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The Journal of Neuroscience, November 1, 1998, 18(21):8900-8911
Synaptogenesis Via Dendritic Filopodia in Developing Hippocampal
Area CA1
John C.
Fiala1,
Marcia
Feinberg1,
Viktor
Popov2, and
Kristen M.
Harris1
1 Division of Neuroscience in the Department of
Neurology, Children's Hospital, Boston Massachusetts, and
2 Institute of Cell Biophysics, Russian Academy of
Sciences, Pushchino, Moscow Region, 142292, Russia
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ABSTRACT |
To determine the role of dendritic filopodia in the genesis of
excitatory synaptic contacts and dendritic spines in hippocampal area
CA1, serial section electron microscopy and three-dimensional analysis
of 16 volumes of neuropil from nine male rat pups, aged postnatal day 1 (P1) through P12, were performed. The analysis revealed that
numerous dendritic filopodia formed asymmetric synaptic contacts with
axons and with filopodia extending from axons, especially during the
first postnatal week. At P1, 22 ± 5.5% of synapses occurred on
dendritic filopodia, with 19 ± 5.9% on filopodia at P4, 20 ± 8.0% at P6, decreasing to 7.2 ± 4.7% at P12
(p < 0.02). Synapses were found at the base
and along the entire length of filopodia, with many filopodia
exhibiting multiple synaptic contacts. In all, 162 completely traceable
dendritic filopodia received 255 asymmetric synaptic contacts. These
synapses were found at all parts of filopodia with equal frequency,
usually occurring on fusiform swellings of the diameter. Most synaptic
contacts (53 ± 11%) occurred directly on dendritic shafts during
the first postnatal week. A smaller but still substantial portion
(32 ± 12%) of synapses were on shafts at P12
(p < 0.036). There was a highly significant
(p < 0.0002) increase in the proportion of dendritic spine synapses with age, rising from just 4.9 ± 4.3% at P1 to 37 ± 14% at P12. The concurrence of primarily shaft and filopodial synapses in the first postnatal week suggests that filopodia
recruit shaft synapses that later give rise to spines through a process
of outgrowth.
Key words:
serial electron microscopy; postsynaptic density; synapse; rat; pyramidal cell; dendrites; spines; three-dimensional
reconstructions
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INTRODUCTION |
Most excitatory synapses in adult
brain are located on the bulbous heads of dendritic spines (Harris and
Kater, 1994 ). During development, before the expression of spines,
cortical dendrites exhibit longer, thinner processes, often without a
bulbous head (Purpura, 1975). These dendritic filopodia disappear, and
spines appear as the cortex matures. This transition can be disrupted by developmental abnormalities that induce mental retardation, such as
fetal alcohol syndrome (Purpura, 1975; Stoltenburg-Didinger and Spohr,
1983; Galofre et al., 1987). Dendrites from mentally retarded adults
often appear to be covered with dendritic filopodia instead of spines
(Marin-Padilla, 1972; Wisniewski et al., 1991). The significance of
these findings is not entirely clear, partly because the role of
dendritic filopodia in synapse and spine formation is uncertain.
Several recent in vitro studies have shown that filopodia
are active along the lengths of dendrites during postnatal
synaptogenesis in hippocampal area CA1. Confocal microscopy of
dissociated hippocampal neurons from embryonic or neonatal rats
revealed long, headless dendritic protrusions during the initial 1-2
weeks in culture (Papa et al., 1995; Ziv and Smith, 1996). These
filopodia were remarkably transient structures, extending and
retracting in <10 min in some cases. Although some filopodia made
apparent synaptic contacts with axons (Ziv and Smith, 1996),
ultrastructural examination found that the majority of filopodia at 1 week in culture had no synaptic contacts (Papa et al., 1995). Over a
period of 4 weeks in culture, there was a transition from relatively
sparse, yet dynamic filopodial protrusions, to a dense distribution of
stable, adult-like spines. Similar results were obtained from area CA1 in hippocampal slice cultures (Dailey and Smith, 1996; Collin et al.,
1997).
The appearance of filopodia before the formation of spines, and the
fact that some filopodia retract into a more stable, spine-like shape
has lead to the hypothesis that most spines form directly from
filopodia (Ziv and Smith, 1996). This hypothesis posits that filopodia
initiate synaptic contacts that mature into spine synapses. In older
cultures, rapid extension of stable spines directly from the dendrite
shafts was observed without the prior appearance of dynamic filopodia
(Dailey and Smith, 1996). This suggests that spines can arise from
shaft synapses and is consistent with ultrastructural data showing that
synapses occur primarily on dendritic shafts and stubby spines before
postnatal day 15 (P15), with a subsequent transition to most synapses
on longer thin spines in the young adult rat (Schwartz et al., 1968;
Cotman et al., 1973; Miller and Peters, 1981; Porkorny and Yamamoto,
1981; Schwartzkroin et al., 1982; Steward and Falk, 1991; Harris et
al., 1992).
To determine whether dendritic filopodia make synaptic contacts and
whether filopodia could be involved in the production of shaft
synapses, we conducted a serial electron microscopy analysis of
in vivo development of synaptic contacts in area CA1.
