Axonal degeneration is an initial key step in traumatic and neurodegenerative CNS disorders. We established a unique in vivo epifluorescence imaging paradigm to characterize very early events in axonal degeneration in the rat optic nerve. Single retinal ganglion cell axons were visualized by AAV-mediated expression of dsRed and this allowed the quantification of postlesional acute axonal degeneration (AAD). EM analysis revealed severe structural alterations of the cytoskeleton, cytoplasmatic vacuolization, and the appearance of autophagosomes within the first hours after lesion. Inhibition of autophagy resulted in an attenuation of acute axonal degeneration. Furthermore, a rapid increase of intraaxonal calcium levels following crush lesion could be visualized using a calciumsensitive dye. Application of calcium channel inhibitors prevented crush-induced calcium increase and markedly attenuated axonal degeneration, whereas application of a calcium ionophore aggravated the degenerative phenotype. We finally demonstrate that increased postlesional autophagy is calcium dependent and thus mechanistically link autophagy and intraaxonal calcium levels. Both processes are proposed to be major targets for the manipulation of axonal degeneration in future therapeutic settings.CNS trauma | live imaging | calcium influx | autophagy A xonal degeneration plays a pivotal role in the pathogenesis of numerous neurological disorders frequently preceding neuronal cell death and resulting in persistent functional disability. Traumatic spinal cord or peripheral nerve injury represent classical conditions where mechanical disruption of axonal integrity results in nervous system dysfunction (1, 2). Several degenerative CNS diseases show prominent axonal pathology already early in the disease course, such as the degeneration of nigrostriatal projection tracts or cardiac sympathetic nerves in Parkinson's disease (3) or corticospinal tracts in amyotrophic lateral sclerosis (4). Key features of axonal degeneration seem to be similar despite variable etiology. The distal part of the lesioned axon undergoes Wallerian degeneration (WD) characterized by initial axonal stability followed by rapid degeneration, fragmentation, and blebbing of the remaining axon, microtubule disassembly, and phagocytic clearance of the lesion site. The proximal part was reported to remain more stable than its distal counterpart (5-8), but imaging of the spinal cord in vivo visualized mechanisms of acute axonal degeneration (AAD) within the first minutes after lesion. In contrast to WD, AAD results in sudden axonal disintegration and extended for ≈300 μm proximal and distal to the lesion (9). One of the putative initiating steps in axonal degeneration is the influx of extracellular calcium, which is suggested to destabilize the axon and to transmit apoptotic signals to the neuronal soma (10-12).The optic nerve (ON) represents a unique model system for the study of axonal pathology in the CNS because of its accessibility and the possibility to manipulate the system...
Human toll-like receptor 8 (TLR8) activation induces a potent T helper-1 (Th1) cell response critical for defense against intracellular pathogens, including protozoa. The receptor harbors two distinct binding sites, uridine and di-and/or trinucleotides, but the RNases upstream of TLR8 remain poorly characterized. We identified two endolysosomal endoribonucleases, RNase T2 and RNase 2, that act synergistically to release uridine from oligoribonucleotides. RNase T2 cleaves preferentially before, and RNase 2 after, uridines. Live bacteria, P. falciparum-infected red blood cells, purified pathogen RNA, and synthetic oligoribonucleotides all required RNase 2 and T2 processing to activate TLR8. Uridine supplementation restored RNA recognition in RNASE2 À/À or RNASET2 À/À but not RNASE2 À/À RNASET2 À/À cells. Primary immune cells from RNase T2-hypomorphic patients lacked a response to bacterial RNA but responded robustly to small-molecule TLR8 ligands. Our data identify an essential function of RNase T2 and RNase 2 upstream of TLR8 and provide insight into TLR8 activation.
