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Volume 17, Number 20, Issue of October 15, 1997 pp. 7831-7838
Copyright ©1997 Society for NeuroscienceMosaics of Islet-1-Expressing Amacrine Cells Assembled by Short-Range Cellular Interactions
Lucia Galli-Resta1, Giovanni Resta2, Seong-Seng Tan3, and Benjamin E. Reese4 1 Istituto di Neurofisiologia del Consiglio Nazionale delle Ricerche, 56127 Pisa, Italy, 2 Istituto di Matematica Computazionale del Consiglio Nazionale delle Ricerche, 56127 Pisa, Italy, 3 Howard Florey Institute of Experimental Physiology and Medicine, University of Melbourne, Parkville Victoria 3052 Australia, and 4 Neuroscience Research Institute and Department of Psychology, University of California at Santa Barbara, Santa Barbara, California 93106-5060
ABSTRACT
The nervous system has a modular architecture with neurons of the same type commonly organized in nonrandom arrays or mosaics. Modularity is essential to parallel processing of sensory information and has provided a key element for brain evolution, but we still know very little of the way neuronal mosaics form during development. Here we have identified the immature elements of two retinal mosaics, the choline acetyltransferase (ChAT) amacrine cells, by their early expression of the homeodomain protein Islet-1, and we show that spatial ordering is an intrinsic property of the two Islet-1 mosaics, dynamically maintained while new elements are inserted into the mosaics. Migrating Islet-1 cells do not show this spatial ordering, indicating that they must move tangentially as they enter the mosaic, under the action of local mechanisms. Clonal territory analysis in X-inactivation transgenic mice confirms the lateral displacement of ChAT amacrine cells away from their clonal columns of origin, and mathematical models show how short-range cellular interactions can guide the assemblage of these mosaics via a simple biological rule.
Key words: retina; LIM proteins; Islet-1; X-inactivation transgenic mouse; ChAT amacrine; tangential migration; Voronoi domains
INTRODUCTION
The retina is one of the best examples of modular organization in neural circuitry. The five main types of retinal neurons are organized into three cell layers. Photoreceptors occupy the outer nuclear layer, bipolar, horizontal, and amacrine cells the inner nuclear layer (INL), and ganglion cells and displaced amacrine cells the ganglion cell layer (GCL). Each principal class of retinal neurons can be divided further into subtypes, which differ in morphology and connectivity as well as biochemical and physiological properties (for review, see Ramon y Cajal, 1892
; Rodieck, 1973
Although the orderly organization of retinal cells is known to be fundamental to the parallel processing of visual information in the retina, little is known of the way neuronal mosaics form during development. Postmitotic retinal neurons migrate to their final positions from the proliferative neuroepithelium, but known markers for retinal mosaics are expressed only after the cells have attained a regular spatial arrangement (Wässle and Riemann, 1978
Here we report that the transcription factor Islet-1 is an early marker for cholinergic amacrine cells. Islet-1, a member of the LIM homeodomain family known to be involved in vertebrate and invertebrate development (Thor et al., 1991
MATERIALS AND METHODS
Surgical procedures and tissue preparation. Long-Evans hooded rats were bred in the laboratory colony. Embryos of known gestational ages were obtained from animals allowed to mate for 12 hr. The morning after mating was designed as E0. To obtain fetal retinas, pregnant rats were anesthetized with Ketalar (ketamine chlorohydrate; Parke Davis Italia) (50 mg/kg body weight, i.m.) at chosen gestational ages, and their fetuses were dissected out. In some experiments, pregnant animals at 17 d of gestation were injected with 5-bromo-2-deoxyuridine (BrdU) 2 hr before fixation to label proliferating cells. Animals were killed by decapitation, and their eyes were removed and fixed by immersion in 4% paraformaldehyde in 0.1 M sodium phosphate buffer. Retinas were routinely dissected and mounted flat. When necessary, fixed eyes were cryoprotected in 20% sucrose in phosphate buffer overnight, embedded in Tissue Freezing medium (Jung), frozen with liquid nitrogen, and sectioned with a cryostat in 10-µm-thick radial sections.
