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Axon growth, a fundamental process of neuron development, is regulated by both intrinsic and external guidance signals. Impairment of axon growth and maintenance is implicated in the pathogenesis of neurodegenerative disorders such as Amyotrophic Lateral Sclerosis and Alzheimer’s disease (AD). Axon growth is driven by several post-transcriptional RNA processing mechanisms, including alternative splicing, polyadenylation, subcellular localization, and translation. These mechanisms are controlled by RNA-binding proteins (RBPs) through interacting with their target RNAs in a sequence-dependent manner. In this study, we investigate the cytosolic functions of two neuronal RBPs, Ptbp2 and hnRNP R, which are essential for axon growth in motoneurons.
Polypyrimidine tract binding protein 2 (Ptbp2) contributes to neuronal differentiation and axonogenesis by modulating different splicing programs to adjust the level of proteins involved in these processes. While the nuclear functions of Ptbp2 in alternative splicing have been studied in more detail, the cytosolic roles of Ptbp2 associated with axon growth have remained elusive. In the first part of the study, we show that Ptbp2 is present in cytosolic fractions of motoneurons including axons and axon terminals. Depletion of Ptbp2 impairs axon growth and growth cone maturation in cultured embryonic mouse motoneurons. Moreover, Ptbp2 knockdown affects the level of piccolo protein in the growth cone of cultured motoneurons. We detect Ptbp2 as a top interactor of the 3' UTR of the Hnrnpr transcript encoding the RBP hnRNP R. This interaction results in axonal localization of and thereby local translation of Hnrnpr mRNA in motoneurons. Consequently, axonal synthesis of hnRNP R was diminished upon depletion of Ptbp2 in motoneurons. We present evidence that Ptbp2 through cooperation with translation factor eIF5A2 controls hnRNP R synthesis. Additionally, we observe that re-expression of hnRNP R in Ptbp2-deficient motoneurons rescued axon growth defect while Ptbp2 overexpression failed to normalize the axon elongation defect observed in hnRNP R-deficient motoneurons. Our findings pinpoint axonal synthesized hnRNP R as a mediator of Ptbp2 functions in axon growth.
In the second part of this study, we identify hnRNP R binds to the 3' UTR of microtubule-associated tau (Mapt) transcript encoding tau protein and regulates the axonal translocation and translation of Mapt mRNA. Tau protein has a central role in neuronal microtubule assembly and stability. However, in AD, the accumulation of abnormally hyperphosphorylated tau protein leads to axon outgrowth defects. Loss of hnRNP R reduces axonal tau protein but not the total level of tau. We observe that the brains of 5xFAD mice, as a mouse model of AD, deficient for hnRNP R contain lower phospho-tau and amyloid-β plaques. Likewise, Neurons treated with blocking antisense oligonucleotides (ASO) to prevent binding of hnRNP R to Mapt mRNA show reduced axonal Mapt mRNA and consequently newly synthesized tau protein levels. We show that blocking Mapt mRNA transport to axons impairs axon elongation. Our data thus suggest that reducing tau levels selectively in axons, a major subcellular site of tangle formation, might represent a novel therapeutic approach for the treatment of AD.
Plastic changes in synaptic properties are considered as fundamental for adaptive behaviors. Extracellular-signal-regulated kinase (ERK)-mediated signaling has been implicated in regulation of synaptic plasticity. Ribosomal S6 kinase 2 (RSK2) acts as a regulator and downstream effector of ERK. In the brain, RSK2 is predominantly expressed in regions required for learning and memory. Loss-of-function mutations in human RSK2 cause Coffin-Lowry syndrome, which is characterized by severe mental retardation and low IQ scores in affected males. Knockout of RSK2 in mice or the RSK ortholog in Drosophila results in a variety of learning and memory defects. However, overall brain structure in these animals is not affected, leaving open the question of the pathophysiological consequences. Using the fly neuromuscular system as a model for excitatory glutamatergic synapses, we show that removal of RSK function causes distinct defects in motoneurons and at the neuromuscular junction. Based on histochemical and electrophysiological analyses, we conclude that RSK is required for normal synaptic morphology and function. Furthermore, loss of RSK function interferes with ERK signaling at different levels. Elevated ERK activity was evident in the somata of motoneurons, whereas decreased ERK activity was observed in axons and the presynapse. In addition, we uncovered a novel function of RSK in anterograde axonal transport. Our results emphasize the importance of fine-tuning ERK activity in neuronal processes underlying higher brain functions. In this context, RSK acts as a modulator of ERK signaling.
The ganglioside-induced differentiation-associated protein 1 (GDAP1) is a mitochondrial fission factor and mutations in GDAP1 cause Charcot–Marie–Tooth disease. We found that Gdap1 knockout mice (\(Gdap1^{−/−}\)), mimicking genetic alterations of patients suffering from severe forms of Charcot–Marie–Tooth disease, develop an age-related, hypomyelinating peripheral neuropathy. Ablation of Gdap1 expression in Schwann cells recapitulates this phenotype. Additionally, intra-axonal mitochondria of peripheral neurons are larger in \(Gdap1^{−/−}\) mice and mitochondrial transport is impaired in cultured sensory neurons of \(Gdap1^{−/−}\) mice compared with controls. These changes in mitochondrial morphology and dynamics also influence mitochondrial biogenesis. We demonstrate that mitochondrial DNA biogenesis and content is increased in the peripheral nervous system but not in the central nervous system of \(Gdap1^{−/−}\) mice compared with control littermates. In search for a molecular mechanism we turned to the paralogue of GDAP1, GDAP1L1, which is mainly expressed in the unaffected central nervous system. GDAP1L1 responds to elevated levels of oxidized glutathione by translocating from the cytosol to mitochondria, where it inserts into the mitochondrial outer membrane. This translocation is necessary to substitute for loss of GDAP1 expression. Accordingly, more GDAP1L1 was associated with mitochondria in the spinal cord of aged \(Gdap1^{−/−}\) mice compared with controls. Our findings demonstrate that Charcot–Marie–Tooth disease caused by mutations in GDAP1 leads to mild, persistent oxidative stress in the peripheral nervous system, which can be compensated by GDAP1L1 in the unaffected central nervous system. We conclude that members of the GDAP1 family are responsive and protective against stress associated with increased levels of oxidized glutathione.