Hostname: page-component-84b7d79bbc-g78kv Total loading time: 0 Render date: 2024-07-25T16:11:17.119Z Has data issue: false hasContentIssue false
  • English
  • Français

Regularity and packing of the horizontal cell mosaic in different strains of mice

Published online by Cambridge University Press:  06 October 2005

MARY A. RAVEN ,
STEPHANIE B. STAGG  and
BENJAMIN E. REESE
MARY A. RAVEN
Affiliation:
Neuroscience Research Institute and Department of Psychology, University of California at Santa Barbara, Santa Barbara
STEPHANIE B. STAGG
Affiliation:
Neuroscience Research Institute and Department of Psychology, University of California at Santa Barbara, Santa Barbara
BENJAMIN E. REESE
Affiliation:
Neuroscience Research Institute and Department of Psychology, University of California at Santa Barbara, Santa Barbara
Get access Rights & Permissions [Opens in a new window]

Abstract

The present study describes the relationships between mosaic regularity, intercellular spacing, and packing of horizontal cells across a two-fold variation in horizontal cell density in four strains of mice. We have tested the prediction that mosaic patterning is held constant across variation in density following our recent demonstration that intercellular spacing declines as density increases, by further examination of that dataset: Nearest-neighbor and Voronoi-domain analyses were conducted on multiple fields of horizontal cells from each strain, from which their respective regularity indices were calculated. Autocorrelation analysis was performed on each field, from which the density recovery profile was generated, and effective radius and packing factor were calculated. The regularity indexes showed negative correlations with density rather than being held constant, suggesting that the strong negative correlation between intercellular spacing and density exceeded that required to produce a simple scaling of the mosaic. This was confirmed by the negative correlation between packing factor and density. These results demonstrate that the variation in the patterning present in the population of horizontal cells across these strains is a consequence of epigenetic mechanisms controlling intercellular spacing as a function of density.