To determine whether the cholinergic amacrine cells are among the cell types that have recently been shown to disperse tangentially from their clonal columns of origin (Reese et al., 1995 -galactosidase. Mice were perfused with physiological saline followed by 4% paraformaldehyde in phosphate buffer. Retinae were dissected whole and then processed for X-gal histochemistry to yield the blue
To distinguish Islet-1+ amacrine cells from Islet-1+ ganglion cells in the GCL, the optic nerve was transected at birth, which causes ganglion cell degeneration within 48 hr (Perry et al., 1983
Immunohistochemistry. 4D5 monoclonal antibody to Islet-1 (1:100), A8 rabbit antiserum against Islet-1 (1:5000; both kindly provided by Dr. T. Jessell, Columbia University), polyclonal anti-ChAT (1:100; Chemicon, Temecula, CA), and monoclonal anti-BrdU antibody (1:75; Boehringer Mannheim) were used. For retinal whole-mount immunohistochemistry, a standard protocol was used, with 4 d incubation in primary antibody and 2 d in secondary antibody (Casini and Brecha, 1991
Data acquisition. Retinae were drawn before and after histological treatment and analyzed only if they had undergone minimal (<5%) shrinkage. Six retinas and 10-20 sampling fields (250 × 160 µm2) per retina, taken at three different eccentricities, were analyzed for each age. Cell positioning data and retinal size were acquired by means of an Image Analyzer (Imaging, Ontario, Quebec, Canada) connected to a Zeiss Axiophot microscope. The total number of labeled cells in a retina was determined by multiplying the retinal area, and the average density of labeled cells was determined in the sampling fields. A Leica TCSNT Confocal Microscope was used to determine colocalization for ChAT/Islet-1 and to analyze potential BrdU/Islet-1 double-labeling in retinal cross sections.
Data analysis. The analysis of the spatial organization of the two Islet-1 mosaics was performed by determining the classic distribution of nearest neighbor distances (Wässle and Riemann, 1978 2 tests for comparison of two sets of data, deriving variances from the experimental data (which had a Gaussian distribution within each histogram bin). For this analysis, adjacent bins were pooled together when necessary to avoid cases with fewer than five events.
Analysis of transgenic retinae. Double-labeled transgenic whole mounts were scanned using a 100× oil immersion objective, and blue (transgene-expressing, or transgene+) ChAT+ double-labeled cells in the GCL and INL were counted. Each of these double-labeled cells was identified as being positioned within a blue (transgene+) or a white (transgene ) column. The latter provide an unambiguous index of the frequency of such cells outside of their clonal territories of origin (Reese et al., 1995
Mathematical simulation. Distributions with a lower limit for intercellular distances were generated by randomly positioning one cell at a time in the sampling field, determining its distance from its closest neighbor and eliminating it whenever it was closer to its nearest neighbor than this selected minimal distance. This process was continued as described above, until the simulated distribution reached the same cell density as that of the real mosaic. Such a distribution corresponds to the distribution of spheres of diameter equal to the chosen minimal intercellular distance. Best simulations were obtained if the minimal distance was allowed to vary within a limited range, which corresponds to a more realistic biological constraint, in which minimal distance varies slightly around a mean value. In this case each cell generated in the simulation was left in place if its distance from its nearest neighbor was higher than a variable value drawn from a Gaussian distribution of given mean and width. To compare simulated and real mosaics, we also used Fourier transforms, which would reveal any hidden geometrical pattern. Fast Fourier transforms (FFTs) were generated by applying the FFT algorithm (Brigham, 1974
RESULTS
Islet-1 is expressed by amacrine cells forming two mosaics
