L. F. Parada
Neurotrophin-Dependent Dendritic Filopodial Motility: A Convergence on PI3K Signaling
J. Neurosci.,
July 2, 2008;
28(27):
7006 - 7012.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. M. Wegner, C. A. Nebhan, L. Hu, D. Majumdar, K. M. Meier, A. M. Weaver, and D. J. Webb
N-WASP and the Arp2/3 Complex Are Critical Regulators of Actin in the Development of Dendritic Spines and Synapses
J. Biol. Chem.,
June 6, 2008;
283(23):
15912 - 15920.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Arstikaitis, C. Gauthier-Campbell, R. Carolina Gutierrez Herrera, K. Huang, J. N. Levinson, T. H. Murphy, M. W. Kilimann, C. Sala, M. A. Colicos, and A. El-Husseini
Paralemmin-1, a Modulator of Filopodia Induction Is Required for Spine Maturation
Mol. Biol. Cell,
May 1, 2008;
19(5):
2026 - 2038.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. C. Ewald, K. R. Van Keuren-Jensen, C. D. Aizenman, and H. T. Cline
Roles of NR2A and NR2B in the Development of Dendritic Arbor Morphology In Vivo
J. Neurosci.,
January 23, 2008;
28(4):
850 - 861.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Shin and D. M. Chetkovich
Activity-dependent Regulation of h Channel Distribution in Hippocampal CA1 Pyramidal Neurons
J. Biol. Chem.,
November 9, 2007;
282(45):
33168 - 33180.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Furutani, H. Matsuno, M. Kawasaki, T. Sasaki, K. Mori, and Y. Yoshihara
Interaction between Telencephalin and ERM Family Proteins Mediates Dendritic Filopodia Formation
J. Neurosci.,
August 15, 2007;
27(33):
8866 - 8876.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
U. V. Nagerl, G. Kostinger, J. C. Anderson, K. A. C. Martin, and T. Bonhoeffer
Protracted Synaptogenesis after Activity-Dependent Spinogenesis in Hippocampal Neurons
J. Neurosci.,
July 25, 2007;
27(30):
8149 - 8156.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Aoto, P. Ting, B. Maghsoodi, N. Xu, M. Henkemeyer, and L. Chen
Postsynaptic EphrinB3 Promotes Shaft Glutamatergic Synapse Formation
J. Neurosci.,
July 11, 2007;
27(28):
7508 - 7519.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. Ramos, B. Gaudilliere, A. Bonni, and G. Gill
Transcription factor Sp4 regulates dendritic patterning during cerebellar maturation
PNAS,
June 5, 2007;
104(23):
9882 - 9887.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. Zhou, S. J. Martinez, M. Haber, E. V. Jones, D. Bouvier, G. Doucet, A. T. Corera, E. A. Fon, A. H. Zisch, and K. K. Murai
EphA4 Signaling Regulates Phospholipase C{gamma}1 Activation, Cofilin Membrane Association, and Dendritic Spine Morphology
J. Neurosci.,
May 9, 2007;
27(19):
5127 - 5138.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. B. Lang, V. Stein, T. Bonhoeffer, and C. Lohmann
Endogenous Brain-Derived Neurotrophic Factor Triggers Fast Calcium Transients at Synapses in Developing Dendrites
J. Neurosci.,
January 31, 2007;
27(5):
1097 - 1105.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Nishida and S. Okabe
Direct Astrocytic Contacts Regulate Local Maturation of Dendritic Spines
J. Neurosci.,
January 10, 2007;
27(2):
331 - 340.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Garcia-Lopez, V. Garcia-Marin, and M. Freire
Three-dimensional reconstruction and quantitative study of a pyramidal cell of a cajal histological preparation.
J. Neurosci.,
November 1, 2006;
26(44):
11249 - 11252.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. L. Sabo, R. A. Gomes, and A. K. McAllister
Formation of Presynaptic Terminals at Predefined Sites along Axons.
J. Neurosci.,
October 18, 2006;
26(42):
10813 - 10825.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. G. von der Ohe, C. Darian-Smith, C. C. Garner, and H. C. Heller
Ubiquitous and Temperature-Dependent Neural Plasticity in Hibernators
J. Neurosci.,
October 11, 2006;
26(41):
10590 - 10598.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Haber, L. Zhou, and K. K. Murai
Cooperative astrocyte and dendritic spine dynamics at hippocampal excitatory synapses.
