Solon Thanos scite author profile

The development of new axonal tract tracing and cell labelling methods has revolutionised neurobiology in the last 30 years. The aim of this review is to consider some of the key methods of neuroanatomical tracing that are currently in use and have proved invaluable in charting the complex interconnections of the central nervous system. The review begins with a short overview of the most frequently used tracers, including enzymes, peptides, biocytin, latex beads, plant lectins and the everincreasing number of¯uorescent dyes. This is followed by a more detailed consideration of both well established and more recently introduced neuroanatomical tracing methods. Technical aspects of the application, uptake mechanisms, intracellular transport of tracers, and the problems of subsequent signal detection, are also discussed. The methods that are presented and discussed in detail include: (1) anterograde and retrograde neuroanatomical labelling with¯uorescent dyes in vivo, (2) labelling of post mortem tissue, (3) developmental studies, (4) transcellular tracing (phagocytosis-dependent staining of glial cells), (5) electrophysiological mapping combined with neuronal tract tracing, and (6) simultaneous detection of more than one axonal tracer. (7) Versatile protocols for three-colour labelling have been developed to study complex patterns of connections. It is envisaged that this review will be used to guide the readers in their selection of the most appropriate techniques to apply to their own particular area of interest. 7

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Intravitreal injections of neurotrophic factors support the survival of axotomized retinal ganglion cells in adult rats in vivo

Mey

1993

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Axonal regeneration and synapse formation in the superior colliculus by retinal ganglion cells in the adult rat

Vidal‐Sanz¹,

Bray²,

et al. 1987

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In adult rats, one optic nerve was transected and replaced by a 4 cm segment of autologous peripheral nerve (PN) that linked one eye and the superior colliculus (SC) along a predominantly extracranial course. Retrograde and orthograde studies with the tracers HRP or rhodamine-B- isothiocyanate (RITC), as well as immunocytochemical neuronal labels, indicated the following: (1) Regenerating axons from the axotomized retinal ganglion cells extended along the entire PN grafts, covering a distance nearly twice that of the normal retinotectal projection of intact rats. (2) Some of these axons penetrated the SC and formed terminal arborizations up to 500 microns from the end of the graft. (3) By electron microscopy, the arborizations of these regenerated axons in the SC were seen as small HRP-labeled axonal profiles that contacted neuronal processes in the SC; some of these contacts showed pre- and postsynaptic membrane specializations. These findings indicate that injured retinal ganglion cells in the adult rat are not only able to regrow lengthy axons, but may also form synapses in the SC.

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Switching Mature Retinal Ganglion Cells to a Robust Growth StateIn Vivo: Gene Expression and Synergy with RhoA Inactivation

Fischer¹,

Petkova²,

Thanos³

et al. 2004

J. Neurosci.

257

221

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The inability of mature CNS neurons to regenerate injured axons has been attributed to a loss of inherent growth potential of cells and to inhibitory signals associated with myelin and the glial scar. The present study investigated two complementary issues: (1) whether mature CNS neurons can be stimulated to alter their gene expression profile and switch into a strong growth state; and (2) whether inactivating RhoA, a convergence point for multiple inhibitory signals, is sufficient to produce strong regeneration even without activating the growth state of neurons. In the mature rat, retinal ganglion cells (RGCs) normally fail to regenerate axons through the injured optic nerve but can be stimulated to do so by activating macrophages in the eye (e.g., by lens injury). To investigate underlying changes in gene expression, we retrogradely labeled RGCs with a fluorescent dye, performed optic nerve surgery with or without lens injury, and 4 d later, dissociated retinas, isolated RGCs by fluorescence-activated cell sorting, and examined their profiles of gene expression using microarrays. To investigate the effects of inactivating RhoA, we transfected RGCs with adeno-associated viruses carrying a gene for C3 ribosyltransferase. Our results show that, with appropriate stimulation, mature CNS neurons can undergo dramatic changes in gene expression comparable with those seen in regenerating neurons of the PNS, and that RhoA inactivation by itself results in moderate regeneration, and strongly potentiates axon regeneration through the mature optic nerve when the growth state of neurons is activated.

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Treatment of the adult retina with microglia-suppressing factors retards axotomy-induced neuronal degradation and enhances axonal regeneration in vivo and in vitro

1993

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To monitor the cascade of events initiated by injury of adult neurons, and to explore whether and how neighboring microglial cells contribute to the degradation of lesioned neurons, axotomy-induced ganglion cell degeneration was investigated in adult rats. Suppression of macrophage and microglia activity during the weeks following transection of the optic nerve was performed with the immunoglobulin-derived tripeptide Thr-Lys-Pro, which is a macrophage inhibitory factor (MIF) and retards the activity of cells of monocytic origin. Single or repeated injection of MIF into the vitreous body during and after transection of the optic nerve resulted in significant retardation of axotomy-induced ganglion cell degradation in the retina as detected by specific labeling with the retrogradely transported fluorescent dye 4Di-10ASP. MIF specifically altered the morphology of labeled microglial cells from a ramified to an oval, less ramified shape, indicating that these cells were targets of its activity. Injection of the tetrapeptide macrophage stimulating factor, also known as tuftsin (Thr-Lys-Pro-Arg), revealed effects opposite to those described for the MIF: it increased the number of labeled microglial cells and enhanced the devastating effects of axotomy on ganglion cells. The viability of rescued ganglion cells in retinas treated with the various drugs was assessed both in vivo and in vitro. (1) Intravitreal injection of MIF to prevent degradation of neurons combined with transplantation of autologous peripheral nerve grafts, which facilitate regrowth of the transected neurites, revealed that significantly more ganglion cells contributed to axonal regeneration (17.1%) than in untreated controls (9.5%). (2) Explantation of retinas that were pretreated with MIF in situ revealed higher incidence of axonal outgrowth in organ cultures than untreated control explants or retinas treated with either the basic fibroblast growth factor or brain-derived neurotrophic factor. The present results demonstrate that axotomy initializes a cascade of microglia-mediated autodestructive retinal responses, which culminate in degradation of "sick," but obviously viable neurons. We postulate that the retinal microglial system has a key role in recognizing and eliminating severed neurons.

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Solon Thanos

Current concepts in neuroanatomical tracing

Intravitreal injections of neurotrophic factors support the survival of axotomized retinal ganglion cells in adult rats in vivo

Axonal regeneration and synapse formation in the superior colliculus by retinal ganglion cells in the adult rat

Switching Mature Retinal Ganglion Cells to a Robust Growth StateIn Vivo: Gene Expression and Synergy with RhoA Inactivation

Treatment of the adult retina with microglia-suppressing factors retards axotomy-induced neuronal degradation and enhances axonal regeneration in vivo and in vitro

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