Stochastic Interaction between Neural Activity and Molecular Cues in the Formation of Topographic Maps

Neuron

Volumn 87, Issue 6, 2015, Pages 1261-1273

  Owens, Melinda T ^a   Feldheim, David A ^b   Stryker, Michael P ^a   Triplett, Jason W ^b,c  

^a UNIVERSITY OF CALIFORNIA   (United States)

^b UNIVERSITY OF CALIFORNIA   (United States)

^c CHILDREN'S NATIONAL MEDICAL CENTER   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

EPHRIN RECEPTOR A3;

ADULT; ANIMAL CELL; ANIMAL TISSUE; ARTICLE; ASSOCIATION; BRAIN MAPPING; CELL ACTIVITY; CONTROLLED STUDY; EPHA3 GENE; EVOKED VISUAL RESPONSE; FUNCTIONAL ANATOMY; GENETIC VARIABILITY; HEMISPHERE; HETEROZYGOTE; MOUSE; NEUROANATOMY; NONHUMAN; PRIORITY JOURNAL; RETINA; STATISTICAL ANALYSIS; STOCHASTIC MODEL; SUPERIOR COLLICULUS; TOPOGRAPHIC MAP; VISION; VISUAL DISCRIMINATION; VISUAL SYSTEM; ANIMAL; C57BL MOUSE; CYTOLOGY; GENE TARGETING; NERVE CELL; PHYSIOLOGY; PROCEDURES; RETINA GANGLION CELL; STATISTICS; TRANSGENIC MOUSE;

ANIMALS; BRAIN MAPPING; CUES; GENE KNOCK-IN TECHNIQUES; MICE; MICE, INBRED C57BL; MICE, TRANSGENIC; NEURONS; RETINAL GANGLION CELLS; STOCHASTIC PROCESSES; SUPERIOR COLLICULI; VISUAL PATHWAYS;

EID: 84942115024     PISSN: 08966273     EISSN: 10974199     Source Type: Journal    
DOI: 10.1016/j.neuron.2015.08.030     Document Type: Article

References (43)