J. Neurosci.,
August 30, 2006;
26(35):
8881 - 8891.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. C. Cottrell, R. E. Campbell, S.-K. Han, and A. E. Herbison
Postnatal Remodeling of Dendritic Structure and Spine Density in Gonadotropin-Releasing Hormone Neurons
Endocrinology,
August 1, 2006;
147(8):
3652 - 3661.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. L. Sanchez, B. J. Matthews, M. M. Meynard, B. Hu, S. Javed, and S. Cohen-Cory
BDNF increases synapse density in dendrites of developing tectal neurons in vivo
Development,
July 1, 2006;
133(13):
2477 - 2486.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Choi, J. Ko, J.-R. Lee, H. W. Lee, K. Kim, H. S. Chung, H. Kim, and E. Kim
ARF6 and EFA6A regulate the development and maintenance of dendritic spines.
J. Neurosci.,
May 3, 2006;
26(18):
4811 - 4819.
[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]
|
|
|
|
|
|
|
Y. Shi and I. M. Ethell
Integrins Control Dendritic Spine Plasticity in Hippocampal Neurons through NMDA Receptor and Ca2+/Calmodulin-Dependent Protein Kinase II-Mediated Actin Reorganization
J. Neurosci.,
February 8, 2006;
26(6):
1813 - 1822.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Z. Huang, K. Zang, and L. F. Reichardt
The origin recognition core complex regulates dendrite and spine development in postmitotic neurons
J. Cell Biol.,
August 15, 2005;
170(4):
527 - 535.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. M. Y. Moresco, S. Donaldson, A. Williamson, and A. J. Koleske
Integrin-Mediated Dendrite Branch Maintenance Requires Abelson (Abl) Family Kinases
J. Neurosci.,
June 29, 2005;
25(26):
6105 - 6118.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. A. Richards, J. M. Mateos, S. Hugel, V. de Paola, P. Caroni, B. H. Gahwiler, and R. A. McKinney
Glutamate induces the rapid formation of spine head protrusions in hippocampal slice cultures
PNAS,
April 26, 2005;
102(17):
6166 - 6171.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. W. Verzi, M. B. Rheuben, and S. M. Baer
Impact of Time-Dependent Changes in Spine Density and Spine Shape on the Input-Output Properties of a Dendritic Branch: A Computational Study
J Neurophysiol,
April 1, 2005;
93(4):
2073 - 2089.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. W. Gray, A. E. Kruchten, J. Chen, and M. A. McNiven
A dynamin-3 spliced variant modulates the actin/cortactin-dependent morphogenesis of dendritic spines
J. Cell Sci.,
March 15, 2005;
118(6):
1279 - 1290.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. L. Falls
Dasm1: A Receptor That Shapes Neuronal Dendrites and Turns On Silent Synapses?
Sci. Signal.,
March 8, 2005;
2005(274):
pe10 - pe10.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. E. Campbell, S.-K. Han, and A. E. Herbison
Biocytin Filling of Adult Gonadotropin-Releasing Hormone Neurons in Situ Reveals Extensive, Spiny, Dendritic Processes
Endocrinology,
March 1, 2005;
146(3):
1163 - 1169.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Futter, K. Uematsu, S. A. Bullock, Y. Kim, H. C. Hemmings Jr., A. Nishi, P. Greengard, and A. C. Nairn
Phosphorylation of spinophilin by ERK and cyclin-dependent PK 5 (Cdk5)
PNAS,
March 1, 2005;
102(9):
3489 - 3494.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Liao, H. Lin, P. Y. Law, and H. H. Loh
Mu-opioid receptors modulate the stability of dendritic spines
PNAS,
February 1, 2005;
102(5):
1725 - 1730.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Chen, R. A. Bender, K. L. Brunson, J. K. Pomper, D. E. Grigoriadis, W. Wurst, and T. Z. Baram
Modulation of dendritic differentiation by corticotropin-releasing factor in the developing hippocampus
PNAS,
November 2, 2004;
101(44):
15782 - 15787.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Roelandse and A. Matus
Hypothermia-Associated Loss of Dendritic Spines
J. Neurosci.,
September 8, 2004;
24(36):
7843 - 7847.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. D. Topp, N. W. Gray, R. D. Gerard, and B. F. Horazdovsky
Alsin Is a Rab5 and Rac1 Guanine Nucleotide Exchange Factor
J. Biol. Chem.,
June 4, 2004;
279(23):
24612 - 24623.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Gauthier-Campbell, D. S. Bredt, T. H. Murphy, and A. E.-D. El-Husseini
Regulation of Dendritic Branching and Filopodia Formation in Hippocampal Neurons by Specific Acylated Protein Motifs
Mol. Biol. Cell,
May 1, 2004;
15(5):
2205 - 2217.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. W. Williams and J. W. Truman
Mechanisms of Dendritic Elaboration of Sensory Neurons in Drosophila: Insights from In Vivo Time Lapse
J. Neurosci.,
February 18, 2004;
24(7):
1541 - 1550.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. Nikonenko, P. Jourdain, and D. Muller
Presynaptic Remodeling Contributes to Activity-Dependent Synaptogenesis
J. Neurosci.,
September 17, 2003;
23(24):
8498 - 8505.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. A. Eaton and G. W. Davis
Synapse disassembly
Genes & Dev.,
September 1, 2003;
17(17):
2075 - 2082.