Volumetric analyses were used to identify the three-dimensional
structures (dendrites, spines, and filopodia) on which synapses
occurred. The results show that filopodial synapses develop
concomitantly with an abundance of shaft synapses, before spine
formation. The data support a role for filopodia in the genesis of
shaft synapses, which later develop into dendritic spines.
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MATERIALS AND METHODS |
Animals. Nine male rat pups of the Long-Evans strain
at four different ages were used (Table
1). Three animals were from P1, and two
each were from P4, P6, and P12. Our procedures follow National
Institutes of Health guidelines and undergo yearly review by the Animal
Care and Use Committee at Children's Hospital.
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Table 1.
Location, volume, and number of synapses for each set of
serial section electron micrographs. R numbers are individual rat
numbers for a total of nine rats; letters a, b, and c are the specific
series identifiers
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Tissue preparation and microscopy. Animals were perfused
through the heart under deep (80 mg/kg) pentobarbital anesthesia with
2.5% glutaraldehyde, 2% paraformaldehyde, 2 mM
CaCl2, and 4 mM MgCl2 in 0.1 M cacodylate buffer. Whole brains were removed after 1 hr
and post-fixed overnight in the same fixative. The next day the brain
was rinsed in buffer and sliced into 300 µm slabs, from which the
hippocampus with dentate gyrus was dissected.
Routine processing of the hippocampi for electron microscopy (EM) was
accelerated using the PELCO 3450 laboratory microwave processor (Ted
Pella Inc., Redding, CA). A slab of hippocampus was placed in an
individual microcentrifuge tube with 1% osmium and 1.5% potassium
ferrocyanide in 0.1 M cacodylate buffer solution, cooled in
an ice bath to <15°C, then microwaved for 2.5 min at 37°C. After
several buffer rinses, a second stage osmium solution (1% osmium in
0.1 M cacodylate buffer) was added, cooled to <15°C, and
then microwaved again for 2.5 min at 37°C. The tissue was rinsed
several times in buffer followed by two brief water rinses and then a
1% aqueous uranyl acetate was added for en bloc staining. This
solution was also cooled to <15°C and then microwaved for 2.5 min at
37°C, followed by two brief water rinses and then dehydrated through
graded acetones beginning with 50%, then 70, 90, and 100% exchanges
in the microwave at 45°C, 40 sec each exchange. The dehydrated tissue
was infiltrated in the microwave using acetone mixed with 1:1 Epon and
Spurr's resin mixtures for 15 min at 50°C. This was followed by two
changes of fresh 100% Epon/Spurr's for 15 min each at 50°C. For
final polymerization and curing the tissue was transferred to
BEEM embedding capsules. Some tissue was cured in the microwave
and others were cured in a 60°C conventional oven for 48 hr.
The cured blocks were cut with a diamond Histo knife on a Reichart
Ultracut S (Leica, Allendale, NJ) ultramicrotome to obtain a full-face
section (1 µm thickness) of the hippocampus and dentate gyrus. These
were stained with 1% toluidine blue and examined under light
microscopy. A trapezoid, 30-115 µm in height and 50-115 µm base
width, was cut from the apical dendritic field of area CA1 using a
Diatome square-shaped trim tool (Electron Microscopy Sciences, Fort
Washington, PA). Table 1 gives the location of each trapezoid,
illustrating how both proximal and distal portions of the apical field
were sampled at each age.
Serial sections were made from the trimmed blocks with silver to
platinum coloring (nominally 70 nm). The number of sections varied from
52 to 135 for each of the 16 series. Series were mounted on Synaptek
pioloform-coated slot grids (Ted Pella Inc.) and stained with saturated
ethanolic uranyl acetate, followed by Reynold's lead citrate, each for
5 min. Each grid was then loaded into a grid cassette (Advanced
Microscopy Techniques, Danvers, MA) and stored in numbered gelatin
capsules (Ernest Fullam Inc., Latham, NY). The grid cassettes were
mounted in rotating stages to obtain consistent orientation of sections
on adjacent grids during photography at a JEOL (Peabody, MA) 1200EX
electron microscope. Each series was photographed at 6000×
magnification along with a corresponding calibration grid (0.463 µm
per square, Ernest Fullam Inc.) and printed at 16000× magnification on
8.5 × 11 inch paper.
Analysis. A volume of tissue was analyzed from the middle of
each series of micrographs so that neuronal structures (synapses, axons, dendrites, spines, and filopodia) could be traced through the
series and identified by three-dimensional (3D) structure (Table 1).
Each micrograph in the volume was systematically scanned for synapses.
Asymmetric synapses were identified by the presence of a postsynaptic
density (PSD) and at least two presynaptic clear vesicles 30-40 nm in
diameter in close proximity to the PSD. En face sections of PSDs were
included when vesicles were found on an adjacent section. In some
instances membrane densities were observed at points of close
apposition in the absence of synaptic vesicles. These were classified
as nonsynaptic surface specializations rather than as synapses.
Symmetrical synapses were differentiated from asymmetrical ones by
thinner densities on both sides of the synapse. Once a synapse was
identified, the postsynaptic process was traced through the series to
identify the location of the synapse as dendritic shaft, stubby, spine,
or filopodium. No attempt was made to differentiate synapses on aspiny
interneurons from those on pyramidal neurons because it is difficult to
distinguish these cell types at these early ages (see Discussion).