We have found that two mosaics of amacrine cells of the rat retina express the transcription factor Islet-1. One mosaic occupies the inner part of the INL (Fig. 1a), whereas the other is found in the GCL (Fig. 1b), where some ganglion cells also express Islet-1 (Thor et al., 1991
Fig. 1. a, Islet-1 mosaic in the inner nuclear layer (INL) of a flat-mounted adult rat retina. Scale bar, 20 µm. b, Islet-1+ (red) cells in the ganglion cell layer (GCL) of the same retina as in a. Ganglion cells, retrogradely labeled with Fluorogold (light yellow), in some cases reveal Islet-1 labeling. Blue patches are salt precipitates that fluoresce when viewed with the filter used for Fluorogold. Scale bar, 20 µm. c, Islet-1+ mosaics correspond to the mosaics of cholinergic amacrine cells, as demonstrated by double-immunofluorescence studies in adult rat retina. The figure shows a confocal image of a radial retinal section (perpendicular to the plane in a and b). Arrowheads point to the amacrine cells that are double-labeled for ChAT (green) and Islet-1 (red). All cholinergic amacrine cells are Islet-1+ immunoreactive amacrine cells and vice versa. Bipolar cells are also Islet-1+ in the adult retina but can easily be distinguished from other Islet-1+ cells by their different position in the retina. The retina illustrated has no ganglion cells; these had all been selectively removed by optic nerve section at birth. Scale bar, 20 µm. d, Expression of Islet-1 in the embryonic retina. On E17, Islet-1 (brown) was expressed by cells that were still in the proliferative zone (PZ), as well as by cells that had already migrated to the vitreal side of the retina (bottom), where different layers cannot yet be distinguished at this age. Scale bar, 10 µm. e, Islet-1+ cells are all postmitotic. Two hours after BrdU injection, no Islet-1+ cell (green, arrowheads) is labeled with BrdU (red), which had been incorporated by proliferating cells. Superimposition of eight optical sections was obtained with a confocal microscope across an overall depth of 10 µm in an E17 retinal section. The only apparent double-labeled cell (arrow) is due to the partial physical superimposition of two cells. PZ is the proliferative zone. Scale bar, 10 µm. f, Islet-1+ mosaic in the INL on E21.5. Note the similarity to the adult mosaic. Scale bar, 10 µm. Nomarski optics.
[View Larger Version of this Image (0K GIF file)]
Islet-1 belongs to the family of LIM homeodomain proteins involved in cell fate determination in many different systems (Thor et al., 1991 Immature Islet-1 mosaics have the same regularity of their adult form and preserve it throughout the time new cells are added
When the the inner portion of the INL became distinguishable within the region of postmitotic cells, it initially contained irregularly spaced Islet-1+ cells, comprising both the future INL mosaic cells and many Islet-1+ cells migrating toward the GCL (not shown). The mosaic of Islet-1+ cells in the INL was first identified 1 d before birth (E21.5) (Fig. 1f), long before any cholinergic marker is detectable (Mitrofanis et al., 1988
Between E21 and P4 the retina expands, and ~30% more Islet-1+ cells enter the INL mosaic, which contains 24,300 ± 1000 cells on E21.5 and 32,000 ± 1800 on P4, when the adult complement of cells is reached. To monitor how the entry of new cells affected mosaic order, we have studied the tiling of the plane generated by the mosaics throughout this period, as well as the classic distribution of nearest neighboring distances (Wässle and Riemann, 1978
Throughout the period of new cell addition, the statistical distributions of Voronoi domains, nearest neighbor distances, and Delaunay segments associated with the Islet-1 mosaic in the INL remained unchanged, indicating that the mosaic preserved its spatial organization during the period of retinal expansion and Islet-1+ cell addition. These results are illustrated in Figure 2a,b for the Voronoi domains and the nearest neighbor distance. The red lines in Figure 2a,b show the expected final distributions if cells entering the mosaic between E21.5 and P4 were randomly positioned. 
