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The Journal of Neuroscience, November 1, 2001, 21(21):8616-8623
Microcircuits for Night Vision in Mouse Retina
Yoshihiko
Tsukamoto1,
Katsuko
Morigiwa2,
Mika
Ueda1, and
Peter
Sterling3
1 Department of Biology, Hyogo College of Medicine,
Nishinomiya, Hyogo 663-8501, Japan, 2 Department of
Physiology and Biosignalling, Graduate School of Medicine, Osaka
University, Suita, Osaka 565-0871, Japan, and 3 Department
of Neuroscience, University of Pennsylvania, Philadelphia, Pennsylvania
19104
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ABSTRACT |
Because the mouse retina has become an important model system, we
have begun to identify its specific neuron types and their synaptic
connections. Here, based on electron micrographs of serial sections, we
report that the wild-type mouse retina expresses the standard rod
pathways known in other mammals: (1) rod  cone (via gap junctions)
to inject rod signals into the cone bipolar circuit; and (2) rod rod bipolar AII amacrine cone bipolar ganglion cell. The
mouse also expresses another rod circuit: a bipolar cell with cone
input also receives rod input at symmetrical contacts that express
ionotropic glutamate receptors (Hack et al., 1999 , 2001). We show that
this rod-cone bipolar cell sends an axon to the outer (OFF)
strata of the inner plexiform layer to form ribbon synapses with
ganglion and amacrine cells. This rod-cone bipolar cell receives
direct contacts from only 20% of all rod terminals. However, we also
found that rod terminals form gap junctions with each other and thus
establish partial syncytia that could pool rod signals for direct
chemical transmission to the OFF bipolar cell. This third rod pathway
probably explains the rod responses that persist in OFF ganglion cells
after the well known rod pathways are blocked (Soucy et al., 1998).
Key words:
mouse retina; microcircuitry; rod circuits; bipolar
cells; gap junctions; electron microscopy
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INTRODUCTION |
Until recently, the anatomical
connections of mammalian photoreceptors seemed well understood. Cones
and rods were known to form chemical synapses on separate classes of
bipolar cell (for review, see Vaney et al., 1991; Sterling, 1998;
Boycott and Wässle, 1999; Sharpe and Stockman, 1999). Cone
bipolar cells synapse directly on ganglion cells and serve high-light
levels (daylight), whereas rod bipolar cells connect to ganglion cells
only indirectly via an interneuron and serve low-light levels
(starlight). Rods were also known to form electrical synapses with
cones and thus to obtain indirect access to the cone bipolar circuits
under medium-light levels (twilight). These parallel circuits,
identified and quantified in cat (Kolb and Famiglietti, 1974; Kolb,
1977; Sterling et al., 1988), rabbit (Strettoi et al., 1990; Young and
Vaney, 1991), and primate (Mills and Massey, 1995), have been
considered fundamental to the mammalian design and different from the
design in fish in which rods and cones form chemical synapses on the
same bipolar cells (Stell et al., 1977; Ishida et al., 1980).
However, recordings from mouse ganglion cells now suggest a direct
pathway from rods to cone bipolar cells (Soucy et al., 1998). In a
mouse retina genetically modified to be "coneless," a fast rod
signal was observed in OFF ganglion cells. Clearly, the signal could
not reach cone bipolar cells via the known pathway (rod-cone
coupling), so the most likely pathway in this retina would be for the
rod to synapse directly onto dendrites of an OFF cone bipolar cell. The
normal mouse showed responses with nearly identical kinetics,
suggesting that this pathway might be a basic feature of mouse retina.
Subsequently, contacts were identified from rods to processes that
express ionotropic glutamate receptors (iGluRs) (Hack et al.,
1999, 2001) and thus are strong candidates for the second-order neurons
of this pathway.
To search for this predicted pathway, as well as other basic circuits,
we prepared electron micrographs of serial sections through retinas of
wild-type mice. Reconstructing from this material, we identified the
standard mammalian circuits for night vision but also a type of OFF
cone bipolar cell that collects from rods as well as cones. This
confirms the prediction of a direct pathway from rods to OFF bipolar
cells. Only 20% of rods directly contact this bipolar cell, but
signals from the remaining rods might reach it via rod-rod gap
junctions observed here and previously unknown in mammals.