A shaft synapse was one that occurred on the surface of a dendrite. The
dendrite was differentiated from spines and filopodia by a less densely
stained cytoplasm that contained microtubules and mitochondria. The
nature of the dendrite at the synapse location was further
characterized as either thin, varicose, or apical-like. Apical-like
dendrites were ones with a large cross-section (i.e., >1 µm
diameter) and a well organized array of microtubules. Other dendrites
exhibited a nonuniform cross-section in which varicose regions,
enlargements with a watery cytoplasm and very sparse or disorganized
microtubules, were interspersed with thin regions that were
microtubule-dense and of much smaller diameter.
A stubby synapse occurred on a short (length less than width)
protrusion of the surface of the dendrite without a constricted neck
region. The protrusion was devoid of microtubules and contained a
grainy appearance, typically darker than the adjacent dendritic cytoplasm. Sometimes these stubby protrusions had features
uncharacteristic of more mature material (Harris et al., 1992), such as
having a pointy tip with a small synapse at the tip or a large synapse at the base, or having multiple synapses. Such synapses were classified as atypical stubby synapses.
A spine synapse was one that occurred at the swollen tip (head) of a
relatively short (<2 µm) protrusion separated from the dendrite by a
constricted neck region. Criteria for spine classification were the
same as in previous studies (Peters and Kaiserman-Abramof, 1970; Harris
et al., 1992), however, some spines exhibited characteristics that were
not typical of spines in area CA1 of the adult. These unusual
characteristics included having multiple synapses on the head, having
an additional asymmetrical synapse at the base or neck, having a very
dark, grainy cytoplasm, having multiple branches, and having an
abnormal neck morphology (e.g., too small, <80 nm, or with a swelling
in the middle). Synapses occurring on these processes were classified
as atypical spine synapses. Short emerging or retracting filopodia,
when present, were probably placed into an atypical category.
Filopodia synapses occurred on dendritic protrusions that were
nonspine-like, i.e., not having a single bulbous head on a narrower
stalk. Filopodia were distinguished from stubbies and spines by having
greater length and/or a pointy, rather than a bulbous tip. Sometimes
filopodia could be identified by having a very narrow or variable
cross-sectional area or having synaptic contacts distributed along
their length. A synapse on a filopodium was further classified as being
at a tip, mid, or base location. A tip synapse occurred at the
filopodium tip or on a swelling in continuity with the tip. A base
synapse was located on the dendritic shaft at the origin of the
filopodium or on an enlargement of the filopodium in continuity with
the shaft. A mid synapse was located at any location along the
filopodium between its tip and base.
A final category of synapse location was on a growth cone or
lamellipodium. Growth cones and lamellipodia were identified by a
grainy, microtubule-free cytoplasm, often filled with large vesicular
compartments. Unlike filopodia, these structures were not narrow
cylindrical processes protruding from a dendrite. They had a complex
three-dimensional structure much larger than filopodia, often in the
form of a flattened sheet.
A continuous volume of tissue containing 50-120 synapses was examined
from the middle of each series in a systematic section-by-section analysis. Synapses were identified and traced through the series so
that they were only counted once. If the process on which a synapse
occurred did not contain microtubules, it was traced through the series
to its tip and origin. The origins of these processes could usually be
traced to a main shaft that did contain microtubules. The shaft of
origin could be a dendrite or an axon, identified by determining if it
was postsynaptic or presynaptic to a synapse located somewhere along
its length. If the origin could not be identified, then the synapse was
not included in the analyses of synapse types. ANOVA were computed
using Statistica software (StatSoft Inc., Tulsa, OK).
Reconstructions. To obtain 3D reconstructions and
measurements from the tissue, micrographs were digitized using a
Hewlett-Packard (Palo Alto, CA) ScanJet 4c flatbed scanner. Serial
sections were then aligned on a Windows NT (Microsoft, Redmond, WA)
personal computer using IGL Align, developed by JCF in the Image
Graphics Laboratory (IGL) of the Mental Retardation Research Center at Children's Hospital. The magnification of each digitized series was
calibrated using the standard grid that was imaged with the same
settings as used for the series.
Section thickness was estimated for each series by counting the number
of sections spanned by longitudinally sectioned mitochondria in single
sections. The diameter of a mitochondrion was measured on a calibrated
section image. Because mitochondria are cylindrical, section thickness
could be estimated for each mitochondrion using: thickness (micrometers
per section) = measured diameter divided by the number of sections
spanned. The mean section thickness for each series was obtained by
averaging the results from 22-25 mitochondria distributed evenly
through the series.
Objects in aligned and calibrated series were measured and traced using
IGL Trace, a Windows software application also developed in the IGL. 3D
surface reconstructions of particular objects were generated in VRML
format by IGL Trace and then imported into 3D Studio MAX (Autodesk
Inc., San Rafael, CA) using Keith Rule's Crossroads program
(http://www.europa.com/~keithr/). For production of figures,
micrographs were scanned at 600 dpi with the ScanJet 4c. Rendered 3D
images and scanned EMs were combined and annotated with Photo-Paint 7 (Corel Corp., Ottawa, Ontario, Canada).
