Slit Proteins Regulate Distinct Aspects of Retinal Ganglion Cell Axon Guidance within Dorsal and Ventral Retina

Thompson, Hannah; Camand, Olivier; Barker, David; Erskine, Lynda

doi:10.1523/jneurosci.1342-06.2006

Cited by 63 publications

(89 citation statements)

References 59 publications

(85 reference statements)

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“…There are multiple factors known to be involved in intraretinal axon pathfinding, including netrin-1, slit, and sonic hedgehog (Deiner et al, 1997;Kolpak et al, 2005;Thompson et al, 2006). These factors comprise an expanding group of molecular cues known to be responsible for the guidance of RGC axons along the optic fiber layer, toward the optic disc and out of the retina.…”

Section: Retinal Expression Of Sema3smentioning

confidence: 99%

Expression of multiple class three semaphorins in the retina and along the path of zebrafish retinal axons

Callander

Lamont

Childs

et al. 2007

Developmental Dynamics

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Retinal ganglion cells (RGCs) extend axons that exit the eye, cross the midline at the optic chiasm, and synapse on target cells in the optic tectum. Class three semaphorins (Sema3s) are a family of molecules known to direct axon growth. We undertook an expression screen to identify sema3s expressed in the retina and/or brain close to in-growing RGC axons, which might therefore influence retinal-tectal pathfinding. We find that sema3Aa, 3Fa, 3Ga, and 3Gb are expressed in the retina, although only sema3Fa is present during the time window when the axons extend. Also, we show that sema3Aa and sema3E are present near or at the optic chiasm. Furthermore, sema3C, 3Fa, 3Ga, and 3Gb are expressed in regions of the diencephalon near the path taken by RGC axons. Finally, the optic tectum expresses sema3Aa, 3Fa, 3Fb, and 3Gb. Thus, sema3s are spatiotemporally placed to influence RGC axon growth. Developmental Dynamics 236:2918 -2924, 2007.

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Section: Retinal Expression Of Sema3smentioning

confidence: 99%

Expression of multiple class three semaphorins in the retina and along the path of zebrafish retinal axons

Callander

Lamont

Childs

et al. 2007

Developmental Dynamics

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“…The results suggest that Slit1 and Slit2 cooperate to maintain RGC axons in the inner surface of the retina. Strikingly, ectopic RGC axon bundles appear to form preferentially (greater than a 2:1 ratio) in the ventral rather than the dorsal part of the retina [Thompson et al (2006a), their Fig. 3 A, Ϫ/Ϫ and slit1/2 Ϫ/Ϫ organs were intermingled.…”

mentioning

confidence: 92%

“…In 1963, Roger Wolcott Sperry performed his eyeball rotation experiment, still taught to almost every student of neuroscience and developmental biology, which showed that growing axons are guided by chemical factors in their environment. Sperry's (1963) chemoaffinity hypothesis spurred a series of studies to investigate the role of axon guidance molecules in the development of the visual system, including the one that is the focus of a recent article in the Journal of Neuroscience by Thompson et al (2006a). The authors addressed the role of Slit proteins in intraretinal axon guidance, the mechanisms by which axons growing from retinal ganglion cells (RGCs) form a layer at the internal surface of the retina, converging toward the optic disc.…”

mentioning

confidence: 99%

“…Previous studies using in situ hybridization, a technique that allows identification of Slit expression in cell bodies but not fibers (the vast majority of mRNAs being restricted to the soma), demonstrated that both genes are expressed in the RGC layer of the retina (Erskine et al, 2000), but the identity of the expressing cells was not clear. The observation that GFP immunoreactivity is evident all along the RGC axon paths [Thompson et al (2006a) performed GFP-staining on longitudinal and transversal sections of retinas obtained from slit1-and slit2-deficient animals and analyzed them by confocal microscopy. Interestingly, they identified two distinct defects in these sections (Fig.…”

mentioning

confidence: 99%

“…jneurosci.org/cgi/content/full/26/31/ 8082/F2), 3 (http://www.jneurosci.org/ cgi/content/full/26/31/8082/F3)] consists of the occurrence of thick bundles of RGC axons mislocalized to the outer layers of the retina, opposite to the inner surface were RGC axons normally navigate. The defect is virtually absent from both wild-type and slit1 Ϫ/Ϫ retinas, but occurs with moderate (an average of five bundles per retina) and high frequency (over thirty bundles) in slit2 Ϫ/Ϫ and slit1/2 doublemutant retinas, respectively [Thompson et al (2006a), their Fig. 3C (http://www.…”

mentioning

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Differential Role of Slits in Dorsal versus Ventral Retinal Axon Guidance: Figure 1.