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MATERIALS AND METHODS |
Animals and tissue preparation. Retinas were obtained
from two mice: mouse 1, C57BL/6J, 9 weeks old, female, 20 gm (SLC,
Shizuoka, Japan); mouse 2, hybrid of 129/SvJ × C57BL/6J,
94 weeks old, female, 38 gm (129/SvJ; The Jackson Laboratory, Bar
Harbor, ME). All experiments were conducted in compliance with
the institutional and NIH guidelines for animal care and treatment.
After deep anesthesia with sodium pentobarbital (45 mg/kg, i.p.), mouse
1 was perfused with a mixture of 2% paraformaldehyde, 2.5%
glutaraldehyde, and 1% acrolein in phosphate buffer (0.1 M), pH 7.4. Excised pieces of the posterior retina were immersed in the same fixative with 1% tannic acid replacing acrolein, microwave irradiated for 10 min, and left at room
temperature for 3 hr. Tissue was post-fixed with 1% osmium tetroxide
for 2 hr. Mouse 2 was perfused with 4% paraformaldehyde in cacodylate
buffer (0.1 M), pH7.4. Pieces of the posterior
retina were immersed in 2% paraformaldehyde, 3% glutaraldehyde, and 2 mM calcium chloride in cacodylate. After
microwave irradiation, tissue remained in the same fixative at 4°C
overnight and was then post-fixed with 1% osmium tetroxide and 0.05%
potassium ferricyanide for 1 hr at room temperature. The tannic
acid-treated tissue (mouse 1) was best for viewing membrane
densification, and the ferricyanide-treated tissue (mouse 2) was best
for viewing the trilamellar unit membrane structures. Tissue was
stained en bloc in 3% uranyl acetate in 80% methanol, dehydrated with
ethanol, and embedded in araldite.
Serial reconstruction procedures. A series of 366 radial
sections were cut from mouse 1 retina, and a series of 157 tangential sections were cut through the entire outer plexiform layer of mouse 2 retina, at the thickness of 90 nm. Sections were mounted on
Formvar-covered slot grids, stained with uranyl acetate and lead
citrate, and photographed at 3000× (mouse 1 series) and 4000× (mouse
2 series) under a JEM1200EX electron microscope (JEOL, Tokyo,
Japan). Certain synaptic contacts were rephotographed at 40,000× with various tilts. Three-dimensional images were
reconstructed with TRI graphic software (Ratoc, Tokyo, Japan)
for Windows NT.
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RESULTS |
Mouse retina expresses two standard rod pathways known in
other mammals
We first examined the gap junctions between photoreceptor
terminals. Analyzing a series of tangential sections covering a small
area of outer retina (35 × 45 µm), we distinguished two types
of terminal. The rod terminal was small and contained a single ribbon
synapse. The cone terminal was larger and contained many ribbon
synapses (10 ± 1.6 synapses; mean ± SD; n = 20). We noted that each rod terminal always had gap junctions (Fig.
1A) with two processes
ascending from cone terminals. At the base of a rod terminal, these gap
junctions were usually opposite to each other across an opening for
invaginating processes. These ascending processes mostly came from the
same cone but occasionally from different adjacent cones. Cone
terminals also protruded many tiny processes horizontally that formed
cone-cone gap junctions (Fig. 1B). Thus, as in other
mammals (DeVries and Baylor, 1995), cones couple to each other and
(crucially for the "twilight" circuit) rods couple to cones.
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Figure 1.
Mouse retina contains electrical and chemical
synapses that serve two rod circuits known in other mammalian retinas.
A, Rod-cone gap junction (arrows).
B, Cone-cone gap junction (arrows).
C, Two rod bipolar dendrites (B)
invaginating a rod synaptic terminal and extending close to the
synaptic ribbon (arrowhead) that is flanked by
horizontal cell processes (H).
D, Ribbon synapse (arrowhead) from rod
bipolar axon to AII amacrine cell. E, Conventional
chemical synapse (arrow) from the AII amacrine cell to
an OFF cone bipolar axon terminal with ribbon output
(arrowhead) to ganglion and amacrine cells.
F, Large gap junction (arrows) between
AII amacrine cell and ON cone bipolar axon terminal, shown at higher
magnification in inset. Also, ribbon output
(arrowhead) to ganglion and amacrine cells.