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RESULTS |
Electron micrographs from 1-12-d-old animals exhibited varying
amounts of extracellular space (Figs.
1-4).
Extracellular space appeared to decrease with age until by day 12 there
was very little extracellular space, as in adult hippocampus. The
neuropil contained numerous axonal and dendritic profiles, many with
well ordered, often densely packed microtubules at all ages. The
density of these profiles increased with age while their average
diameter decreased, suggesting an increasingly fine arborization of
both dendritic and axonal processes over the first two postnatal
weeks.
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Figure 1.
Representative CA1 neuropil from postnatal day 1 (R53) has large amounts of extracellular space (ECS). A
dendrite (D) with well organized microtubules
gives rise to a dendritic filopodium (df), which
continues on adjacent serial sections. An asymmetric synapse
(s) on a stubby dendritic protrusion is evident
at the top of the figure. Also in evidence are
nonsynaptic surface specializations (solid square
arrows). The tip of an axonal filopodium
(af), identified by tracing it back to its axonal
origin, has a surface specialization or possibly a nascent synapse
(open arrow) where it contacts the tip of a dendritic
filopodium (f), also identified through
series. Scale bar, 1 µm.
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Figure 2.
Representative CA1 neuropil from postnatal
day 4 (R48a). A dendritic filopodium (df) emerges
from the middle of a dendrite (D). The entire
filopodium is reconstructed in Figure 5. A synapse on an apparently
stubby profile is actually at the base (B) of a
filopodium that could be traced on adjacent serial sections. A shaft
synapse (sh) has synaptic vesicles in a docked position,
suggesting the synapse is functional. The profile in the upper left
corner (f) makes synaptic contact with an
axon containing docked vesicles. This synapse occurs in the middle of a
dendritic filopodium that could be followed for 70 sections to its tip,
at which there was no synaptic contact. Scale bar, 1 µm.
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Figure 3.
Neuropil from postnatal day 6 (R43b) showing
varicosities (V) with interposed thin
regions that give some dendrites a beaded appearance. Some varicosities
had a watery cytoplasm (W) with organelles
compressed to the periphery, suggesting that they might have undergone
swelling. A synapse (s) located on a dendritic
shaft has the appearance of a symmetric synapse with equally thin
densities on both membranes. Asymmetric synaptic contacts on two
dendritic filopodia profiles (f) were
identified through serial sections. Note that these profiles might be
mistaken for dendritic spines if they were viewed only on this section.
Scale bar, 1 µm.
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Figure 4.
The neuropil from postnatal day 12 (R45a) is much
denser than in the first postnatal week, with many more profiles of
small processes. Asymmetric synapses are seen on thin dendritic spines
(t), as well as on stubby spines
(s) and dendritic shafts (sh).
Many dendritic spines at this age do not have the typical
characteristics of adult CA1 spines. An atypical thin spine
(a) receives synaptic contacts from two different
axons. Multiple synapses are rarely identifiable on single sections.
The atypical stubby (as) in the lower left has only one
of its two synapses visible on this section, whereas two synapses
(arrows) are apparent on the atypical stubby
(as) in the inset. One postsynaptic
process (?) could not be traced to its origin and, therefore, could not
be unequivocally identified. Scale bar, 1 µm.
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Some dendrites in most (but not all) series exhibited enlargements with
less dense cytoplasm and disorganized, sparsely distributed microtubules (Fig. 3). These enlargements were spherical to fusiform in
shape and up to 3 µm in diameter. They were separated along the
length of a dendrite by much thinner regions with well ordered microtubule arrays. These varicosities gave the dendrites a beaded appearance consistent with that observed in other developmental studies
(Schwartz et al., 1968; Morest, 1969a; Pokorny and Yamamoto, 1981).
Many varicosities had the appearance of being swollen as evidenced by
watery cytoplasm, few organelles, and the presence of clear vacuoles,
but mitochondria were consistently small and dense, exhibiting no signs
of swelling in all dendrites and axons.
Synapses were identifiable at all ages by the presence of spherical
vesicles 30-40 nm in diameter clustered near a darkly stained,
paramembranous density (Figs. 1-4). Most synapses had the typical
appearance of asymmetric excitatory contacts, with a presynaptic cluster of vesicles apposed to a PSD. Occasionally, symmetric synapses
were observed with a thinner PSD that was matched by an equal density
on the presynaptic side (Fig. 3). In the first postnatal week there
were many small asymmetric synaptic contacts with just a few synaptic
vesicles, some of which were in close proximity to the presynaptic
membrane, suggesting that they were docked at presynaptic release sites
and that the synapses were functional (Fig. 2). In addition, there were
numerous cell-cell contacts with small paramembranous densities
without any synaptic vesicles. These apparently nonsynaptic surface
specializations had densities at one or both of the apposed cell
membranes (Fig. 1).
Numerous processes having characteristics consistent with those of
dendritic filopodia (Morest, 1969b; Ulfhake and Cullheim, 1988; Papa et
al., 1995; Dailey and Smith, 1996; Ziv and Smith, 1996; Collin et al.,
1997) were observed in developing area CA1. These filopodia emerged
primarily from dendritic shafts with well organized microtubule arrays
(Figs. 1, 2), rather than from growth cones of dendrite terminals
(Vaughn, 1989). Dendritic filopodia were devoid of microtubules and
other organelles, although sometimes thin, clear tubules or vesicles
were seen. The cytoplasm was dark and grainy, consistent with a dense
actin matrix (Markham and Fifkova, 1986).