Improved survival of injured neurons and the inhibition of repulsive environmental signalling are prerequisites for functional regeneration. BAG1 (Bcl-2-associated athanogene-1) is an Hsp70/Hsc70-binding protein, which has been shown to suppress apoptosis and enhance neuronal differentiation. We investigated BAG1 as a therapeutic molecule in the lesioned visual system in vivo. Using an adeno-associated viral vector, BAG1 (AAV.BAG1) was expressed in retinal ganglion cells (RGC) and then tested in models of optic nerve axotomy and optic nerve crush. BAG1 significantly increased RGC survival as compared to adeno-associated viral vector enhanced green fluorescent protein (AAV.EGFP) treated controls and this was independently confirmed in transgenic mice over-expressing BAG1 in neurons. The numbers and lengths of regenerating axons after optic nerve crush were also significantly increased in the AAV.BAG1 group. In pRGC cultures, BAG1-over-expression resulted in a approximately 3-fold increase in neurite length and growth cone surface. Interestingly, BAG1 induced an intracellular translocation of Raf-1 and ROCK2 and ROCK activity was decreased in a Raf-1-dependent manner by BAG1-over-expression. In summary, we show that BAG1 acts in a dual role by inhibition of lesion-induced apoptosis and interaction with the inhibitory ROCK signalling cascade. BAG1 is therefore a promising molecule to be further examined as a putative therapeutic tool in neurorestorative strategies.
Hepatocyte growth factor (HGF) is known to promote the survival and foster neuritic outgrowth of different subpopulations of CNS neurons during development. Together with its corresponding receptor c-mesenchymal-epithelial transition factor (Met), it is expressed in the developing and the adult murine, rat and human CNS. We have studied the role of HGF in paradigms of retinal ganglion cell (RGC) regeneration and cell death in vitro and in vivo. After application of recombinant HGF in vitro, survival of serum-deprived RGC-5 cells and of growth factor-deprived primary RGC was significantly increased. This was shown to be correlated to the phosphorylation of c-Met and subsequent activation of serine/threonine protein kinase Akt and MAPK downstream signalling pathways involved in neuronal survival. Furthermore, neurite outgrowth of primary RGC was stimulated by HGF. In vivo, c-Met expression in RGC was up-regulated after optic nerve axotomy lesion. Here, treatment with HGF significantly improved survival of axotomized RGC and enhanced axonal regeneration after optic nerve crush. Our data demonstrates that exogenously applied HGF has a neuroprotective and regeneration-promoting function for lesioned CNS neurons. We provide strong evidence that HGF may represent a trophic factor for adult CNS neurons, which may play a role as therapeutic target in the treatment of neurotraumatic and neurodegenerative CNS disorders.
A lesion to the rat rubrospinal tract is a model for traumatic spinal cord lesions and results in atrophy of the red nucleus neurons, axonal dieback, and locomotor deficits. In this study, we used adeno-associated virus (AAV)-mediated over-expression of BAG1 and ROCK2-shRNA in the red nucleus to trace [by co-expression of enhanced green fluorescent protein (EGFP)] and treat the rubrospinal tract after unilateral dorsal hemisection. We investigated the effects of targeted gene therapy on neuronal survival, axonal sprouting of the rubrospinal tract, and motor recovery 12 weeks after unilateral dorsal hemisection at Th 8 in rats. In addition to the evaluation of BAG1 and ROCK2 as therapeutic targets in spinal cord injury, we aimed to demonstrate the feasibility and the limits of an AAV-mediated protein over-expression versus AAV.shRNAmediated down-regulation in this traumatic CNS lesion model. Our results demonstrate that BAG1 and ROCK2-shRNA both promote neuronal survival of red nucleus neurons and enhance axonal sprouting proximal to the lesion.
Human TLR8 is an essential sensor of bacterial RNA which induces proinflammatory and Th1 cytokines. Crystallography revealed that TLR8 binds both uridine and short single-stranded RNA, but the RNases that process the RNA are still unknown. Herein, we demonstrate that two endosomal endoribonucleases, RNaseT2 and RNase2, can process RNA for TLR8 recognition. In the endosome, RNase2 and -T2 act synergistically to release uridine from oligoribonucleotides, with RNaseT2 cleaving preferentially before and RNase2 after uridines. Live bacteria, P. falciparum-infected red blood cells, purified pathogen RNA, and synthetic ligands all required RNase processing for TLR8 activation, and uridine supplementation restored RNA recognition in RNASE2−/− or RNASET2−/− but not double knockout cells. Strikingly, peripheral blood mononuclear cells from RNaseT2 hypomorphic patients did not respond to bacterial RNA but did to small-molecule TLR8 agonists. Our data provide a novel insight into TLR8 activation and its differences between cell types and species.
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