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Fig. 8. Model of IPL formation and sublamination in wild-type and lak
mutants. (A-C) IPL formation in wild-type retina. At 2 dpf (A), ACs (green,
blue) start to grow neurites. GCs and/or their dendrites (red), which have
already grown out to form a proto-IPL, provide a signal that either orients
ACs and their processes towards the nascent IPL (model 1, left), or else
stabilizes IPL-oriented processes (model 2, right). At 2.5 dpf (B), ON (blue)
and OFF (green) ACs have ramified their dendrites within the IPL (gray shaded
area), but separate sublayers are not yet distinguishable. ON and OFF IPL
domains (light blue and green shading) may already be distinct, but so close
together within the developing IPL that they look like a single diffuse layer
(model 1, represented by the two left-hand cells in B). Alternatively, ON and
OFF strata may not be separate yet at this stage, in which case ACs would
project diffusely throughout the extent of the IPL (model 2; right-hand cells
of B). By 5 dpf (C), distinct ON and OFF sublayers are clearly evident. GCs
are shown in pink; their dendrites are not fully depicted in B or C. (D-F) IPL
formation in the absence of GCs. In lak mutants at 2 dpf (D), ACs
lack the orienting signal from GCs and grow neurites in random directions, or
towards each other. Their cell bodies are often ectopically positioned
adjacent to the ILM, which causes the early IPL to form there as well. By 2.5
dpf (E), the tendency of AC neurites to grow towards each other has led to
formation of an IPL. Because of the initial disorganization of AC somata and
neurites, however, the nascent IPL is uneven. AC somata continue to accumulate
between the IPL and the ILM, forming a layer of `misplaced' ACs. By 5 dpf (F),
much of the unevenness has dissipated and IPL sublayers have formed,
indicating that there are cues available to ACs that allow correction of early
errors. One such mechanism may be homotypic attraction between ACs. However,
these cues are not sufficient to allow correction of every error, leading to
local perturbations of IPL sublamination (arrow).
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promoter. The sequence of the highly conserved DF4 element
is shown. (C) Cross-sectional view of GFP+ ACs and their neurites
in the IPL of line 220 7 dpf retina. GFP fluorescence is superimposed on a
Nomarski image of a section through the eye. Two bright sublaminae are evident
in the IPL (see higher magnification image, inset). (D) Digital rotation of a
confocal image stack, providing an orthogonal view of a region of inner retina
of a line 220 retinal wholemount at 9 dpf. S1 is an optical slice of this
field of view showing sparsely distributed GFP+ neurites close to
the AC cell bodies. S2-5 are image planes within the boxed region in S1. The
two major GFP+ sublaminae are S2 and S4; note also sparse
innervation of sublaminae S1 and S5 by GFP+ neurites. (E)
Cross-sectional view of the eye of an 7 dpf line 243 fish. (F) Morphology of
individual GFP+ cells in line 243. Maximum projection of a confocal
image stack (47 µm total) through the inner retina of a retinal whole mount
at 35 dpf. (G) Arbors of a few isolated ACs (1, 2 in F) at an IPL depth closer
to the GCL. (H) Digital rotation of the complete image stack providing
orthogonal views of cells 1 and 2. Cell 1 has a diffuse asymmetric arbor
spanning the thickness of the IPL. By contrast, cell 2 has a radially
symmetric arbor stratifying in the ON sublamina. (I-K) Cross-sections of adult
line 220 retina immunolabeled for ChAT. The two bright GFP+ laminae
in line 220 coincide with the two major ChAT-immunopositive bands in
sublaminae S2 and S4. Some, but not all, GFP+ cells are also
immunoreactive for ChAT (arrows). GCL, ganglion cell layer; INL, inner nuclear
layer; IPL, inner plexiform layer; NV, optic nerve; dpf, days
post-fertilization; L, lens.