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Next, we used a series of vertical sections spanning a 90 × 30 µm patch of both plexiform layers to identify the synapses along the
standard pathways. These synapses showed the same ultrastructure observed in other mammals: rod terminals were invaginated by rod bipolar dendrites (Fig. 1C), and the rod bipolar axon
expressed ribbon synapses directed at the AII amacrine cell (Fig.
1D). The AII cell directed conventional chemical
synapses at the axon terminals of OFF cone bipolar cells (Fig.
1E) (McGuire et al., 1984; Pourcho and Owczarzak,
1991; Sassoè-Pognetto et al., 1994) and formed large gap
junctions with axon terminals of ON cone bipolar cells (Fig.
1F). The axon terminals of OFF and ON bipolar cells
formed many ribbon synapses onto amacrine processes and ganglion cell dendrites (Fig. 1E,F) (see
Fig. 3).
We also surveyed the basic patterns of convergence and divergence along
the rod and cone bipolar pathways (Fig.
2) by tracing the cells and synaptic
connections through the available serial sections (Fig. 2). Many rods
(22) converged on the rod bipolar cell, whereas few cones (four to
seven) converged on the cone bipolar cells. The rod bipolar terminal
expressed a modest number of ribbon synapses (43 ± 1; mean ± SD; n = 3) by which it diverged to multiple AII
cells. The AII cell, collecting from several rod bipolar cells,
expressed many electrical junctions (16) by which it diverged to
several ON bipolar terminals. The AII cell also expressed many
conventional synapses (19) by which it diverged to several OFF bipolar
terminals of the same type. Additional detailed reconstructions will be
needed to establish the definitive numbers of synapses and
convergence-divergence; nevertheless, these numbers are comparable
with those reported in cat (Sterling et al., 1988), rabbit (Strettoi et
al., 1990), and monkey (Wässle et al., 1995).
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Figure 2.
Mouse retina expresses two rod circuits known in
other mammals. Reconstructions from electron micrographs of a single
series approximately quantify the connections; each rod diverges to two
rod bipolar cells, and 22 rods converge on one rod bipolar cell. The
rod bipolar cell provides 43 ribbon synapses to AII amacrine cells. The
AII forms 16 large gap junctions with ON cone bipolar terminals and 19 conventional synapses with the OFF cone bipolar terminals. The ON
bipolar terminal receives 11 of these gap junctions, and the OFF
bipolar terminal receives 31 conventional synapses.
Numbers enclosed by a circle,
square, and triangle represent the
numbers of input or output synapses between a particular pair of
adjacent cells. Total output synapses at the ON and OFF cone bipolar
terminals are shown in Figure 3.
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Two types of OFF bipolar cell
We reconstructed six bipolar cells with axon terminals in the OFF
strata of the inner plexiform layer (IPL) (Fig.
3). Three cells resembled each other:
dendritic field spanning ~10-18 µm, basal contacts from cones
(5 ± 1.7; mean ± SD), stout axon (~1 µm thick, measured
5 µm below the soma), and a terminal arbor spanning 0-35% of the
IPL. This elaborate arbor produced an enormous number of ribbon
synapses (135 ± 3), each presynaptic to a pair of processes
(dyad). The axon terminals of all three cells received chemical
synapses from AII amacrine cells. These bipolar cells were separated by
10-15 µm. The clustering by multiple parameters suggests that these
cells belong to a specific type (Cohen and Sterling, 1990), here
designated B1.
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Figure 3.
Two types of OFF cone bipolar cell and one ON cell
identified by reconstruction. Type B1 is distinguished by a thick axon
(1.0 µm) and a large number of ribbon outputs that distribute
throughout the OFF stratum. B1 receives direct contacts only from
cones. Type B2 is distinguished by a thin axon (0.6 µm) and modest
number of ribbon outputs that distribute throughout the OFF stratum of
the IPL. B2 receives direct contacts from both rods and cones.
Type Bon is distinguished by a thin axon (0.75 µm) that
provides a modest number of ribbon outputs in the ON stratum. It
receives direct input only from cones. INL, Inner
nuclear layer.