Fig. 2. Islet-1 mosaics preserve their spatial organization while new cells are added. a, Voronoi domains and (b) nearest neighbor distances of the INL mosaic on E21.5 (triangles), P2 (circles), and P4 (squares). No change with time is observed in the normalized histograms, although ~30% more cells enter the mosaic between E21.5 and P4. When experimental variation is considered (not shown), the P4 distribution represents a fit for the E21.5 distribution, with p > 0.99 for the nearest neighbor distance and p > 0.95 for the Voronoi distribution, as determined by
[View Larger Version of this Image (0K GIF file)]
The second mosaic of Islet-1+ amacrine cells, located in the GCL, was studied from P1.5 onward. To be able to distinguish Islet-1+ amacrine cells from Islet-1+ ganglion cells in the GCL, we either severed the optic nerve at birth, which causes ganglion cell degeneration within 48 hr (Perry et al., 1983
In conclusion, immature Islet-1 mosaics had the same regularity of their adult forms and preserved it throughout the period of new cell addition, indicating the existence of an active control of regular cell positioning. In this respect, it is interesting to consider that the distributions associated with the two Islet-1 mosaics did not vary with eccentricity at the ages tested (not shown), and that both mosaics displayed the same minimal Voronoi area (compare a and c) and the same minimal intercellular spacing (compare b and d), although the regularity of the GCL mosaic was always lower than that of the INL. Spatial ordering is not achieved at the time of terminal mitosis
To understand whether mosaic regularity reflects a spatial order that cells possess before reaching the mosaic layer, we analyzed the spacing between neighboring Islet-1+ cells before entry into the mosaic. This analysis required that a single population of migrating Islet-1 amacrine cells could be identified selectively, which was impossible in the proliferative zone where one could not discriminate between cells destined to enter separate mosaics. We therefore studied cells migrating through the inner plexiform layer (IPL) toward the GCL (Fig. 3a), to examine only the population of Islet-1+ amacrine cells destined for the GCL. As mentioned before, some ganglion cells are also Islet-1+; however, several studies have documented the later migration of amacrine cells with respect to synchronously born ganglion cells, so that after P0 only amacrine cells are still migrating through the IPL in the central retina (Perry et al., 1983
Fig. 3. a, Islet-1+ cells crossing the IPL have no minimal intercellular spacing. Cross section of a P1 retina. The spacing between Islet-1+ amacrine cells migrating through the inner plexiform layer (IPL) was studied after P0 in the central retina, where the migration of ganglion cells that also express Islet-1 has ceased by this time. Scale bar, 10 µm. b, Lack of regular intercellular spacing between Islet-1 cells that are still outside the GCL mosaic. Normalized histogram of nearest neighbor distances between Islet-1+ cells in the IPL (filled squares) in P2 retinal sections. The histogram shows that the only limit to the spacing between Islet-1+ cells migrating through the IPL is the diameter of the cell, simply reflecting the fact that two cells cannot occupy the same physical space. The nearest neighbor distribution in the INL derived from the same sections (open circles) is shown as a comparison, because the minimal spacing is the same in both Islet-1 mosaics. As should be expected, the normalized distributions of nearest neighbor distances computed in sections and flat-mounted retina have the same minimal spacing but different tails, because the nearest neighbor in sections can be farther away (but, of course, never closer) than the real nearest neighbor in the mosaic. Counts were made in 30 randomly selected P2 sections from two retinae (n = 2). c, Retinal whole mount from an X-inactivation transgenic mouse showing a portion of the INL. Arrowheads point to four mosaic cells (brown; ChAT-immunoreactive) that are transgene-positive (blue) but are displaced in transgene-negative columns. These cells must be derived from neighboring transgene-positive clones. d, A portion of the ganglion cell layer showing one transgene-positive mosaic cell (arrowhead) and several transgene-positive ganglion cells (the largest cells in the field) in a transgene-negative column. These cells must have moved tangentially away from their clone of origin. Scale bar, 20 µm.
[View Larger Version of this Image (88K GIF file)]
We have found that neighboring Islet-1+ cells crossing the IPL could frequently be found side by side in the central retina, as illustrated in Figure 3a. Consequently, the distribution of nearest neighboring distances for Islet-1+ cells crossing the IPL lacked the minimal intercellular distance characteristic of the elements of the mosaics (Fig. 3b). This indicates that Islet-1+ amacrine cells attain their characteristic spacing only once they enter the mosaic layers. Clonal territory analysis in X-inactivation transgenic mice reveals lateral movement of mosaic cells
We know from previous studies that certain types of retinal neurons become displaced tangentially from their clonal columns of origin, and it has been suggested that this tangential dispersion contributes to the formation of orderly retinal mosaics (Reese et al., 1995Short-range cellular interactions are sufficient to generate the Islet-1 mosaics
How cells "know" whether a given position is compatible with mosaic regularity remains unknown, but mathematical analysis provides some important clues. We have found that Islet-1+ mosaics are indistinguishable from random distributions of the same density where neighboring cells could not be closer than a fixed minimal distance of 15 ± 2 µm.