Dendritic filopodia differed in appearance from dendritic spines,
lacking bulbous heads with single synaptic contacts and thin necks, as
in adult spines. Dendritic filopodia were longer than typical adult
spines and had a pointy tip, frequently without a synapse (Figs. 2,
5). Most dendritic filopodia were
irregularly cylindrical in shape. The cross-sectional diameter was
variable, but usually 0.1-0.4 µm (Figs. 1, 2). Along the length of a
single filopodium the diameter could vary by an order of magnitude
(Fig. 5). In single sections it was impossible to distinguish
cross-sections of filopodia from cross-sections of dendritic spines
(Fig. 3), instead dendritic filopodia were accurately identified by
tracing their entire length through serial sections.
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Figure 5.
Three-dimensional reconstruction of the dendritic
filopodium whose origin is shown in Figure 2. The filopodium is ~11
µm long from origin to tip. Filopodia of this length were rarely
captured in series of only 100 ultrathin sections. At its narrowest
point (solid arrow) the filopodium has a diameter of
~0.1 µm, whereas the maximum diameter is ~1 µm. The filopodium
is enfolded in stubby protrusions from the axon, one of which
(star) appears to make a synaptic contact with the
filopodium (F) (inset, star
arrow). Scale bar in inset, 0.5 µm; 3D scale bar, 1 µm.
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Dendritic filopodia were observed at all ages but most frequently
during the first postnatal week. By P12, many actin-filled dendritic
processes had the shape of adult spines with a bulbous head and a thin
neck (Fig. 4). However, these early spines often exhibited
characteristics not typical of adult spines. Some atypical spines had
darker cytoplasm than adult spines stained by the same protocol (Harris
et al., 1992; Spacek and Harris, 1997). Many atypical spines had
multiple synaptic contacts from different axons. In some cases it was
difficult to distinguish a filopodium from an atypical spine (Fig.
6). Such processes had a bulbous head
with a very long neck, similar in appearance to the "torturous spines" observed in some forms of mental retardation (Purpura, 1975).
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Figure 6.
A montage of four sections from postnatal day 6 (R44a) showing a filopodium (f) emerging
from a dendrite (D), and terminating in a bulbous
head (h) that has two synapses from different
axons. The filopodium is similar in shape to an atypical spine (see
Materials and Methods), but its unusual length (~3 µm) is more
characteristic of a filopodium. In addition, the "neck" has a
variable diameter, a dark cytoplasm suggesting a dense accumulation of
actin, and exhibits a surface specialization at one point along its
length where it contacts another dendritic process
(arrow). Scale bar, 1 µm.
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A few microtubule-free, actin-filled processes exhibited a complex,
noncylindrical shape. These were often sheet-like or of large diameter
extending through large volumes with subprocesses and holes, consistent
with the ultrastructural appearance of growth cones and lamellipodia
(Pappas et al., 1975; Pfenninger and Rees, 1976). Structures with some
of these characteristics protruded from dendrite shafts, giving the
appearance of an emerging dendritic branch (Fig.
7). The difference between these apparent
growth structures and the thinner filopodia, taken in conjunction with observations in cultured cells (cf. Dailey and Smith, 1996), suggests that most dendritic filopodia are not nascent branches of the dendritic
arborization.
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Figure 7.
A montage of two sections from P1 (R55) showing a
vesicle-filled process (P) emerging from a bend
in a dendrite (D), all of which is outlined in
white. This process shares more characteristics with
growth processes than most dendritic filopodia (compare with Figs. 1
and 2), suggesting that it might represent a budding branch of the
dendrite. Note the mitochondrian (arrow) partly invades
the base of the process. Mitochondria were never observed in filopodia.
Scale bar, 1 µm.
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Axonal filopodia were sometimes similar in appearance to dendritic
filopodia (Fig. 1) but were more often broader and shorter extensions
from the axon (Figs. 5, 8). These axonal
filopodia were observed in contact with dendritic filopodia. Dendritic
filopodia received asymmetric synaptic contacts and often displayed
nonsynaptic surface specializations where they contacted other elements
of the neuropil, especially at their tips. Axonal filopodia, on the other hand, contained synaptic vesicles and sometimes appeared to
participate in the formation of nascent synapses, particularly at
points of contact with dendritic filopodia (Figs. 1, 5, 8).
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Figure 8.
Top. Interaction between axonal and
dendritic filopodia at postnatal day 4 (R48a). A, An axon
has a broad protrusion with a grainy cytoplasm indicative of actin.
This actin-filled region is devoid of microtubules and ends in a narrow
process (af) identical in appearance to dendritic
filopodia except for the presence of synaptic vesicles (black
arrows). There are two synapses at the base of this axonal
filopodium, one (blue arrow) with a dendrite shaft and
another (red arrow) with the tip of a dendritic
filopodium (df). B, Three-dimensional
reconstruction of segments of the same axon and dendrite with the
interacting filopodia that are shown in A. Scale bars, 1 µm.