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Three other bipolar neurons also resembled each other: dendritic field
spanning ~8-14 µm, standard basal contacts from approximately two
cones, plus unusual, symmetrical contacts from approximately five rods
(see below). The axon was thin (~0.6 µm), with a terminal arbor
spanning 0-40% of the IPL. The number of ribbon synapses was quite
modest (44 ± 3), including several in the axon stalk. Again, the
clustering by multiple parameters suggests a specific type, here called
B2. The dendritic arbors of two neighboring B2 cells were reconstructed
from tangential sections (see Fig. 8). Averaging all five B2 cells
(three in vertical sections and two in tangential sections), their
dendrites received 2.2 ± 0.4 cones and 4.8 ± 0.8 rods. B2
bipolar cells were separated by ~4-10 µm.
We fully reconstructed one ON bipolar cell and found its arbor to span
levels 45-73% of the inner plexiform layer (Fig. 3). Because the
convention of numbering bipolar cell types proceeds from outer to inner
(Boycott and Wässle, 1991) and it is unclear how many types will
be interposed between B2 and this ON cell, we designate it temporarily
as Bon. It resembles the rat type 7 cone bipolar
cell (Euler and Wässle, 1995).
Type B1 bipolar cell (but not type B2) collects synapses from the
AII amacrine cell
All of the axons of three B1 cells shown in Figure 3
arborized among the lobular appendages of AII cells and received
conventional, chemical synapses from the AII cells (Figs.
1E, 2). A particular B1 terminal received five such
contacts from one AII cell and a total of 31 AII contacts (Fig. 2).
Thus, the B1 cell is a key link for the standard rod bipolar pathway
into the OFF system. The B2 axons also arborized among the AII lobular
appendages. However, although we found five sites of membrane
apposition (0.1-1 µm long) between two AII and two B2 cells, there
were neither membrane specializations nor vesicle accumulations. Thus,
the AII seems not to synapse on the B2 axon terminal. Whether there are
more types of OFF cells that might connect with AII remains to be
determined
Mouse retina expresses a third rod pathway
At the point at which a B2 dendrite contacted a cone terminal,
there was a typical "basal contact" (Boycott and Kolb, 1973): the
presynaptic membrane, devoid of docked vesicles, was indented by the
dendritic tip; both presynaptic and postsynaptic membranes were
densified; and the cleft had constant width (20 nm) and contained filamentous material (Fig.
4A,B).
However, at the point at which the B2 dendrite contacted a rod
terminal, the features were different: presynaptic membrane was not
indented, but the area was substantial (up to 0.5 × 1 µm), and
the membranes displayed no consistent densification and varied in both
cleft width and content of filamentous material (Fig.
4C,D). The rod-B2 contacts resembled those shown by Hack et al. (1999, 2001) to stain for iGluR subunits, and this led
us to investigate whether all rods participate in this pathway.
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Figure 4.
Ultrastructure of contacts between the B2 bipolar
dendrites and cone and rod terminals. A,
B, Cone terminals. Presynaptic and postsynaptic
membranes are smooth and arched with a cleft of constant width (~20
nm) that contains filamentous material. Presynaptic densification is
evident, but postsynaptic densification is less prominent.
C, D, Rod terminals. Glial wrappings
(g) make windows; contacts are large (0.5-1.0
µm2) and rugged (brackets), and the
clefts are variable in width (15-25 nm). Presynaptic and postsynaptic
membranes are hardly densified, and filamentous material is seen at
intermittent spots. A and C are from
radial sections stained with tannic acid; B and
D are from tangential sections stained with
ferricyanide.
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The densely packed photoreceptor outer segments are narrow, whereas
their somas and synaptic terminals are broad. Consequently, a monolayer
of outer segments requires the somas to stack up, forming ~10 tiers
(Fig. 5A). The underlying
synaptic terminals must also stack, forming three to four tiers (Fig.
5B). Cone terminals form the innermost synaptic tier with a
few intermingled rod terminals. The remaining rod terminals, each
containing one ribbon, form the two to three outer synaptic tiers.
Finally, the rod somas at the deepest somatic tier each contain a
ribbon and active zone at the base of the soma itself (Fig.
5B).
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Figure 5.