The experimental distributions of Voronoi domains and Delaunay segments associated with the simulated distributions were the same as those associated with the real mosaic, as shown qualitatively in Figure 4a-c, where the Voronoi domains associated with the real mosaic (Fig. 4a) are shown together with those associated with the simulated distribution (Fig. 4b), and for comparison are shown with those of a pure random distribution (Fig. 4c). In further support of this model, the FFTs, which would reveal any hidden geometrical patterns, were the same for the experimental and the simulated mosaics within a 10% error (Fig. 4d-f). 
Fig. 4. Islet-1 mosaics are indistinguishable from random distributions generated by imposing a minimal distance of 15 ± 2 µm between neighboring cells. a, A field of the INL Islet-1 mosaic is illustrated (dots represent cells) together with the tiling of the plane that it generates (Voronoi domains). b, Tiling of the plane arising from a random distribution of cells (randomdmin) that was generated, imposing a lower limit (dmin = 15 ± 2 µm) to the distance between neighboring cells. Cell density is identical to that of the Islet-1+ mosaic shown in a. c, Tiling generated by a random distribution of cells at the same cell density as in a. d, e, Fast Fourier Transform (FFT) of the Islet-1 mosaic (d) and the randomdmin distribution (e). FFTs are represented as amplitude maps and illustrated in the intervalsx
(
1),
[View Larger Version of this Image (69K GIF file)]
These results indicate that short-range cellular interactions that prevent cells from getting closer than 15 ± 2 µm to one another are sufficient to generate the regularity of Islet-1 mosaics.
DISCUSSION
We have shown that two mosaics of amacrine cells express the transcription factor Islet-1 before their assembly is complete. As soon as Islet-1 mosaics can be identified, they show the same regularity of their adult form, and preserve it throughout the time new cells are added. Migrating Islet-1+ cells do not show this spatial ordering, indicating that they must move tangentially as they enter the mosaic, under the action of local mechanisms. Clonal territory analysis in X-inactivation transgenic mice confirms the lateral displacement of these cells away from their clonal columns of origin, and mathematical models show that a local rule forcing cells to stay at a minimal distance of 15 ± 2 µm from one another is sufficient to assemble Islet-1 mosaics.Islet-1 is expressed by the elements of two mosaics of amacrine cells before mosaic assembly is complete
A number of previous studies have analyzed the development of retinal mosaics, but all relied on markers that are expressed by cells only after they have entered their mosaics, making it difficult to understand how regularity comes about (Wässle and Riemann, 1978
Islet-1+ amacrine cells in the adult retina express ChAT immunoreactivity, but the appearance of orderly arrays of Islet-1+ amacrine cells precedes by more than 2 weeks the first detectable immunoreactivity for ChAT in the rat retina (Mitrofanis et al., 1988 Regularity is an intrinsic property of Islet-1 mosaics, dynamically preserved while new elements are added into the mosaics
Mathematical analyses show that both Islet-1 mosaics have an intrinsic regularity, which is the same found in the mature mosaics and is preserved throughout the time new cells are added. This was determined by monitoring mosaic regularity by means of the classic method of nearest neighbor distance, as well as by analyzing the tiling of the plane associated with the mosaics, described by the Voronoi domains, which assign to each cell the region of the plane containing the points closer to that cell than to any other cell of the mosaic. Although Voronoi domains are a pure geometrical abstraction, their biological significance should not be underrated. The Voronoi domain is the field the cell controls if all mosaic cells secrete some factor, and it is also the minimal region over which the dendritic tree of the cell should extend to ensure a complete tiling of the plane by the mosaic of dendritic fields. Thus, the constancy of the Voronoi domains associated with Islet-1 mosaics during development reveals the constancy of the biological interactions that underlie mosaic formation.Clonal boundary analysis in X-inactivation transgenic mice reveals that lateral displacement is the likely means by which mosaic regularity is established
New Islet-1+ cells are not regularly spaced before their entry into the mosaic, indicating that an orderly spacing of Islet-1+ amacrine cells is not established at the time of terminal division or at the time of commitment to the Islet-1+ status. Indeed, because the genesis of mosaic cells destined to occupy the same retinal region occurs over several days (Reese and Colello, 1992Short-range interactions are sufficient to assemble the Islet-1 mosaic
The central biological question of how cells "know" where to go remains unsolved; however, the absence of order between Islet-1+ cells before their entry in the mosaics suggests that local mechanisms account for the appropriate positioning of the mosaic cells. By mathematical modeling we have shown that simulated distributions of cells that are constrained only by a minimal intercellular distance of 15 ± 2 µm are indistinguishable from the real Islet-1 mosaics. These correspond to random distributions of spheres of diameter 15 ± 2 µm. Because Islet-1+ cell bodies are only ~4 µm in diameter at the ages studied (Fig. 1f), this model suggests a mechanism by which cells can exclude other cells in their layer from a minimal circular area of ~((15 ± 2)/2)2 µm2 around them. Whether this is achieved by contact inhibition between developing dendritic trees or by other means remains to be determined; mathematical modeling indicates only that this type of local mechanism can generate the mosaics, not that it actually does so.
