Hepatocyte growth factor protects retinal ganglion cells by increasing neuronal survival and axonal regeneration in vitro and in vivo

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.     

Circadian regulation of phospholipid metabolism in retinal photoreceptors and ganglion cells

The neural retina is a key component of the vertebrate circadian system that is responsible for synchronizing the central circadian pacemaker to external light-dark (LD) cycles. The retina is itself rhythmic, showing circadian cycles in melatonin levels and gene expression. We assessed the in vivo incorporation of 32P-phosphate and 3H-glycerol into phospholipids of photoreceptor cells (PRCs) and retina ganglion cells (GCs) from chicks in constant illumination conditions (dark: DD or light: LL) over a 24-h period. Our findings showed that in DD there was a daily oscillation in 32P-labeling of total phospholipids synthesized in GCs and axonally transported to the brain. This metabolic fluctuation peaked during the subjective night (zeitgeber time [ZT] 20), persisted for several hours well into the subjective day and declined at subjective dusk (ZT 10-12). PRCs also exhibited an in vivo rhythm of 32P-phospholipid synthesis in DD. This rhythm peaked around ZT 22, continued a few hours into the day and declined by the end of subjective dusk. The major individual species labeled 1 h after 32P administration was phosphatidylinositol (PI) in both PRCs and GCs. Rhythmic phospholipid biosynthesis was also observed in DD after 3H-glycerol administration, with levels in GCs elevated from midday to early night. PRCs exhibited a similar rhythmic profile with the lowest levels of labeling during midnight. Phosphatidylcholine (PC) accounted for the individual species with the highest ratio of 3H-glycerol incorporation in both cell populations at all phases examined. By contrast, in LL the rhythm of 3H-glycerol labeling of phospholipids damped out in both cell layers. Our findings support the idea that, in constant darkness, the metabolism of retinal phospholipids, including their de novo biosynthesis, is regulated by an endogenous circadian clock.     

Gap-43 immunoreactivity and axon regeneration in retinal ganglion cells of the rat

Retinal ganglion cells (RGCs) in rats were retrogradely labeled with the fluorescent tracer Fluorogold (FG) and subjected to GAP-43 and c-JUN immunocytochemistry to identify those RGSs that are capable of regenerating an axon. After optic nerve section (ONS) and simultaneous application of FG to the nerve stump (group 1 experiments), GAP-43 immunoreactive RGCs (between 2 and 21 days after ONS) always represented a subfraction of both FG-labeled (i.e., surviving) RGCs and RGCs exhibiting c-JUN. GAP-43 immunoreactive RGCs represented 22% of RGCs normally present in rat retinae and 25% of surviving RGCs at 5 days after ONS but were reduced to 2% and 1%, which is 6% and 5% of survivors at 14 and 21 days, respectively. In animals that received a peripheral nerve (PN) graft after ONS (group 2 experiments), RGCs with regenerating axons were identified by FG application to the graft at 14 and 21 days. When examined at 21 and 28 days, all FG-labeled RGCs exhibited GAP-43 immunoreactivity, and FG/GAP-43-labeled RGCs were 3% and 2% of those resent in normal rat retinae. In relation to surviving. RGCs GAP-43 immunoreactive RGCs represented 10% at both time points. FG-/GAP-43 labeled RGCs also exhibited c-JUN, but c-JUN immunoreactive RGCs were at both time points at least twice as numerous a FG-/GAP-43-labeled RGCs. These data suggest that regenerating axons in PN grafts derive specifically from GAP-43 reexpressing RGCs. Appearance of GAP-43 immunoreactivity may therefore identify those RGCs that are capable of axonal regeneration or sprouting. 1994 John Wiley & Sons, Inc.     

Effects of metabolic deprivation on methotrexate transport in L1210 leukemia cells: Further evidence for separate influx and efflux systems with different energetic requirements

Summary Measurements of methotrexate transport in L1210 cells in the presence and absence ofd-glucose reveal that both influx and efflux are depressed in the absence ofd-glucose, whereas the steady-state accumulation of drug is enhanced. The reason for the increase in steady state is that the relative decline in efflux is greater than the decline in influx. Analysis of the concentration dependence of steady-state methotrexate accumulation ind-glucose-deprived cells indicates a linear relationship consistent with a one-carrier active transport model. Similar data in nondeprived cells is highly nonlinear and strongly supports the postulate that under physiological conditions influx and efflux of methotrexate are mediated by separate carrier systems. These results indicate that the efflux system, preferentially transporting methotrexate under normal conditions, cannot operate in the absence ofd-glucose, whereas the influx system is only partially inhibited under conditions of glucose deprivation.