Jörg Mey

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

After transection of the optic nerve (ON) in adult rats, retinal ganglion cells (RGC) progressively degenerate until, after two months, a residual population of only about 5% of these cells survives. In this study, we investigated the effect of regeneration-associated factors from sciatic nerve (ScN), BDNF, and CNTF on the survival of adult rat RGC after intraorbital ON transection. Neurotrophic factors were injected into the vitreous body. Rats were allowed to survive 3, 5, or 7 weeks, and the remaining viable RGC were then labelled by retrograde staining with the carbocyanine dye, 4Di-10Asp, which was applied onto the proximal nerve stump in vivo. The animals were sacrificed 3 days later and RGC counted in retinal whole mounts. Due to progressive degeneration following nerve transection the number of surviving RGC decreased to about 10% of the initially labelled population after 3 weeks, to about 8% after 5 weeks, and to about 5% after 7 weeks. Survival of axotomized cells could be prolonged using either of the neurotrophic factors: after 3 weeks a 2-3-fold increase in the number of viable RGC could be obtained compared to uninjected controls and to those which received injection of buffer. The prolonged survival effect vanished after 5 and 7 weeks, and no additive effect could be seen when combining brain-derived neurotrophic factor (BDNF) and ciliary neuronotrophic factor (CNTF) treatment. Morphometric analysis of labelled cells revealed that all neurotrophic factors supported predominantly large RGC with somal areas > 250 micron 2. In retinae from rats that survived the ON transection for several months, a characteristic population of axotomy-resistant RGC remained alive. Their few, very large, and often curled dendrites showed signs of placticity in the depleted inner nuclear layer of the adult rat retina. We conclude that the intraocular injection of CNTF, BDNF, and ScN-derived medium, which retard the process of lesion-induced RGC degeneration, may be successfully used as a subsidiary strategy in transplatation protocols. This would result in larger populations of RGC which can be recruited to regenerate their axons and provide a basis for functional recovery.

Current concepts in neuroanatomical tracing.

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 ever-increasing number of fluorescent 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 fluorescent 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.

Retinoic Acid Signaling in the Nervous System of Adult Vertebrates

The majority of the functions of vitamin A are carried out by its metabolite, retinoic acid (RA), a potent transcriptional activator acting through members of the nuclear receptor family of transcription factors. In the CNS, RA was first recognized to be essential for the control of patterning and differentiation in the developing embryo. It has recently come to light, however, that many of the same functions that RA directs in the embryo are involved in the regulation of plasticity and regeneration in the adult brain. The same intricate metabolic control system of synthetic and catabolic enzymes, combined with cytoplasmic binding proteins, is used in both embryo and adult to create regions of high and low RA to modulate gene transcription. This review summarizes some of the discoveries in the new field of retinoid neurobiology including its functions in neural plasticity and LTP in the hippocampus; its possible role in motor disorders such as Parkinson’s disease, motoneuron disease, and Huntington’s disease; its role in regeneration after sciatic nerve and spinal cord injury; and its possible involvement in psychiatric diseases such as depression.

Oestrogen and progesterone reduce lipopolysaccharide-induced expression of tumour necrosis factor-alpha and interleukin-18 in midbrain astrocytes.

Besides microglia, astrocytes exert an important regulatory function in the initiation and control of neuro‐inflammatory processes in the central nervous system. Clinical and experimental data suggest that sex steroids are neuroprotective and that neurological/neurodegenerative disorders display sex‐specific characteristics. Astroglia is known to respond to toxic stimuli by secretion of distinct pro‐inflammatory/apoptotic cytokines. In the present study, we investigated the influence of oestrogen and progesterone on the expression of the cytokines tumour necrosis factor (TNF)‐α and interleukin (IL)‐18 in primary astrocytes obtained from neonatal mouse midbrain and cerebral cortex after the stimulation with lipopolysaccharides (LPS). LPS strongly induced the expression of TNF‐α in astrocytes from both brain regions and IL‐18 in those from midbrain. Oestrogen significantly attenuated LPS‐induced TNF‐α expression in the midbrain glia but not in the cortex glia. Combined treatment with oestrogen and progesterone together diminished LPS‐induced IL‐18 expression in the midbrain completely. Both steroid effects could be specifically antagonised by the steroid hormone receptor antagonists ICI 182 780 and mifepristone. We conclude that neuroprotective oestrogen and progesterone effects in the midbrain might be in part the consequence of a reduced pro‐inflammatory response of astroglia.