Keywords

Nearest neighborVoronoi domainAutocorrelationDensity recovery profileRetinaDevelopment
Type
Research Article
Information
Visual Neuroscience , Volume 22 , Issue 4 , July 2005 , pp. 461 - 468
Copyright
2005 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Cameron, D.A. & Carney, L.H. (2004). Cellular patterns in the inner retina of adult zebrafish: Quantitative analyses and a computational model of their formation. Journal of Comparative Neurology 471, 1125.Google Scholar
Cellerino, A., Novelli, E., & Galli-Resta, L. (2000). Retinal ganglion cells with NADPH-diaphorase activity in the chick form a regular mosaic with a strong dorsoventral asymmetry that can be modelled by a minimal spacing rule. European Journal of Neuroscience 12, 613620.Google Scholar
Cook, J.E. (1996). Spatial properties of retinal mosaics: An empirical evaluation of some existing measures. Visual Neuroscience 13, 1530.Google Scholar
Cook, J.E. (2003). Spatial regularity among retinal neurons. In The Visual Neurosciences, ed. Chalupa, L.M. & Werner, J.S., pp. 463477. Boston, Massachusetts: MIT Press.
Curcio, C.A. & Sloan, K.R. (1992). Packing geometry of human cone photoreceptors: Variation with eccentricity and evidence for local anisotropy. Visual Neuroscience 9, 169180.Google Scholar
Donatien, P. & Jeffery, G. (2002). Correlation between rod photoreceptor numbers and levels of ocular pigmentation. Investigative Ophthalmology and Visual Science 43, 11981203.Google Scholar
Dorsky, R.I., Chang, W.S., Rapaport, D.H., & Harris, W.A. (1997). Regulation of neuronal diversity in the Xenopus retina by Delta signalling. Nature 385, 6770.Google Scholar
Dyer, M.A., Livesey, F.J., Cepko, C.L., & Oliver, G. (2003). Prox1 function controls progenitor cell proliferation and horizontal cell genesis in the mammalian retina. Nature Genetics 34, 5358.Google Scholar
Eglen, S.J., van Ooyen, A., & Willshaw, D.J. (2000). Lateral cell movement driven by dendritic interactions is sufficient to form retinal mosaics. Network: Computation in Neural Systems 11, 103118.Google Scholar
Eglen, S.J., Galli-Resta, L., & Reese, B.E. (2003a). Theoretical models of retinal mosaic formation. In Modelling Neural Development, ed. van Ooyen, A., pp. 133150. Boston, Massachusetts: MIT Press.
Eglen, S.J., Raven, M.A., Tamrazian, E., & Reese, B.E. (2003b). Dopaminergic amacrine cells in the inner nuclear layer and ganglion cell layer comprise a single functional retinal mosaic. Journal of Comparative Neurology 466, 343355.Google Scholar
Galli-Resta, L. (2000). Local, possibly contact-mediated signalling restricted to homotypic neurons controls the regular spacing of cells within the cholinergic arrays in the developing rodent retina. Development 127, 15091516.Google Scholar
Galli-Resta, L. (2002). Putting neurons in the right places: Local interactions in the genesis of retinal architecture. Trends in Neurosciences 25, 638643.Google Scholar
Galli-Resta, L., Novelli, E., Kryger, Z., Jacobs, G.H., & Reese, B.E. (1999). Modelling the mosaic organization of rod and cone photoreceptors with a minimal-spacing rule. European Journal of Neuroscience 11, 14611469.Google Scholar
Galli-Resta, L., Novelli, E., & Viegi, A. (2002). Dynamic microtubule-dependent interactions position homotypic neurones in regular monolayered arrays during retinal development. Development 129, 38033814.Google Scholar
He, S., Weiler, R., & Vaney, D.I. (2000). Endogenous dopaminergic regulation of horizontal cell coupling in the mammalian retina. Journal of Comparative Neurology 418, 3340.Google Scholar
Jeyarasasingam, G., Snider, C.J., Ratto, G.-M., & Chalupa, L.M. (1998). Activity-regulated cell death contributes to the formation of ON and OFF alpha ganglion cell mosaics. Journal of Comparative Neurology 394, 335343.Google Scholar
Kouyama, N. & Marshak, D.W. (1997). The topographical relationship between two neuronal mosaics in the short wavelength-sensitive system of the primate retina. Visual Neuroscience 14, 159167.Google Scholar
Li, S., Mo, Z., Yang, X., Price, S.M., Shen, M.M., & Xiang, M. (2004). Foxn4 controls the genesis of amacrine and horizontal cells by retinal progenitors. Neuron 43, 795807.Google Scholar
Lia, B., Williams, R.W., & Chalupa, L.M. (1987). Formation of retinal ganglion cell topography during prenatal development. Science 236, 848851.Google Scholar
Peichl, L. & González-Soriano, J. (1994). Morphological types of horizontal cell in rodent retinae: A comparison of rat, mouse, gerbil, and guinea pig. Visual Neuroscience 11, 501517.Google Scholar