Photoreceptor somas and synaptic terminals stack
in multiple tiers. A, Densely packed somas (~96%
rods) form ~10 tiers. B, Rod somas of the innermost
somatic tier (* in A) form a ribbon synapse at the base
(just beneath the cell nucleus). Rods and cones of the outer somatic
tiers (as seen in A) form axons that snake between the
somas to reach the outer synaptic layer, in which the terminals
segregate. Cones plus some rods form the innermost synaptic tier; rod
terminals form the outer synaptic tiers. Nu, Nucleus;
rt, rod terminal; ct, cone
terminal.
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The B2 dendrites reach the innermost tier of synaptic terminals, i.e.,
where cones and rods intermingle. The dendrites mostly stop there and
barely penetrate the remaining tiers of rod terminals. Thus, B2
dendrites contact only a small fraction of all rods, ~20%. Wondering
how the other rods might convey signals to the B2 dendrites, we
searched carefully for evidence of rod-rod coupling, although it has
generally not been observed in mammals (Smith et al., 1986).
We did find rod-rod gap junctions. These were small and convex, like a
contact between two elbows (Fig. 6). They
were present at several loci: between rod soma and rod terminal,
between two rod terminals, and between rod terminal and passing rod
axons (Fig. 6A-C). Although these contacts were not
marked by adherent junctions [as between cones in primate retina
(Tsukamoto et al., 1992)], they were marked by localized fenestration
of the glial wrappings (g) shown particularly
well in Figure 6C. Furthermore, at the point at which two
rods were coupled, they commonly formed junctions at several different
sites.
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Figure 6.
Rods contact each other via small gap junctions.
A-C, Rod terminals contact the following: rod soma at
innermost somatic tier (A); another rod terminal
(B); and two descending rod axons wrapped by
glial processes (C, g). From tangential
sections stained with ferricyanide.
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We quantified the distribution of various photoreceptor gap junctions
in serial sections cut tangentially through a region containing three
cone terminals and 98 rod terminals (Fig.
7). Each cone formed one gap junction
directly with the neighboring cone, but most of the fine processes
emanating from the cone terminal connected to rods. Rod divergence to
cones was minimal; each rod contacted only slightly more than one cone
(1.2 ± 0.4), whereas convergence was considerable, ~32 ± 3 rods contacted each cone. The ratio of convergence-divergence was
27.8, closely matching the ratio of the rod-cone densities (334,000 mm 2 rods/12,700
mm2 cones was 26.3). This confirmed the
accuracy of our connectivity measurements (Freed et al., 1987).
Each rod contacted up to four neighboring rods (1.6 ± 0.9) (Fig.
7). Thus, a rod diverges more to rods than to cones.
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Figure 7.
Reconstructed pattern of gap junctions; rods form
local syncytia. Rod terminals (circles) that contact a
given cone (C1-C3) via gap junctions are displayed in
the same color as the cone (saturated for rod,
pale for cone). A rod that contacts two cones is
displayed in two colors. Cone-cone and rod-rod gap junctions are
indicated by the symbol for ohmic resistance. Note that
many rods converge on each cone, but each rod diverges very little.
Most rods also couple to other rods, forming local syncytia of up to 11 rods. Only 12 rods of 98 were apparently isolated.
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Three-dimensional reconstruction of synaptic input to B2
bipolar cells
We reconstructed the contacts for two adjacent B2 cells using the
same tangential sections as for the preceding gap junction analysis.
The primary dendrites of the two cells were separated by ~8 µm, and
their dendritic arbors extended horizontally, producing fields ~8
µm in diameter with some overlap (Fig.
8A). One cell (gray) collected chemical synaptic contacts from five
rods (R1-R5) and two cones (C1 and C2). The other cell
(blue) collected from six rods (R6-R11) and two cones (C1
and C2). Cones were shared, but the rods were not.
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Figure 8.
Three-dimensional reconstruction of synaptic input
to two neighboring rod-cone OFF bipolar cells. A,
Varicose dendrites of the bipolar cells are postsynaptic to five rods
and two cones (B2-1 in gray) and to six
rods and two cones (B2-2 in blue).
B, Left side of A, rotated to show
electrical pathways for rods that lack chemical synapses onto
dendrites. The dendrites (gray) receive chemical
contacts (red patches) from rod terminals
(R2-R4) in the innermost tier. One dendrite
ascends to receive an extensive chemical contact (vertical red
patch) along the lateral surface of R4. Other
rods (R12-R14) lack chemical synaptic contacts
but make gap junctions (red resistance) with R2-R4.