RAR/RXR and PPAR/RXR signaling in neurological and psychiatric diseases.

Retinoids are important signals in brain development. They regulate gene transcription by binding to retinoic acid receptors (RAR) and, as was discovered recently, a peroxisome proliferator-activated receptor (PPAR). Traditional ligands of PPAR are best known for their functions in lipid metabolism and inflammation. RAR and PPAR are ligand-activated transcription factors, which share members of the retinoid X receptor (RXR) family as heterodimeric partners. Both signal transduction pathways have recently been implicated in the progression of neurodegenerative and psychiatric diseases. Since inflammatory processes contribute to various neurodegenerative diseases, the anti-inflammatory activity of retinoids and PPARgamma agonists recommends them as potential therapeutic targets. In addition, genetic linkage studies, transgenic mouse models and experiments with vitamin A deprivation provide evidence that retinoic acid signaling is directly involved in physiology and pathology of motoneurons, of the basal ganglia and of cognitive functions. The activation of PPAR/RXR and RAR/RXR transcription factors has therefore been proposed as a therapeutic strategy in disorders of the central nervous system.

Inflammatory cytokine release of astrocytes in vitro is reduced by all-trans retinoic acid

In the central nervous system inflammation is mediated by microglia and astrocytes. To investigate its regulation, murine astrocyte cultures were treated with bacterial lipopolysaccharides (LPS) and analyzed with Affymetrix gene array, qRT-PCR and ELISA. Cells responded to LPS with a strong upregulation of pro-inflammatory cytokines and chemokines. Treatment with the transcriptional activator retinoic acid (RA) suppressed mRNA expression and protein release of several important cytokines (IL-1β 4%, IL-6 21%, TNFα 30%, IL-12p40 42%, and IL-12p35/p40 27%; p<0.01). The data are consistent with the hypothesis that all-trans RA takes part in endogenous anti-inflammatory feedback loops in the CNS.

Activation of retinoic acid signalling after sciatic nerve injury: up-regulation of cellular retinoid binding proteins

In mammalian peripheral nerves a crush lesion causes interactions between injured neurons, Schwann cells and haematogenous macrophages that can lead to successful axonal regeneration. We suggest that the transcriptional activator retinoic acid (RA), takes part in gene regulation after peripheral nerve injury and that RA signalling is activated via the cellular retinoic acid binding protein (CRABP)‐II and cellular retinol binding protein (CRBP)‐I. With RT‐PCR and immunoblotting all necessary components of the RA signalling pathway were detected in the sciatic nerve of adult rats. These are retinoic acid receptors, retinoid X receptors, the retinoic acid synthesizing enzymes RALDH‐1, RALDH‐2, and RALDH‐3, in addition, the cellular retinoid binding proteins CRBP‐I, CRABP‐I and CRABP‐II. Enzyme activity of RALDH‐2 was detectable in the nerve, and using a transgenic reporter mouse we found local activation of RA responsive elements in the regenerating nerve. Sciatic nerve crush as well as transection resulted in a more than 10‐fold up‐regulation of CRBP‐I, which is thought to facilitate the synthesis of RA. Both kinds of injury also caused a 15‐fold increase in transcript and protein concentration of CRABP‐II, a possible mediator of RA transfer to its nuclear receptors.

Expression of Enzymes Involved in the Prostanoid Metabolism by Cortical Astrocytes after LPS- induced Inflammation

Neuroinflammatory processes are a common epiphenomenon for a number of neurological and neurodegenerative diseases. Besides microglia, astrocytes are implicated in brain inflammation in response to harmful stimuli and pathological processes. Bacterial endotoxins can induce the synthesis and release of proinflammatory mediators, i.e., cytokines and chemokines, by astroglia. In this study, we have investigated the effect of lipopolysaccharide (LPS) treatment on the expression of enzymes of prostanoid synthesis and degradation in cultured mouse cortical astrocytes using an Affymetrix Gene Chip array, quantitative reverse transcriptase polymerase chain reaction (RT-PCR), and an enzyme-immunosorbent assay. LPS treatment induced an upregulation of enzymes responsible for prostaglandin E2 synthesis, a downregulation of enzymes that catalyzes prostaglandin E2 (PGE2) degradation and production of proinflammatory leukotrienes. Changes in enzyme expression were accompanied by a highly significant increase in extracellular PGE2. Our data demonstrate that astrocytes are directly involved in the complex regulation of proinflammatory prostanoids in the CNS under pathological processes, thus being of potential interest as targets for therapeutical interventions. Further studies are required to unravel the different roles and interactions between astroglia and other cells of the brain-intrinsic innate immune system during inflammation.