Figure 9.
Bottom. A cluster of
filopodia emerging from a varicosity in a beaded dendrite at P6 (R43a).
Reconstruction of a segment of the dendrite shows the location of six
synapses (blue). The filopodia (copper) receive
synaptic contacts near the tips (1, 6) and
at the base (3, 4, 5). An additional
shaft synapse (2) can be seen on the surface of the
dendrite. Two other shaft synapses and one spine synapse (data not
shown) also occurred on this dendritic segment. Electron micrographs
(insets) show the details of each synapse. Scale bars in
insets, 0.5 µm; 3D scale bar, 1 µm.
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Synapses were found at the base and along the length of dendritic
filopodia (Fig. 9). Often a single
filopodium exhibited multiple synapses along its length, up to six were
observed. Dendritic filopodia without synapses were also observed,
particularly during the first postnatal week, but these were not
quantified.
To assess the overall distribution of synapses in area CA1 during
development, volumes of tissue containing 50-120 synapses were
analyzed (Materials and Methods). In total, more than 6500 µm3 were systematically analyzed revealing a total of
1483 synapses (Table 1). Approximately 4.5% of these synapses were
unidentified, the rest were classified according to synapse type and
location. Synapses on growth cones/lamellipodia and symmetric synapses
comprised only 2.8 and 1.3%, respectively, of synaptic contacts across
all ages and so are not shown in the figures. During the first
postnatal week, 21 ± 6.0% of 1062 identified synaptic contacts
in area CA1 occurred on filopodia, whereas 75% of the synapses
occurred on shafts, stubbies, or spines (Fig.
10).
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Figure 10.
Distribution of synapse locations in CA1 during
the first postnatal week. Bars represent the mean percentages of
synapses in each class. Light shading indicates mean
percentages for atypical spines and stubbies (see Materials and Methods
for details). Error bars show the minimum and maximum values for
combined means measured in 12 series from seven animals aged P1, P4,
and P6.
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Synaptic filopodia identified in the volume analysis that could be
traced in entirety from origin to distal tip were further analyzed to
determine the distribution of synapses along the filopodia (Fig.
11). There were 162 completely
traceable dendritic filopodia across all ages. These 162 filopodia
received a total of 255 synaptic contacts. Most filopodia had only one
synapse, but 41% had multiple synapses from different presynaptic
partners. Unlike spines, which have synapses preferentially located on
the spine head, filopodia can have synapses anywhere with equal
probability. Of the 162 complete filopodia, 65 had at least one synapse
at the tip, 74 had at least one synapse at the base, and 76 had at
least one synapse in an intermediate location between the tip and base. Of the 255 filopodial synapses, 80 were at the tip, 83 were at the
base, and 92 were found in an intermediate location. There was a trend
for synapses to be located more on the tips of filopodia at P12 (Fig.
11).
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Figure 11.
The location of synapses on 162 complete
filopodia as a percent of the total number (n) of
synapses on these filopodia at each age. There were more tip locations
at P12 (F(3,12) = 6.21;
p < 0.009), but apparent trends in mid and base
locations were not statistically significant
(p < 0.07 and p < 0.26, respectively).
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Synapses on filopodia occurred at enlargements or swellings in
filopodia. Although synaptic swellings in filopodia were occasionally bulbous like spine heads (Fig. 6), more often they were fusiform in
shape (Fig. 9). Often multiple synapses were observed on a single
filopodial enlargement. Among the 80 tip synapses on the 162 complete
filopodia, 81% occurred on these enlargements. Similarly, 77% of the
mid synapses occurred on identified enlargements in filopodia. In
total, only 21% of tip and mid synapses were not located on
enlargements.
Filopodia usually occurred as single processes, but sometimes they were
branched or several emerged in a clump (Fig. 9). Approximately 9.3% of
the filopodia identified through the synapse analysis had a branched
morphology. Filopodia originated from dendrites of all sizes. Of those
origins that could be clearly classified, 23% were large, apical-like
dendrites with well organized microtubules, whereas 34% were thin
dendrites with well organized microtubules. The remaining filopodia
(43%) originated from varicose regions of dendrites (Fig. 9).
The distribution of synapse locations in CA1 changed with developmental
age (Fig. 12). Synapses were found
mostly on dendritic shafts during the first postnatal week. Asymmetric
shaft synapses were also frequent at P12. There was a statistically
significant increase in the frequency of spine synapses with age
(F(3,12) = 16.30; p < 0.0002).
At P1 4.9 ± 4.3% of synapses were on dendritic spine-like
protrusions. These P1 spines all had characteristics that were not
typically found in adult spines, suggesting that they might be
retracting filopodia rather than true spines. By P12 the proportion of
spine synapses had risen to 37 ± 14% of all synapses.
This increase in spine synapses was accompanied by a decrease
in filopodial (F(3,12) = 4.82; p < 0.02) and shaft (F(3,12) = 3.97;
p < 0.036) synapses. By P12, filopodial synapses were
only 7.2 ± 4.7% of all synapses.
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Figure 12.
Distribution of synapse locations by age as
revealed by the mean percentage of synapses at each location.