Random distributions with a lower limit for intercellular distance may seem poor modular structures, but they offer considerable advantages. They can be generated entirely by local interactions, require a minimal building rule, are extremely tolerant to assembling errors, and can ensure a uniform sampling of space, a fundamental requirement for the formation of modular circuits. Furthermore, their regularity is not considerably altered by the random elimination of a limited number of cells (as could be the case with cell death), and their extent can easily be increased by the addition of new elements, a mechanism largely exploited in evolution (Rakic, 1995
FOOTNOTES
Received June 9, 1997; revised August 1, 1997; accepted August 6, 1997.
This work was supported by the Consiglio Nazionale delle Ricerche (L.G.-R., G.R.), the European Community, DG XII, Biotechnology Program (L.G.-R.), the NH and Medical Research Council (S.-S.T.), and National Institutes of Health (B.E.R.). We thank Dr. T. Jessell for the kind gift of 4D5 and A8 antibodies, and M. Ensini, E. Strettoi, M. Morrone, D. Petracchi, and L. Chalupa for helpful comments.
Correspondence should be addressed to Lucia Galli-Resta, Istituto di Neurofisiologia del Consiglio Nazionale delle Ricerche, via San Zeno 51, 56127 Pisa, Italy.
REFERENCES
- Brigham EO (1974) In: The fast Fourier transform. Englewoods Cliffs, NJ: Prentice-Hall.
- Casini G, Brecha N (1991) Vasoactive intestinal polypeptide- containing cells in the rabbit retina: immunohistochemical localization and quantitative analysis. J Comp Neurol 305:313-327[ISI][Medline].
- Cook JE (1996) Spatial properties of retinal mosaics: an empirical evaluation of some existing measures. Vis Neurosci 13:15-30[ISI][Medline].
- Dowling JE (1987) In: The retina, an approachable part of the brain. Cambridge, MA: Harvard UP.
- Ericson J, Thor S, Edlund T, Jessell TM, Yamada TY (1992) Early stages of motor neuron differentiation revealed by expression of Homeobox gene Islet-1. Science 256:1555-1560
[Abstract/Free Full Text] .- Feller MB, Wellis DP, Stellwagen D, Werblin FS, Shatz CJ (1996) Requirement for cholinergic synaptic transmission in the propagation of spontaneous retinal waves. Science 272:1182-1187[Abstract].
- Fortune SJ (1987) A sweepline algorithm for Voronoi diagrams. Algorithmica 2:153-172.
- Galli-Resta L, Ensini M (1996) An intrinsic limit between genesis and death of individual neurons in the developing retinal ganglion cell layer. J Neurosci 16:2318-2324
[Abstract/Free Full Text] .- Grumnbaum B, Shephard GC (1989) In: Tilings and patterns. An introduction. New York: Freeman.
- Hutsler JJ, Chalupa LM (1995) Development of neuropeptide Y immunoreactive amacrine and ganglion cells in the pre- and postnatal cat retina. J Comp Neurol 361:152-164[ISI][Medline].