1. Ackman J.B., Burbridge T.J., Crair M.C. Retinal waves coordinate patterned activity throughout the developing visual system. Nature 2012, 490:219-225.
2. Bevins N., Lemke G., Reber M. Genetic dissection of EphA receptor signaling dynamics during retinotopic mapping. J. Neurosci. 2011, 31:10302-10310.
3. Brown A., Yates P.A., Burrola P., Ortuño D., Vaidya A., Jessell T.M., Pfaff S.L., O'Leary D.D., Lemke G. Topographic mapping from the retina to the midbrain is controlled by relative but not absolute levels of EphA receptor signaling. Cell 2000, 102:77-88.
4. Cang J., Feldheim D.A. Developmental mechanisms of topographic map formation and alignment. Annu. Rev. Neurosci. 2013, 36:51-77.
5. Cang J., Kaneko M., Yamada J., Woods G., Stryker M.P., Feldheim D.A. Ephrin-as guide the formation of functional maps in the visual cortex. Neuron 2005, 48:577-589.
6. Cang J., Rentería R.C., Kaneko M., Liu X., Copenhagen D.R., Stryker M.P. Development of precise maps in visual cortex requires patterned spontaneous activity in the retina. Neuron 2005, 48:797-809.
7. Cang J., Niell C.M., Liu X., Pfeiffenberger C., Feldheim D.A., Stryker M.P. Selective disruption of one Cartesian axis of cortical maps and receptive fields by deficiency in ephrin-As and structured activity. Neuron 2008, 57:511-523.
8. Cang J., Wang L., Stryker M.P., Feldheim D.A. Roles of ephrin-as and structured activity in the development of functional maps in the superior colliculus. J. Neurosci. 2008, 28:11015-11023.
9. Chandrasekaran A.R., Plas D.T., Gonzalez E., Crair M.C. Evidence for an instructive role of retinal activity in retinotopic map refinement in the superior colliculus of the mouse. J. Neurosci. 2005, 25:6929-6938.
10. Feinberg E.H., Meister M. Orientation columns in the mouse superior colliculus. Nature 2015, 519:229-232.
11. Feldheim D.A., Kim Y.I., Bergemann A.D., Frisén J., Barbacid M., Flanagan J.G. Genetic analysis of ephrin-A2 and ephrin-A5 shows their requirement in multiple aspects of retinocollicular mapping. Neuron 2000, 25:563-574.
12. Frisén J., Yates P.A., McLaughlin T., Friedman G.C., O'Leary D.D., Barbacid M. Ephrin-A5 (AL-1/RAGS) is essential for proper retinal axon guidance and topographic mapping in the mammalian visual system. Neuron 1998, 20:235-243.
13. Gaze R.M. Growth and the Development of Pattern 1981, Company of Biologists, Cambridge University Press.
14. Golding B., Pouchelon G., Bellone C., Murthy S., Di Nardo A.A., Govindan S., Ogawa M., Shimogori T., Lüscher C., Dayer A., Jabaudon D. Retinal input directs the recruitment of inhibitory interneurons into thalamic visual circuits. Neuron 2014, 81:1057-1069.
15. Grimbert F., Cang J. New model of retinocollicular mapping predicts the mechanisms of axonal competition and explains the role of reverse molecular signaling during development. J. Neurosci. 2012, 32:9755-9768.
16. Grubb M.S., Rossi F.M., Changeux J.-P., Thompson I.D. Abnormal functional organization in the dorsal lateral geniculate nucleus of mice lacking the beta 2 subunit of the nicotinic acetylcholine receptor. Neuron 2003, 40:1161-1172.
17. Hickey T.L., Guillery R.W. Variability of laminar patterns in the human lateral geniculate nucleus. J. Comp. Neurol. 1979, 183:221-246.
18. Huberman A.D., Stellwagen D., Chapman B. Decoupling eye-specific segregation from lamination in the lateral geniculate nucleus. J. Neurosci. 2002, 22:9419-9429.
19. Kaas J.H., Guillery R.W. The transfer of abnormal visual field representations from the dorsal lateral geniculate nucleus to the visual cortex in Siamese cats. Brain Res. 1973, 59:61-95.
20. Kaas J.H., Huerta M.F., Weber J.T., Harting J.K. Patterns of retinal terminations and laminar organization of the lateral geniculate nucleus of primates. J. Comp. Neurol. 1978, 182:517-553.
21. Kalatsky V.A., Stryker M.P. New paradigm for optical imaging: temporally encoded maps of intrinsic signal. Neuron 2003, 38:529-545.
22. Koulakov A.A., Tsigankov D.N. A stochastic model for retinocollicular map development. BMC Neurosci. 2004, 5:30.
23. Lee D., Malpeli J.G. Global form and singularity: modeling the blind spot's role in lateral geniculate morphogenesis. Science 1994, 263:1292-1294.
24. Lim Y.-S., McLaughlin T., Sung T.-C., Santiago A., Lee K.-F., O'Leary D.D.M. p75(NTR) mediates ephrin-A reverse signaling required for axon repulsion and mapping. Neuron 2008, 59:746-758.
25. McLaughlin T., Torborg C.L., Feller M.B., O'Leary D.D.M. Retinotopic map refinement requires spontaneous retinal waves during a brief critical period of development. Neuron 2003, 40:1147-1160.
26. Meister M., Wong R.O., Baylor D.A., Shatz C.J. Synchronous bursts of action potentials in ganglion cells of the developing mammalian retina. Science 1991, 252:939-943.
27. Nicol X., Voyatzis S., Muzerelle A., Narboux-Nême N., Südhof T.C., Miles R., Gaspar P. cAMP oscillations and retinal activity are permissive for ephrin signaling during the establishment of the retinotopic map. Nat. Neurosci. 2007, 10:340-347.
28. Pfeiffenberger C., Cutforth T., Woods G., Yamada J., Rentería R.C., Copenhagen D.R., Flanagan J.G., Feldheim D.A. Ephrin-As and neural activity are required for eye-specific patterning during retinogeniculate mapping. Nat. Neurosci. 2005, 8:1022-1027.
29. Pfeiffenberger C., Yamada J., Feldheim D.A. Ephrin-As and patterned retinal activity act together in the development of topographic maps in the primary visual system. J. Neurosci. 2006, 26:12873-12884.
30. Rashid T., Upton A.L., Blentic A., Ciossek T., Knöll B., Thompson I.D., Drescher U. Opposing gradients of ephrin-As and EphA7 in the superior colliculus are essential for topographic mapping in the mammalian visual system. Neuron 2005, 47:57-69.
31. Reber M., Burrola P., Lemke G. A relative signalling model for the formation of a topographic neural map. Nature 2004, 431:847-853.
32. Simon D.K., O'Leary D.D. Development of topographic order in the mammalian retinocollicular projection. J. Neurosci. 1992, 12:1212-1232.
33. Stafford B.K., Sher A., Litke A.M., Feldheim D.A. Spatial-temporal patterns of retinal waves underlying activity-dependent refinement of retinofugal projections. Neuron 2009, 64:200-212.
34. Stryker M.P. Precise development from imprecise rules. Science 1994, 263:1244-1245.
35. Suetterlin P., Drescher U. Target-independent ephrina/EphA-mediated axon-axon repulsion as a novel element in retinocollicular mapping. Neuron 2014, 84:740-752.
36. Triplett J.W. Molecular guidance of retinotopic map development in the midbrain. Curr. Opin. Neurobiol. 2014, 24:7-12.
37. Triplett J.W., Owens M.T., Yamada J., Lemke G., Cang J., Stryker M.P., Feldheim D.A. Retinal input instructs alignment of visual topographic maps. Cell 2009, 139:175-185.
38. Triplett J.W., Pfeiffenberger C., Yamada J., Stafford B.K., Sweeney N.T., Litke A.M., Sher A., Koulakov A.A., Feldheim D.A. Competition is a driving force in topographic mapping. Proc. Natl. Acad. Sci. USA 2011, 108:19060-19065.
39. Triplett J.W., Wei W., Gonzalez C., Sweeney N.T., Huberman A.D., Feller M.B., Feldheim D.A. Dendritic and axonal targeting patterns of a genetically-specified class of retinal ganglion cells that participate in image-forming circuits. Neural Dev. 2014, 9:2.
40. Tsigankov D.N., Koulakov A.A. A unifying model for activity-dependent and activity-independent mechanisms predicts complete structure of topographic maps in ephrin-A deficient mice. J. Comput. Neurosci. 2006, 21:101-114.
41. Tsigankov D., Koulakov A.A. Sperry versus Hebb: topographic mapping in Isl2/EphA3 mutant mice. BMC Neurosci. 2010, 11:155.
42. Xu W., Orr-Urtreger A., Nigro F., Gelber S., Sutcliffe C.B., Armstrong D., Patrick J.W., Role L.W., Beaudet A.L., De Biasi M. Multiorgan autonomic dysfunction in mice lacking the beta2 and the beta4 subunits of neuronal nicotinic acetylcholine receptors. J. Neurosci. 1999, 19:9298-9305.
43. Yates P.A., Roskies A.L., McLaughlin T., O'Leary D.D. Topographic-specific axon branching controlled by ephrin-As is the critical event in retinotectal map development. J. Neurosci. 2001, 21:8548-8563.