Light regions depict percentages with atypical
characteristics, (see Materials and Methods for details). Error bars
indicate SDs.
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DISCUSSION |
Recent studies have demonstrated dynamic dendritic filopodia in
the early development of area CA1 in vitro (Dailey and
Smith, 1996; Ziv and Smith, 1996; Collin et al., 1997). Their movements and interactions with other elements in the culture suggest that they
may be involved in locating presynaptic targets and consolidating them
into stable synapses. As a consequence, Dailey and Smith (1996)
proposed that dendritic filopodia are involved in the establishment of
all axodendritic synapses in hippocampal area CA1. However, evidence
for large numbers of synapses on filopodia has been lacking (Markham
and Fifkova, 1986; Harris et al., 1992; Papa et al., 1995). One reason
may have been the limitations of single-section analyses in
differentiating filopodial synapses from stubby or spine head synapses
(Schwartz et al., 1968; Steward and Falk, 1991; compare Fig. 3). The
serial section analyses of the present work provide evidence that
enough synaptic contacts occur on dendritic filopodia in
vivo to support the Dailey and Smith (1996) proposal.
In fact, there appear to be far more filopodial synapses than are
consolidated into synapses of other types. From Table 1 it can be seen
that there were, on average, 3.1 filopodial synapses/100 µm3 at P4 and 6.2/100 µm3 at
P6. Ziv and Smith (1996) report the average lifetime of a filopodium is
about 10 min in vitro. A more conservative assumption would
be that the entire population of filopodia turns over once an hour,
giving an average of 4.65 new filopodial synapses/100 µm3/hr. In 48 hr, 223/100 µm3
new synapses should have been created by a filopodial synaptogenic mechanism. Only 14.6/100 µm3 nonfilopodial
synapses were created between P4 and P6 (Table 1). Thus, probably <7%
of filopodial synapses were retained during this period.
A long-standing hypothesis for the formation of spine synapses in
hippocampus is that spines arise from shaft synapses by a process of
outgrowth (Cotman et al., 1973; Pokorny and Yamamoto, 1981). This idea
has been supported by the repeated finding that shaft synapses
predominate early in the development of hippocampus (Cotman et al.,
1973; Pokorny and Yamamoto, 1981; Schwartzkroin et al., 1982; Steward
and Falk, 1991; Harris et al., 1992; Boyer et al., 1998) and in other
brain regions as well (Juraska and Fifkova, 1979; Miller and Peters,
1981; Mates and Lund, 1983; Landis, 1987). The results of the present
study also show that most synapses occur on dendritic shafts during the
first two postnatal weeks. The density of shaft synapses does not
decrease until the later stages of development (P15 to adult), during
the transition to the full complement of spines (Harris et al., 1992).
This, along with the appearance of synapses on stubby protrusions
intermediate between shafts and spines, suggests that spines arise from
shaft synapses by a process of outgrowth. Dynamic outgrowth of
mature-looking spines from dendritic shafts has also been observed in
culture (Dailey and Smith, 1996).
If filopodia give rise to all synapses as proposed by Dailey and Smith
(1996), then filopodia frequently give rise to shaft synapses, because
these predominate during the first postnatal week. To compare the
likelihood of shaft and stubby synapse creation to spine synapse
creation, consider the data of Table 1. There were 4.9 spine
synapses/100 µm3 created between P4 and P6,
whereas the combined increase in shaft and stubby synapses was 8.0/100
µm3 during this same period. Thus, less than half
of new synapses are of the spine type. Spine synapses created directly
from filopodia may be an even smaller portion of new synapses, however,
if we consider the possibility that some spines may be forming from shaft synapse outgrowth during this period.
A significant proportion of spines identified in the present material
exhibited multiple synaptic contacts and other irregularities distinguishing them from adult spines in area CA1. These atypical spines might be related to the "protospines" of Dailey and Smith (1996), which were observed to be persistent but still showed structural changes. Atypical spines might also be filopodia in the
process of retracting. In either case they will undergo further development in which competing synapses are eliminated, but it is not
clear whether they ultimately remain spines or whether they experience
an intermediate shaft stage. If atypical spines are not true spines,
then they should be excluded from the estimate of new spine synapses.
This yields only 1.8/100 µm3 new spine synapses
from P4 to P6, versus 6.9/100 µm3 for shafts
alone. Thus, far fewer stable spine synapses than shaft synapses appear
to be created from filopodia during the early stages of
synaptogenesis.
It is well established that spiny neurons exhibit dendritic filopodia
during developmental synaptogenesis. This has been reported for visual
cortex (Lund et al., 1977; Miller and Peters, 1981; Markham and
Fifkova, 1986), cerebellar cortex (Berry et al., 1972), red nucleus
(Saito et al., 1997), and many other areas (Morest, 1969b). But even
neurons that are nonspiny when mature exhibit dendritic filopodia
during synaptogenesis (Lund et al., 1977; Difiglia et al., 1980;
Dvergsten et al., 1986; Ulfhake and Cullheim, 1988; Wong et al., 1992;
Linke et al., 1994). This finding suggests that the purpose of
dendritic filopodia is not to form spines, but rather to facilitate the
establishment of shaft synapses. This idea is supported by our
observations and those of others (Ulfhake and Cullheim, 1988) that
synapses are frequently found around the bases of filopodia.