Retinoic acid synthesis by a population of NG2-positive cells in the injured spinal cord

Retinoic acid (RA) promotes growth and differentiation in many developing tissues but less is known about its influence on CNS regeneration. We investigated the possible involvement of RA in rat spinal cord injury (SCI) using the New York University (NYU) impactor to induce mild or moderate spinal cord contusion injury. Changes in RA at the lesion site were determined by measuring the activity of the enzymes for its synthesis, the retinaldehyde dehydrogenases (RALDHs). A marked increase in enzyme activity occurred by day 4 and peaked at days 8–14 following the injuries. RALDH2 was the only detectable RALDH present in the control or injured spinal cord. The cellular localization of RALDH2 was identified by immunostaining. In the noninjured spinal cord, RALDH2 was detected in oligodendroglia positive for the markers RIP and CNPase. Expression was also intense in the arachnoid membrane surrounding the spinal cord. After SCI the increase in RALDH2 was independent of the RIP‐ and CNPase‐positive cells, which were severely depleted. Instead, RALDH2 was present in a cell type not previously identified as capable of synthesizing RA, that expressed NG2 and that was negative for markers of astrocytes, oligodendroglia, microglia, neurons, Schwann cells and immature lymphocytes. We postulate that the RALDH2‐ and NG2‐positive cells migrate into the injured sites from the adjacent arachnoid membrane, where the RALDH2‐positive cells proliferate substantially following SCI. These findings indicate that close correlations exist between RA synthesis and SCI and that RA may play a role in the secondary events that follow acute SCI.

Sources and sink of retinoic acid in the embryonic chick retina: distribution of aldehyde dehydrogenase activities, CRABP-I, and sites of retinoic acid inactivation

Previous experiments in mice and zebrafish led to the hypothesis that an asymmetric distribution of the transcriptional activator retinoic acid (RA) causes ventral-dorsal polarity in the vertebrate eye anlage. A high concentration of RA in the ventral retinal neuroepithelium has been suggested to induce developmental events that finally establish topographic order in the retinotectal projection along the vertical eye axis. In the present study we have investigated potential sources and sinks of RA during embryonic development of the chick retina. At embryonic day (E)1 to E2, when the spatial determination of the eye primordia takes place, no RA synthesis by aldehyde dehydrogenases was detectable, and neither immunoreactivity for retinaldehyde dehydrogenase RALDH-2 nor for cellular retinoic acid binding protein CRABP-I was observed. These components of RA signal transduction appeared in the eye between E3 and E5. At later stages, RA-measurements with a reporter cell line showed highest synthesis in the retinal pigment epithelium (RPE) and at the ventral and dorsal poles of the retina. RA degradation occurred mostly in a horizontal region in the middle of the retina with only small differences along the nasal-temporal axis. CRABP-I immunoreactivity appeared first in differentiating retinal ganglion cells with no indication of a spatial gradient across the ventral-dorsal eye axis. RA-production depended on three NAD+-dependent enzyme activities, which could be competitively inhibited by citral. One enzyme, located in the dorsal retina (corresponding to mouse RALDH-1), and one enzyme in the RPE (RALDH-2) were aldehyde dehydrogenases of the same molecular weight (monomers about 55 kDa) but with different isoelectric points (6.5-6.9; 4.9-5.4). The third RA-synthesizing activity (pI 6.0-6.3) was limited to the ventral retina, and likely corresponded to mouse RALDH-3. The restricted localization of retinoid-metabolizing activities along the dorsal-ventral axis of the embryonic chick retina does support the idea that RA is involved in dorsal-ventral eye patterning. However, the late time of appearance of aldehyde dehydrogenase activities and CRABP-I points to functions in cellular differentiation that are distinct from the initiation of the dorsal-ventral polarity.