R13 is a rod soma (exceptionally protruding into the
synaptic layer) with input to the dendrites
(gray) via electrical junction with
R2. R15 does not connect to the
dendrites.
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At higher magnification, we discerned a specific laminar arrangement of
the connections (Fig. 8B). At the inner tier, the dendrites (gray) contacted the basal surfaces of rod
terminals (R2 and R3), plus the lateral and basal surfaces of R4.
Terminals R12 and R13 lacked chemical synapses with the dendrites but
coupled via gap junctions with R2. Similarly, terminal R14, located at the outermost tier, far from the dendrites, coupled to the R3 axon.
Thus, signals from rods of the outer tiers can reach rods of the inner
tiers and drive their chemical synapses with the B2 dendrites.
Combining information from Figures 7 and 8 suggests that 25 rods
converge onto one B2 cell (gray), and 21 rods
converge onto the other (blue).
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DISCUSSION |
It is important to learn what circuit features are conserved
between mouse and other mammals and how particular features change with
scale and/or environmental niche. The first quantitative studies of
mouse retina by light-electron microscopy showed that, despite the
mouse's nocturnal reputation, cones and cone bipolar cells are
quantitatively significant (Jeon et al., 1998). To this, Haverkamp and
Wässle (2000) have added, by immunostaining, a major survey of
retinal cell types and transmitter receptors. The present study
presents the first quantitative study of synaptic circuitry and offers
several initial insights.
Several circuits are conserved
The basic circuits for "starlight" [rod rod bipolar AII amacrine cone bipolar] and for "twilight" [rod cone
cone bipolar], previously identified in cat, rabbit, and primate
(Dacheux and Raviola, 1986; Smith et al., 1986; Strettoi et al., 1990; Vaney et al., 1991; Wässle et al., 1995) are clearly evident in
the mouse (Figs. 1, 2). Synaptic structures are also strongly conserved. Thus, the rod terminal in mouse has a single active zone and
a synaptic ribbon with the same semilunar form as the rod terminal in
cat and monkey (Rao-Mirotznik et al., 1995; Haverkamp et al., 2001).
Because the length of active zone and size of ribbon are also
conserved, they probably dock similar numbers of synaptic vesicles.
This makes sense because the function of the rod synapse is also
probably conserved: to transmit an irreducibly simple signal (binary),
the arrival of 0 or 1 photon (Rao-Mirotznik et al., 1994). Even the rod
bipolar terminal provides comparable numbers of active zones [mouse
~43 (Fig. 2) vs cat ~30; R. Rao-Mirotznik and P. Sterling,
unpublished observations].
The cone circuits are also conserved in several respects. Cone
terminals couple by gap junctions to neighboring cones and use both
multiple ribbon synapses and multiple types of OFF bipolar cell. These
features are thought to improve transmission of finely graded signals
that cover a wide temporal bandwidth (DeVries, 2000; Freed, 2000). The
numbers of ribbon synapses expressed by different types of mouse cone
bipolar cell are also comparable with cat. The range in mouse (41-138
ribbons) (Fig. 3) is similar to cat (47-105 ribbons) (Cohen and
Sterling, 1990).
Some circuits are unique
The mouse rod circuits exhibit certain features not found so far
in larger mammals (Fig. 9). The innermost
layer of rod terminals forms symmetrical contacts with dendrites of a
rod-cone OFF bipolar cell (B2). Although these contacts lack obvious
membrane specializations, they are probably not accidental: (1)
reconstructions show the B2 OFF dendrites extending for several
micrometers toward particular rod terminals (Fig. 3); (2) the
glial wrappings around a rod terminal form a "window" to permit
contact with the bipolar dendrite over a relatively wide area (Fig.
4C,D); and (3) membranes within this contact area
are neither consistently dense nor constant in width, but these
ultrastructural features are also seen at contacts between the rod and
the processes immunostained for GluR1 and GluR2 (Hack et al., 1999,
2001). These receptor sites on the B2 OFF dendrites are rather far from
the apex of the rod invagination, in which vesicles are released, but
the distance is comparable with that from cone release sites to basal
contacts (Calkins et al., 1996). We conclude that the rod B2
bipolar junction, like a cone basal synapse, responds to an
increase in glutamate concentration at light OFF by depolarizing the
bipolar cell.