- Jacobson M (1991) In: Developmental neurobiology. New York: Plenum.
- Masland RH, Tauchi M (1986) The cholinergic amacrine cell. Trends Neurosci 9:218-223[ISI].
- Mitrofanis J, Maslim J, Stone J (1988) Catecholaminergic and cholinergic neurons in the developing retina of the rat. J Comp Neurol 276:343-359[ISI][Medline].
- Perry VH, Henderson Z, Linden R (1983) Postnatal changes in retinal ganglion and optic axon populations in the pigmented rat. J Comp Neurol 219:356-368[ISI][Medline].
- Rakic P (1995) A small step for the cell, a giant leap for mankind: a hypothesis of neocortical expansion during evolution. Trends Neurosci 18:383-388[ISI][Medline].
- Ramon y Cajal S (1892) In: The structure of the retina (Thrope SA, Glickenstein M, translators). Springfield, IL: Charles C. Thomas.
- Reese BE, Colello RJ (1992) Neurogenesis in the retinal ganglion cell layer of the rat retina. Neuroscience 46:419-429[ISI][Medline].
- Reese BE, Harvey AR, Tan S-S (1995) Radial and tangential dispersion patterns in the mouse retina are cell-class specific. Proc Natl Acad Sci USA 92:2494-2498
[Abstract/Free Full Text] .- Rodieck RW (1973) In: The vertebrate retina: principles of structure and function. New York: Freeman.
- Scheibe R, Schnitzer J, Röhrenbeck J, Wohlrab F, Reichenbach A (1995) Development of A-type (axonless) horizontal cells in the rabbit retina. J Comp Neurol 354:438-458[ISI][Medline].
- Tan S-S, Williams EA, Tam PP (1993) X-chromosome inactivation occurs at different times in different tissues of the post-implantation mouse embryo. Nat Genet 3:170-174[ISI][Medline].
- Thor S, Ericson J, Brännström T, Edlund T (1991) The homeodomain LIM protein Isl-1 is expressed in subsets of neurons and endocrine cells in the adult rat. Neuron 7:881-889[ISI][Medline].
- Tsuchida T, Ensini M, Morton SB, Baldassarre M, Edlund T, Jessel TM, Pfaff SL (1994) Topographic organization of embryonic motor neurons defined by expression of LIM homeobox genes. Cell 79:957-970[ISI][Medline].
- Turner DL, Snyder EY, Cepko CL (1990) Lineage-independent determination of cell type in the embryonic mouse retina. Neuron 4:833-845[ISI][Medline].
- Vaney DI (1990) The mosaic of amacrine cells in the mammalian retina. Prog Retinal Res 9:49-100.
- Voigt T (1986) Cholinergic amacrine cells in the rat retina. J Comp Neurol 248:19-35[ISI][Medline].
- Wässle H, Boycott BB (1991) Functional architecture of the mammalian retina. Physiol Rev 71:447-480
[Free Full Text] .- Wässle H, Riemann HJ (1978) The mosaic of nerve cells in the mammalian retina. Proc R Soc Lond [Biol] 200:441-461[Medline].
- Wikler KC, Rakic P (1991) Relation of an array of early-differentiated cones to the photoreceptor mosaic in the primate retina. Nature 351:397-400[Medline].
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[Abstract] [Full Text] [PDF]
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[Abstract] [Full Text] [PDF]
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Spatiotemporal Features of Early Neuronogenesis Differ in Wild-Type and Albino Mouse Retina
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[Abstract] [Full Text] [PDF]
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[Abstract] [Full Text] [PDF]
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p57(Kip2) regulates progenitor cell proliferation and amacrine interneuron development in the mouse retina
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[Abstract] [PDF]
L Galli-Resta
Local, possibly contact-mediated signalling restricted to homotypic neurons controls the regular spacing of cells within the cholinergic arrays in the developing rodent retina
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[Abstract] [PDF]
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Spatial order within but not between types of retinal neurons
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[Abstract] [Full Text] [PDF]
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[Abstract] [Full Text] [PDF]
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