Causeret

2006

J. Neurosci.

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Editor's Note: These short reviews of a recent paper in the Journal, written exclusively by graduate students or postdoctoral fellows, are intended to mimic the journal clubs that exist in your own departments or institutions. For more information on the format and purpose of the Journal Club, please see http://www.jneurosci.org/misc/ifa_features.shtml. The establishment of accurate projections is essential to the precise functioning of neuronal structures. Furthermore, the acquisition of appropriate wiring patterns by neurons in sensory systems ensures the viability of the entire organism. Partly for this reason, the retina has, for over a century, grabbed the attention of well known scientists. Santiago Ramó n y Cajal's (1911) pioneering work provided precise anatomical descriptions of the architecture of the retina, leading him to propose hypotheses about its function. In 1963, Roger Wolcott Sperry performed his eyeball rotation experiment, still taught to almost every student of neuroscience and developmental biology, which showed that growing axons are guided by chemical factors in their environment. Sperry's (1963) chemoaffinity hypothesis spurred a series of studies to investigate the role of axon guidance molecules in the development of the visual system, including the one that is the focus of a recent article in the Journal of Neuroscience by Thompson et al. (2006a). The authors addressed the role of Slit proteins in intraretinal axon guidance, the mechanisms by which axons growing from retinal ganglion cells (RGCs) form a layer at the internal surface of the retina, converging toward the optic disc. These projections then exit the retina to form the optic nerve. The pathfinding process of RGC axons is essential to the development of the visual system as defects in the internal organization of the retina affect the proper functioning of the eye. The authors focused on Slit1 and Slit2, two secreted proteins whose role as chemorepellents and growth inhibitors is well documented in different axonguidance systems. In particular, they took advantage of the availability of slit1-and slit2-deficient mice (Plump et al., 2002) to analyze the effects of the loss of these molecules on the establishment of retinal architecture. Differential Role of Slits in Dorsal versus Ventral Retinal Axon GuidanceMutant mice were designed to express tau-green fluorescent protein (GFP) under the control of the endogenous slit1 or slit2 promoters, so that any cell that would normally express slit mRNA would express GFP in cell bodies and processes. Previous studies using in situ hybridization, a technique that allows identification of Slit expression in cell bodies but not fibers (the vast majority of mRNAs being restricted to the soma), demonstrated that both genes are expressed in the RGC layer of the retina (Erskine et al., 2000), but the identity of the expressing cells was not clear. The observation that GFP immunoreactivity is evident all along the RGC axon paths [Thompson et al. (2006a) performed GFP-staining on longitudi...

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Visual System Development in Vertebrates

Johnson

Shewan

Holt

2013

Encyclopedia of Life Sciences

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The development of a functional visual system involves a complex series of inductive and signalling interactions essential for the formation of the eye and its central connections with the brain. Outpouchings from the forebrain, together with the overlying surface ectoderm and neural crest cells give rise to the major structures of the eye (neural retina, pigmented epithelium, lens and cornea). Central connections between the eye and brain regions that receive direct connections from the eye (visual targets) are formed by the axons of retinal ganglion cells. Attractive and repulsive cues in the extracellular environment guide the retinal axon along specific pathways in the brain. Gradients of signalling molecules, together with spontaneous neural activity, drive a point‐to‐point mapping of retinal axons in visual targets, ensuring accurate reconstruction of the visual image. The cellular, molecular and inductive mechanisms that sculpt each of these key developmental processes essential for normal visual system development are beginning to be understood. Key Concepts: The eye primordia (optic cups) develop as outgrowths from the forebrain. Contact of the optic cup with the overlying surface ectoderm induces formation of the lens. Signals from the lens induce the formation of the cornea. Retinal cells differentiate into overlapping central–peripheral waves to form three layers of cell bodies separated by two plexiform (synaptic) layers. Inhibitory signalling and local adhesive interactions control synaptic specificity in the retina. Attractive and repulsive signals in the extracellular environment direct growth of retinal axons to target regions in the brain. Retinal axons map topographically in target regions of the brain. Map formation is controlled through the graded action of repulsive signalling molecules and spontaneous retinal activity. Activity‐dependent mechanisms drive the formation of eye‐specific layering of synaptic inputs in visual targets.

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Slit Proteins Regulate Distinct Aspects of Retinal Ganglion Cell Axon Guidance within Dorsal and Ventral Retina

Cited by 63 publications

References 59 publications

Expression of multiple class three semaphorins in the retina and along the path of zebrafish retinal axons

Expression of multiple class three semaphorins in the retina and along the path of zebrafish retinal axons

Differential Role of Slits in Dorsal versus Ventral Retinal Axon Guidance: Figure 1.

Visual System Development in Vertebrates

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