Translating regeneration: Local protein synthesis in the neuronal injury response.

Neurons convey signals over long distances, for example motor neurons and sensory neurons project axons up to a meter long in humans. To this end, a sophisticated network of long-range signaling mechanisms enables communication between neuronal processes and somata. These mechanisms are activated during axonal injury and have essential roles both for sensing the injury and regulating subsequent regeneration. Here we survey the role of one such mechanism, axonal translation, which contributes to both retrograde injury signaling and as a source of proteins for regenerating axons. The nature of the axonal synthesis machinery has become progressively clearer over the past decade. A large number of axonally localized mRNAs have been identified, which cover a wide spectrum of protein families; and axonal ribosomes have been detected, even though their origin is still subject to debate. Various kinase pathways, most prominently mTOR, have been implicated in driving local translation in axons. Finally, new technologies are becoming available to visualize axonal translation and enable proteomic analyses. These technological improvements offer new avenues towards comprehensive characterization of the axonal translational machinery.

Importin α5 Regulates Anxiety through MeCP2 and Sphingosine Kinase 1.

Importins mediate transport from synapse to soma and from cytoplasm to nucleus, suggesting that perturbation of importin-dependent pathways should have significant neuronal consequences. A behavioral screen on five importin α knockout lines revealed that reduced expression of importin α5 (KPNA1) in hippocampal neurons specifically decreases anxiety in mice. Re-expression of importin α5 in ventral hippocampus of knockout animals increased anxiety behaviors to wild-type levels. Hippocampal neurons lacking importin α5 reveal changes in presynaptic plasticity and modified expression of MeCP2-regulated genes, including sphingosine kinase 1 (Sphk1). Knockout of importin α5, but not importin α3 or α4, reduces MeCP2 nuclear localization in hippocampal neurons. A Sphk1 blocker reverses anxiolysis in the importin α5 knockout mouse, while pharmacological activation of sphingosine signaling has robust anxiolytic effects in wild-type animals. Thus, importin α5 influences sphingosine-sensitive anxiety pathways by regulating MeCP2 nuclear import in hippocampal neurons.

Translatome Regulation in Neuronal Injury and Axon Regrowth.

Transcriptional events leading to outgrowth of neuronal axons have been intensively studied, but the role of translational regulation in this process is not well understood. Here, we use translatome analyses by ribosome pull-down and protein synthesis characterization by metabolic isotopic labeling to study nerve injury and axon outgrowth proteomes in rodent dorsal root ganglia (DRGs) and sensory neurons. We identify over 1600 gene products that are primarily translationally regulated in DRG neurons after nerve injury, many of which contain a 5'UTR cytosine-enriched regulator of translation (CERT) motif, implicating the translation initiation factor Eif4e in the injury response. We further identified approximately 200 proteins that undergo robust de novo synthesis in the initial stages of axon growth. ApoE is one of the highly synthesized proteins in neurons, and its receptor binding inhibition or knockout affects axon outgrowth. These findings provide a resource for future analyses of the role of translational regulation in neuronal injury responses and axon extension.

Locally translated mTOR controls axonal local translation in nerve injury.

How is protein synthesis initiated locally in neurons? We found that mTOR (mechanistic target of rapamycin) was activated and then up-regulated in injured axons, owing to local translation of mTOR messenger RNA (mRNA). This mRNA was transported into axons by the cell size-regulating RNA-binding protein nucleolin. Furthermore, mTOR controlled local translation in injured axons. This included regulation of its own translation and that of retrograde injury signaling molecules such as importin ß1 and STAT3 (signal transducer and activator of transcription 3). Deletion of the mTOR 3' untranslated region (3'UTR) in mice reduced mTOR in axons and decreased local translation after nerve injury. Both pharmacological inhibition of mTOR in axons and deletion of the mTOR 3'UTR decreased proprioceptive neuronal survival after nerve injury. Thus, mRNA localization enables spatiotemporal control of mTOR pathways regulating local translation and long-range intracellular signaling.

Nucleolin-Mediated RNA Localization Regulates Neuron Growth and Cycling Cell Size.

How can cells sense their own size to coordinate biosynthesis and metabolism with their growth needs? We recently proposed a motor-dependent bidirectional transport mechanism for axon length and cell size sensing, but the nature of the motor-transported size signals remained elusive. Here, we show that motor-dependent mRNA localization regulates neuronal growth and cycling cell size. We found that the RNA-binding protein nucleolin is associated with importin ß1 mRNA in axons. Perturbation of nucleolin association with kinesins reduces its levels in axons, with a concomitant reduction in axonal importin ß1 mRNA and protein levels. Strikingly, subcellular sequestration of nucleolin or importin ß1 enhances axonal growth and causes a subcellular shift in protein synthesis. Similar findings were obtained in fibroblasts. Thus, subcellular mRNA localization regulates size and growth in both neurons and cycling cells.

A voltage-gated pore for translocation of tRNA.

Very little is known about how nucleic acids are translocated across membranes. The multi-subunit RNA Import Complex (RIC) from mitochondria of the kinetoplastid protozoon Leishmania tropica induces translocation of tRNAs across artificial or natural membranes, but the nature of the translocation pore remains unknown. We show that subunits RIC6 and RIC9 assemble on the membrane in presence of subunit RIC4A to form complex R3. Atomic Force Microscopy of R3 revealed particles with an asymmetric surface groove of ∼20 nm rim diameter and ∼1 nm depth. R3 induced translocation of tRNA into liposomes when the pH of the medium was lowered to ∼6 in the absence of ATP. R3-mediated tRNA translocation could also be induced at neutral pH by a K(+) diffusion potential with an optimum of 60-70 mV. Point mutations in the Cys2-His2 Fe-binding motif of RIC6, which is homologous to the respiratory Complex III Fe-S protein, abrogated import induced by low pH but not by K(+) diffusion potential. These results indicate that the R3 complex forms a pore that is gated by a proton-generated membrane potential and that the Fe-S binding region of RIC6 has a role in proton translocation. The tRNA import complex of L. tropica thus contains a novel macromolecular channel distinct from the mitochondrial protein import pore that is apparently involved in tRNA import in some species.

Mitochondrial gene therapy: The tortuous path from bench to bedside.

The association of mitochondrial dysfunction with a variety of human diseases and disabilities has been documented. Mitochondrial gene therapy (MGT) seeks to correct the genetic defect in mitochondrial DNA. For successful MGT, an appreciation of the nature of the dysfunction and of the complexities of mitochondrial disease is necessary. This review summarizes the current status of various MGT protocols described in the literature. Although there are many technical difficulties to be overcome, there are indications that some of them will find clinical applications in the near future.