Taken together, these observations suggest that dendritic filopodia
participate in the recruitment of shaft synapses much more frequently
than in the formation of mature spines. How could filopodia generate
shaft synapses? One possibility is that filopodia represent a
specialized receptive surface for the formation of new synapses.
Synapses can form on this surface at points of contact with axons, but
only contacts near the base of filopodia are stabilized into shaft
synapses. Synapses at the tip and along the length of filopodia are not
retained (Fig. 13A).
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Figure 13.
Possible mechanisms by which filopodia might
induce shaft synapses. A, Synapses form on the receptive
surface of filopodia, but only those near the base of filopodia are
stabilized into shaft synapses. B, Filopodia retract,
pulling the presynaptic partner to the dendrite. C,
Dendritic filopodia guide axonal filopodia to the dendrite where
synapses are stabilized by subsequent maturation of the axonal
filopodium into an axon branch. D, Dendritic filopodia
act as conduits along which synapses move to the dendrite shaft.
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A second possibility for the production of shaft synapses by filopodia
is that filopodia make a nascent synapse at their tip, then retract to
the dendritic shaft, pulling the presynaptic axon along with them (Fig.
13B). Several presynaptic axons could be retrieved to the
shaft by the filopodium repeatedly extending and retracting. Repeated
extensions and retractions of a single filopodium have been observed
in vitro (Dailey and Smith, 1996; Ziv and Smith, 1996). A
consequence of this mechanism is that some axons will be required to
translate several micrometers through the neuropil. Competing
interactions on one axon by filopodia from different dendrites would
presumably cause the axon to be bent into complex undulations during
early development. Later, as dendritic spines extend, the undulations
could "relax" into straighter axons as seen in adults (Shepherd and
Harris, 1998).
A third mechanism is suggested by the analysis of growth cone-target
cell interactions in culture (Cooper and Smith, 1992; Davenport et al.,
1996). These experiments show that filopodia of axonal growth cones,
which contact target cell filopodia, adhere to them and grow along them
to reach the cell surface. Our results similarly show axonal filopodia
contacting dendritic filopodia and in some cases extending along their
length (Fig. 8). So shaft synapses might arise from direct
axon-dendrite contacts produced as a result of the axonal branching
and growth along dendritic filopodia (Fig. 13C). This idea
is supported by studies showing that axon terminal arborizations can
exhibit dynamic filopodia (O'Rourke et al., 1994), but not every
synapse on a dendritic filopodium has an axonal filopodium as the
presynaptic element. Perhaps, either the axonal filopodium or the
dendritic filopodium could elaborate into a new lateral branch if
conditions support the stabilization of the initial synaptic contact
(Morest, 1969a). Dailey and Smith (1996) noted that some dendritic
filopodia transform into growth cones and nascent dendrite branches. In
addition, Kossel et al. (1997) have shown that increased dendritic
arborization is induced by the presence of synaptic axons in
culture.
The distribution of synapses all along a filopodium suggests that
filopodia might act as nonretracting conduits for the transference of
synaptic contacts to the dendrite shaft. The movement of actin filaments within the filopodium, which is responsible for the extension
and retraction of these processes (Fisher et al., 1988; Smith, 1988;
Sheetz et al., 1992), can also serve to move an attached membrane
component along the filopodium (Smith, 1994). Thus, nascent synapses
forming near the filopodium tip could be transported down the
filopodium to eventually mature into shaft synapses (Fig. 13D). This mechanism also requires axons to translocate as
the synapse is pulled to the dendrite.
In conclusion, the results show that dendritic filopodia are involved
in developmental synaptogenesis in area CA1, making nascent synaptic
contacts with axonal elements. Although some filopodia appear to
retract into atypical or "protospines", filopodia result in mostly
shaft synapses by an unknown mechanism (Fig. 14). While it is possible that these
early shaft synapses are not the source of spine synapses (Landis,
1987), our current knowledge favors a model in which these shaft
synapses are subsequently converted to dendritic spines.
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Figure 14.
Genesis of most excitatory synapses may involve
four stages. 1, Initial induction of a synapse by a
filopodium. In early stages of development, atypical or
"protospines" are apparent, but their ultimate fate is unclear.
2, Retraction of the filopodia and stabilization of the
synapse on the dendrite shaft. 3, Emergence of a stubby
protrusion beneath the synapse. 4, Outgrowth of
protrusion into a mature spine.
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FOOTNOTES |
Received June 8, 1998; revised Aug. 3, 1998; accepted Aug. 17, 1998.
This work was supported by National Institutes of Health Grants NS21184
and NS33574, Human Brain Project (HBP) Grant R01 MH/DA 57351 (K.M.H.)
and Mental Retardation Research Center Grant P30-HD18655 (Dr.
Joseph Volpe, PI). The HBP research is funded jointly by National
Institute of Mental Health, National Institute on Drug Abuse, and
NASA.
Correspondence should be addressed to Dr. Kristen M. Harris, Division
of Neuroscience, Enders 260, Children's Hospital, 300 Longwood Avenue,
Boston, MA 02115.
| |
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Top
Abstract
Introduction