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Figure 9.
Circuit for fast rod pathway to OFF ganglion cell.
Certain rods form symmetrical, iGluR-mediated synapses on dendrites of
rod-cone OFF bipolar cells. Other rods lack direct access to these
bipolar dendrites but couple electrically to the axons of rods that do
have direct access. Nu, Nucleus.
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The only rod terminals to directly contact the B2 bipolar are those
intermingled with the cone terminals in the innermost synaptic tier
(Figs. 8B, 9). These amount to ~20% of all rods in
the B2 dendritic field. However, each rod diverges via gap junction
(electrical synapse) to 1.6 other rods and thus forms local syncytia
(Fig. 7). By pooling their signals with the rods that do form chemical
synapses onto the B2 bipolar dendrites, most rods probably contribute
to this fast OFF pathway. Rod-rod gap junctions have not been reported
in larger mammals (monkey, cat, and rabbit), but they are present in
another small mammal, the guinea pig (P. Sterling, unpublished
observation). This design, in which rods couple to each other, is well
known in amphibians (Lasansky, 1972; Fain et al., 1976; Gold, 1979;
Attwell and Wilson, 1980).
One can never be completely certain that gap junctions observed by
electron microscopy are functional. However, the accumulated evidence
that ultrastructural identification, such as illustrated in Figures 1
and 6, corresponds to a physiological conductance is extremely
impressive. For example, the mammalian rod-cone gap junctions clearly
conduct, because the rod signal is recorded directly in the cone
(Nelson, 1977; Schneeweis and Schnapf, 1995). Furthermore, cone-cone
coupling in mammalian retina has now been shown by dual patch-clamp
recordings (S. H. DeVries, unpublished observations). In
this context, the hypothesis seems reasonable that rod-rod gap
junctions actually pool signals for conveyance via chemical synapses.
Why are OFF pathways favored in mouse?
Although much more remains to be learned about microcircuitry of
mouse retina, what we know so far suggests that the OFF system is more
highly developed than the ON system. Thus, the auxiliary rod pathway
described here uses OFF but not ON bipolar cells. Also, the B1 bipolar
axon, which carries the AII signal to OFF ganglion cells (Fig. 2), is
more robust and expresses twofold more ribbon synapses than its ON
counterpart (Fig. 3, compare B1,
Bon). With neither rod bipolar nor ON cone
bipolar signaling, mGluR6-deficient mice showed almost the same
performance for light-conditioned avoidance as the wild type (Masu et
al., 1995). These mice relied on information carried solely in OFF pathways.
An OFF system will be more useful than an ON system in which background
activity is strong enough that its suppression by an object darker than
the mean level would give a good signal. This implies that the
auxiliary rod pathway (rod B2 bipolar ) would serve light levels
in which there are many photoisomerizations (R*) per rod per
integration time. At such levels, coupling pools rod signals and
improves the signal-to-noise ratio, whereas with less than one
R* per rod per integration time, coupling would pool rod
noise and thus degrade the signal-to-noise ratio (Smith et al., 1986).
In fact, the fast rod pathway identified physiologically by Soucy et
al. (1998) in normal and coneless mouse, does operate over light levels
that generate ~5-500 R* per rod per integration time. Why
should this system be present in mouse and also possibly in guinea pig,
rat (Muller et al., 1993), and gray squirrel (West, 1978)? Small
rodents commonly spend considerable time in small, dark holes, looking
out. At dawn and dusk, objects moving through their visual scene might
tend to be faintly backlit and thus most efficiently detected by a
rod-driven OFF system.
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FOOTNOTES |
Received May 22, 2001; revised July 23, 2001; accepted Aug. 15, 2001.
This work was supported by Japan Society for the Promotion of Science
Grant-in-Aid 12878144 (Y.T.) and National Institutes of Health
Grant EY 00828 (P.S.). We thank Noga Vardi and Robert Smith for
suggestions to this manuscript and Sharron Fina for preparing it.
Correspondence should be addressed to Yoshihiko Tsukamoto, Department
of Biology, Hyogo College of Medicine, 1-1, Mukogawa, Nishimomiya,
Hyogo 663-8501, Japan. E-mail: ytsuka{at}hyo-med.ac.jp.
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ABSTRACT
INTRODUCTION
