Dual leucine-zipper kinase (DLK) is critical for axon-to-soma retrograde signaling following nerve injury. However, it is unknown how DLK, a predicted soluble kinase, conveys long-distance signals and why homologous kinases cannot compensate for loss of DLK. Here, we report that DLK, but not homologous kinases, is palmitoylated at a conserved site adjacent to its kinase domain. Using short-hairpin RNA knockdown/rescue, we find that palmitoylation is critical for DLK-dependent retrograde signaling in sensory axons. This functional importance is because of three novel cellular and molecular roles of palmitoylation, which targets DLK to trafficking vesicles, is required to assemble DLK signaling complexes and, unexpectedly, is essential for DLK's kinase activity. By simultaneously controlling DLK localization, interactions, and activity, palmitoylation ensures that only vesiclebound DLK is active in neurons. These findings explain how DLK specifically mediates nerve injury responses and reveal a novel cellular mechanism that ensures the specificity of neuronal kinase signaling.
Subcellular localization of ribosomes defines the location and capacity for protein synthesis. Methods for in vivo visualizing ribosomes in multicellular organisms are desirable in mechanistic investigations of the cell biology of ribosome dynamics. Here, we developed an approach using split GFP for tissue-specific visualization of ribosomes in Caenorhabditis elegans. Labeled ribosomes are detected as fluorescent puncta in the axons and synaptic terminals of specific neuron types, correlating with ribosome distribution at the ultrastructural level. We found that axonal ribosomes change localization during neuronal development and after axonal injury. By examining mutants affecting axonal trafficking and performing a forward genetic screen, we showed that the microtubule cytoskeleton and the JIP3 protein UNC-16 exert distinct effects on localization of axonal and somatic ribosomes. Our data demonstrate the utility of tissue-specific visualization of ribosomes in vivo, and provide insight into the mechanisms of active regulation of ribosome localization in neurons.
Inducing protein
translocation to the plasma membrane (PM) is an
important approach for manipulating diverse signaling molecules/pathways
in living cells. We previously devised a new chemogenetic system,
in which a protein fused to Escherichia coli dihydrofolate reductase (eDHFR) can be rapidly translocated from
the cytoplasm to the PM using a trimethoprim (TMP)-based self-localizing
ligand (SL), mgcTMP. However, mgcTMP-induced protein translocation
turned out to be transient and spontaneously reversed within 1 h,
limiting its application. Here, we first demonstrated that the spontaneous
reverse translocation was caused by cellular degradation of mgcTMP,
presumably by proteases. To address this problem, we newly developed
a proteolysis-resistant SL, mDcTMP. This mDcTMP
now allows sustained PM localization of eDHFR-fusion proteins (over
several hours to a day), and it was applicable to inducing prolonged
signal activation and cell differentiation. mDcTMP also
worked in live nematodes, making it an attractive new tool for probing
and controlling living systems.
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