Peichl, L., Sandmann, D., & Boycott, B.B. (1998). Comparative anatomy and function of mammalian horizontal cells. In Development and Organization of the Retina, ed. Chalupa & L.M., Finlay, B.L., pp. 147172. New York: Plenum Press.
Petkov, P.M., Ding, Y., Cassell, M.A., Zhang, W., Wagner, G., Sargent, E.E., Asquith, S., Crew, V., Johnson, K.A., Robinson, P., Scott, V.E., & Wiles, M.V. (2004). An efficient SNP system for mouse genome scanning and elucidating strain relationships. Genome Research 14, 18061811.Google Scholar
Raven, M.A. & Reese, B.E. (2002). Horizontal cell density and mosaic regularity in pigmented and albino mouse retina. Journal of Comparative Neurology 454, 168176.Google Scholar
Raven, M.A. & Reese, B.E. (2003). Mosaic regularity of horizontal cells in the mouse retina is independent of cone photoreceptor innervation. Investigative Ophthalmology and Visual Science 44, 965973.Google Scholar
Raven, M.A., Eglen, S.J., Ohab, J.J., & Reese, B.E. (2003). Determinants of the exclusion zone in dopaminergic amacrine cell mosaics. Journal of Comparative Neurology 461, 123136.Google Scholar
Reese, B.E. & Galli-Resta, L. (2002). The role of tangential dispersion in retinal mosaic formation. Progress in Retinal and Eye Research 21, 153168.Google Scholar
Reese, B.E., Harvey, A.R., & Tan, S.-S. (1995). Radial and tangential dispersion patterns in the mouse retina are cell-class specific. Proceedings of the National Academy of Sciences of the U.S.A. 92, 24942498.Google Scholar
Reese, B.E., Necessary, B.D., Tam, P.P.L., Faulkner-Jones, B., & Tan, S.-S. (1999). Clonal expansion and cell dispersion in the developing mouse retina. European Journal of Neuroscience 11, 29652978.Google Scholar
Reese, B.E., Raven, M.A., & Stagg, S.B. (2005). Afferents and homotypic neighbors regulate horizontal cell morphology, connectivity and retinal coverage. Journal of Neuroscience 25, 21672175.Google Scholar
Rice, D.S., Williams, R.W., & Goldowitz, D. (1995). Genetic control of retinal projections in inbred strains of albino mice. Journal of Comparative Neurology 354, 459469.Google Scholar
Rockhill, R.L., Euler, T., & Masland, R.H. (2000). Spatial order within but not between types of retinal neurons. Proceedings of the National Academy of Sciences of the U.S.A. 97, 23032307.Google Scholar
Rodieck, R.W. (1991). The density recovery profile: A method for the analysis of points in the plane applicable to retinal studies. Visual Neuroscience 6, 95111.Google Scholar
Rodieck, R.W. & Marshak, D.W. (1992). Spatial density and distribution of choline acetyltransferase immunoreactive cells in human, macaque, and baboon retinas. Journal of Comparative Neurology 321, 4664.Google Scholar
Scheibe, R., Schnitzer, J., Rohrenbeck, J., Wohlrab, F., & Reichenbach, A. (1995). Development of A-type (axonless) horizontal cells in the rabbit retina. Journal of Comparative Neurology 354, 438458.Google Scholar
Strettoi, E. & Pignatelli, V. (2000). Modifications of retinal neurons in a mouse model of retinitis pigmentosa. Proceedings of the National Academy of Sciences of the U.S.A. 97, 1102111025.Google Scholar
Strettoi, E. & Volpini, M. (2002). Retinal organization in the bcl-2-overexpressing transgenic mouse. Journal of Comparative Neurology 446, 110.Google Scholar
Wässle, H. & Riemann, H.J. (1978). The mosaic of nerve cells in the mammalian retina. Proceedings of the Royal Society B (London) 200, 441461.Google Scholar
Wässle, H., Peichl, L., & Boycott, B.B. (1978). Topography of horizontal cells in the retina of the domestic cat. Proceedings of the Royal Society B (London) 203, 269291.Google Scholar
Wässle, H., Röhrenbeck, J., & Boycott, B.B. (1989). Horizontal cells in the monkey retina: Cone connections and dendritic network. European Journal of Neuroscience 1, 421435.Google Scholar
Williams, R.W., Strom, R.C., & Goldowitz, D. (1998a). Natural variation in neuron number in mice is linked to a major quantitative trait locus on Chr 11. Journal of Neuroscience 18, 138146.Google Scholar
Williams, R.W., Strom, R.C., Zhou, G., & Yan, Z. (1998b). Genetic dissection of retinal development. Seminars in Cell and Developmental Biology 9, 249255.Google Scholar
Young, R.W. (1984). Cell death during differentiation of the retina in the mouse. Journal of Comparative Neurology 229, 362373.Google Scholar
Zhan, X.J. & Troy, J.B. (2000). Modeling cat retinal beta-cell arrays. Visual Neuroscience 17, 2339.Google Scholar