Nerve growth factor (NGF) was first discovered more than 5 decades ago as a molecule that promotes the survival and maturation of developing neurons in the peripheral nervous system 1. NGF released from target cells activates tropomyosin-related kinase A (TrkA) on axon terminals and triggers activation of PI3K/Akt, MEK/ERK, and PLCγ signaling pathways. The signal then travels retrogradely along axon to cell body to promote neuronal survival 2. However, the nature of the retrograde signal remains mysterious.
Several distinct types of retrograde signals could derive from axon terminals 3. First, NGF itself could undergo retrograde transport from terminals to cell body thus activates intracellular TrkA receptor. Indeed, 125I-labeled NGF applied to axon terminals in vivo was found to be retrogradely transported to the neuronal cell bodies 4. Second, NGF triggers TrkA endocytosis through binding to TrkA, and the endocytic TrkA might serve as the retrograde signal 5. In supporting of this notion, both NGF and phosphorylated TrkA are found in endosomes 6. Finally, NGF activates TrkA downstream signal molecules, which could also provide as the retrograde signals 7. These hypotheses are not mutually exclusive, and multiple retrograde signals may exist.
In this issue, Mok and colleagues describe a fundamentally different retrograde mechanism in which NGF suppresses an apoptotic signal in distal axons 8. Campenot's group developed compartmentalized cultures of sympathetic neurons which could segregate the distal axons from cell bodies and proximal axons by a distance of about 1 mm. By employing this system with advantages of segregating cellular compartments, researchers could dissect the molecular mechanisms underlying NGF-dependent retrograde signaling. Previous studies from Campenot's laboratory demonstrated that NGF applied to distal axons of sympathetic neurons supports neuronal survival without transport of NGF towards the cell bodies or TrkA phosphorylation in the cell bodies, suggesting that NGF binding to TrkA in distal axons triggers its downstream signaling cascades locally; afterwards the signals travel retrogradely to the cell bodies and communicate with soma 9. In the current study, the authors found that neutralizing NGF in distal segment of axons but not in the cell bodies led to activation of c-jun and cleavage of caspase-3 in the cell bodies as illustrated in the Figure 1 of schematic model. Interestingly, when NGF was applied to cell bodies while deprived from the distal axons at the same time, nuclear accumulation of phosphorylated c-jun was still observed, similar to cultures completely deprived of NGF. These findings are consistent with the notion that loss of NGF in the distal axons generates an apoptotic signal in the axon terminals which travels to the cell bodies and activates c-jun. However, local delivery of NGF at cell bodies protected against cell death despite the activation of c-jun, suggesting that survival signals activated by NGF in the cell bodies do not simply override the retrograde apoptotic signal but promote neuronal survival probably by acting downstream of c-jun. The axon-specific pro-apoptotic signal was blocked by treating cultures with the protein kinase C (PKC) inhibitor rottlerin, but not by down-regulating the proposed δ isoform of PKC. This inconsistency between pharmacological approach and molecular manipulation may be due to the inefficiency of siRNA knockdown or non-specific effects of pharmacological inhibitor. Further efforts to understand how rottlerin exerts its protective effect showed that NGF deprivation in axon terminals activated GSK3 in a rottlerin-sensitive manner in the distal axons. Furthermore, inhibiting GSK3 activity in distal axons or cell bodies/proximal axons was able to prevent NGF deprivation-induced apoptosis. However, how PKC and GSK3 were activated at axon terminals were not clear.
Growing evidence suggests that NGF supports neuronal survival by activating TrkA and its downstream signals at the axon terminals which retrogradely transmit to the cell bodies. The current study demonstrates that NGF deprivation at the distal axons induces a transportable retrograde pro-apoptotic signal traveling towards the cell bodies to initiate apoptosis. Whether the inhibition of the retrograde apoptotic signal initiated at the axon terminals accounts for NGF-dependent neuronal survival or this novel mechanism operates along with other distinct pathways within the same neurons remains unknown. It is possible that sustained pro-survival signal is activated in the presence of NGF in axon terminals to antagonize endogenous pro-apoptotic signal.
Taken together, this study provides evidence in cultured sympathetic neurons that deprivation of NGF at axon terminal triggers the pro-apoptotic signal which in turn transmits to cell body. Results of this study also shed lights on neurodegenerative diseases 10. However, several important issues remain to be solved: how does the retrograde signal transport from axon terminal to cell body? Is it in a cargo-like transport manner or a flow of continuously signaling activation along the axon segment from distal part to soma? What is the minimal amount of NGF required to antagonize the apoptotic signal? What is the molecular mechanism underlying the cross-talk between pro-survival and pro-apoptotic signals? Does neurotrophin deprivation induce retrograde pro-apoptotic signaling in sympathetic neurons in vivo? Can the same notion be applied to situations such as in nerve injury? Finding answers to these questions is of high importance, both for basic neurobiology and neurodegenerative diseases.
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Zhou, Y., Lu, TJ. & Xiong, ZQ. NGF-dependent retrograde signaling: survival versus death. Cell Res 19, 525–526 (2009). https://doi.org/10.1038/cr.2009.47
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DOI: https://doi.org/10.1038/cr.2009.47
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