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Portera-Cailliau, D. T. Pan, and R. Yuste
Activity-Regulated Dynamic Behavior of Early Dendritic Protrusions: Evidence for Different Types of Dendritic Filopodia
J. Neurosci.,
August 6, 2003;
23(18):
7129 - 7142.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Takahashi, Y. Sekino, S. Tanaka, T. Mizui, S. Kishi, and T. Shirao
Drebrin-Dependent Actin Clustering in Dendritic Filopodia Governs Synaptic Targeting of Postsynaptic Density-95 and Dendritic Spine Morphogenesis
J. Neurosci.,
July 23, 2003;
23(16):
6586 - 6595.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. C. Martinez, T. Ochiishi, M. Majewski, and K. S. Kosik
Dual regulation of neuronal morphogenesis by a {delta}-catenin-cortactin complex and Rho
J. Cell Biol.,
July 7, 2003;
162(1):
99 - 111.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Cohen-Cory
The Developing Synapse: Construction and Modulation of Synaptic Structures and Circuits
Science,
October 25, 2002;
298(5594):
770 - 776.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. M. Inglis, R. Crockett, S. Korada, W. C. Abraham, M. Hollmann, and R. G. Kalb
The AMPA Receptor Subunit GluR1 Regulates Dendritic Architecture of Motor Neurons
J. Neurosci.,
September 15, 2002;
22(18):
8042 - 8051.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. M. Huber, S. M. Gallagher, S. T. Warren, and M. F. Bear
Altered synaptic plasticity in a mouse model of fragile X mental retardation
PNAS,
May 28, 2002;
99(11):
7746 - 7750.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-S. Uhm, B. Neuhuber, B. Lowe, V. Crocker, and M. P. Daniels
Synapse-Forming Axons and Recombinant Agrin Induce Microprocess Formation on Myotubes
J. Neurosci.,
December 15, 2001;
21(24):
9678 - 9689.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. Khazipov, M. Esclapez, O. Caillard, C. Bernard, I. Khalilov, R. Tyzio, J. Hirsch, V. Dzhala, B. Berger, and Y. Ben-Ari
Early Development of Neuronal Activity in the Primate Hippocampus In Utero
J. Neurosci.,
December 15, 2001;
21(24):
9770 - 9781.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
O. Prange and T. H. Murphy
Modular Transport of Postsynaptic Density-95 Clusters and Association with Stable Spine Precursors during Early Development of Cortical Neurons
J. Neurosci.,
December 1, 2001;
21(23):
9325 - 9333.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Okabe, A. Miwa, and H. Okado
Spine Formation and Correlated Assembly of Presynaptic and Postsynaptic Molecules
J. Neurosci.,
August 15, 2001;
21(16):
6105 - 6114.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Geinisman, R. W. Berry, J. F. Disterhoft, J. M. Power, and E. A. Van der Zee
Associative Learning Elicits the Formation of Multiple-Synapse Boutons
J. Neurosci.,
August 1, 2001;
21(15):
5568 - 5573.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. A. Nimchinsky, A. M. Oberlander, and K. Svoboda
Abnormal Development of Dendritic Spines in FMR1 Knock-Out Mice
J. Neurosci.,
July 15, 2001;
21(14):
5139 - 5146.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Majewska, A. Tashiro, and R. Yuste
Regulation of Spine Calcium Dynamics by Rapid Spine Motility
J. Neurosci.,
November 15, 2000;
20(22):
8262 - 8268.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. E. Chen, B. Lendvai, E. A. Nimchinsky, B. Burbach, K. Fox, and K. Svoboda
Imaging High-Resolution Structure of GFP-Expressing Neurons in Neocortex In Vivo
Learn. Mem.,
November 1, 2000;
7(6):
433 - 441.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
A. Matus
Actin-Based Plasticity in Dendritic Spines
Science,
October 27, 2000;
290(5492):
754 - 758.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
A. K. McAllister
Cellular and Molecular Mechanisms of Dendrite Growth
Cereb Cortex,
October 1, 2000;
10(10):
963 - 973.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Y. Nakayama, M. B. Harms, and L. Luo
Small GTPases Rac and Rho in the Maintenance of Dendritic Spines and Branches in Hippocampal Pyramidal Neurons
J. Neurosci.,
July 15, 2000;
20(14):
5329 - 5338.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W. T. Wong, B. E. Faulkner-Jones, J. R. Sanes, and R. O. L. Wong
Rapid Dendritic Remodeling in the Developing Retina: Dependence on Neurotransmission and Reciprocal Regulation by Rac and Rho
J. Neurosci.,
July 1, 2000;
20(13):
5024 - 5036.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Dunaevsky, A. Tashiro, A. Majewska, C. Mason, and R. Yuste
Developmental regulation of spine motility in the mammalian central nervous system
PNAS,
November 9, 1999;
96(23):
13438 - 13443.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. T. Kavalali, J. Klingauf, and R. W. Tsien
Activity-dependent regulation of synaptic clustering in a hippocampal culture system
PNAS,
October 26, 1999;
96(22):
12893 - 12900.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. Y. Wu, D. J. Zou, I. Rajan, and H. Cline
Dendritic Dynamics In Vivo Change during Neuronal Maturation
J. Neurosci.,
June 1, 1999;
19(11):
4472 - 4483.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Maletic-Savatic, R. Malinow, and K. Svoboda
Rapid Dendritic Morphogenesis in CA1 Hippocampal Dendrites Induced by Synaptic Activity
Science,
March 19, 1999;
283(5409):
1923 - 1927.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
S. Halpain, A. Hipolito, and L. Saffer
Regulation of F-Actin Stability in Dendritic Spines by Glutamate Receptors and Calcineurin
J. Neurosci.,
December 1, 1998;
18(23):
9835 - 9844.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Shimada, C. A. Mason, and M. E. Morrison
TrkB Signaling Modulates Spine Density and Morphology Independent of Dendrite Structure in Cultured Neonatal Purkinje Cells
J. Neurosci.,
November 1, 1998;
18(21):
8559 - 8570.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. C. Fiala, M. Feinberg, V. Popov, and K. M. Harris
Synaptogenesis Via Dendritic Filopodia in Developing Hippocampal Area CA1
J. Neurosci.,
November 1, 1998;
18(21):
8900 - 8911.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Jiang, C. L. Lee, K. L. Smith, and J. W. Swann
Spine Loss and Other Persistent Alterations of Hippocampal Pyramidal Cell Dendrites in a Model of Early-Onset Epilepsy
J. Neurosci.,
October 15, 1998;
18(20):
8356 - 8368.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. Rajan and H. T. Cline
Glutamate Receptor Activity Is Required for Normal Development of Tectal Cell Dendrites In Vivo
J. Neurosci.,
October 1, 1998;
18(19):
7836 - 7846.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Boyer, T. Schikorski, and C. F. Stevens
Comparison of Hippocampal Dendritic Spines in Culture and in Brain
J. Neurosci.,
July 15, 1998;
18(14):
5294 - 5300.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Saito, W.-J. Song, and F. Murakami
Preferential Termination of Corticorubral Axons on Spine-Like Dendritic Protrusions in Developing Cat
J. Neurosci.,
November 15, 1997;
17(22):
8792 - 8803.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Mundel, H. W. Heid, T. M. Mundel, M. Kruger, J. Reiser, and W. Kriz
Synaptopodin: An Actin-associated Protein in Telencephalic Dendrites and Renal Podocytes
J. Cell Biol.,
October 6, 1997;
139(1):
193 - 204.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. H. Kossel, C. V. Williams, M. Schweizer, and S. B. Kater
Afferent Innervation Influences the Development of Dendritic Branches and Spines via Both Activity-Dependent and Non-Activity-Dependent Mechanisms
J. Neurosci.,
August 15, 1997;
17(16):
6314 - 6324.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. L. Shorte
N-Methyl-D-Aspartate Evokes Rapid Net Depolymerization of Filamentous Actin in Cultured Rat Cerebellar Granule Cells
J Neurophysiol,
August 1, 1997;
78(2):
1135 - 1143.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Collin, K. Miyaguchi, and M. Segal
Dendritic Spine Density and LTP Induction in Cultured Hippocampal Slices
J Neurophysiol,
March 1, 1997;
77(3):
1614 - 1623.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. C. Katz and C. J. Shatz
Synaptic Activity and the Construction of Cortical Circuits
Science,
November 15, 1996;
274(5290):
1133 - 1138.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
T. Krucker, G. R. Siggins, and S. Halpain
Dynamic actin filaments are required for stable long-term potentiation (LTP) in area CA1 of the hippocampus
PNAS,
June 6, 2000;
97(12):
6856 - 6861.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
