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RPM-1 Uses Both Ubiquitin Ligase and Phosphatase-Based Mechanisms to Regulate DLK-1 during Neuronal Development

PLoS Genetics (2014) 10(5)
DOI: 10.1371/journal.pgen.1004297
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Abstract

The Pam/Highwire/RPM-1 (PHR) proteins are key regulators of neuronal development that function in axon extension and guidance, termination of axon outgrowth, and synapse formation. Outside of development, the PHR proteins also regulate axon regeneration and Wallerian degeneration. The PHR proteins function in part by acting as ubiquitin ligases that degrade the Dual Leucine zipper-bearing Kinase (DLK). Here, we show that the Caenorhabditis elegans PHR protein, Regulator of Presynaptic Morphology 1 (RPM-1), also utilizes a phosphatase-based mechanism to regulate DLK-1. Using mass spectrometry, we identified Protein Phosphatase Magnesium/Manganese dependent 2 (PPM-2) as a novel RPM-1 binding protein. Genetic, transgenic, and biochemical studies indicated that PPM-2 functions coordinately with the ubiquitin ligase activity of RPM-1 and the F-box protein FSN-1 to negatively regulate DLK-1. PPM-2 acts on S874 of DLK-1, a residue implicated in regulation of DLK-1 binding to a short, inhibitory isoform of DLK-1 (DLK-1S). Our study demonstrates that PHR proteins function through both phosphatase and ubiquitin ligase mechanisms to inhibit DLK. Thus, PHR proteins are potentially more accurate and sensitive regulators of DLK than originally thought. Our results also highlight an important and expanding role for the PP2C phosphatase family in neuronal development. © 2014 Baker et al.

Figures

  • Figure 1. RPM-1 binds to the PP2C phosphatase PPM-2. (A) RPM-1::GFP was transgenically expressed in the neurons of C. elegans alone or in combination with FLAG::PPM-2. Coprecipitating RPM-1::GFP was detected with FLAG::PPM-2 (upper panel). Levels of FLAG::PPM-2 (middle blot) and RPM-1::GFP (lower blot) were determined by immunoprecipitation (IP). (B and C) At left are epifluorescent images of transgenic animals expressing GFP from the native ppm-2 promoter (Pppm-2::GFP). At right are schematic diagrams of the cells, nerve cords or regions of interest. Pppm-2::GFP expression was detected in (B) the nerve ring, and in (C) the dorsal and ventral nerve cords. (D and E) Shown are epifluorescent images of transgenic animals expressing both GFP from the native ppm-2 promoter (Pppm-2::GFP) and mCherry from a cell-specific promoter for the mechanosensory neurons (Pmec-7::mCherry). Expression of Pppm-2::GFP detected in (D) an ALM mechanosensory neuron (arrow) and (E) a PLM mechanosensory neuron (arrow). In all cases, multiple independently derived transgenic lines showed similar results, and images from a representative transgenic line are shown. Scale bars are 10 mm. doi:10.1371/journal.pgen.1004297.g001
  • Figure 2. ppm-2 regulates axon termination of PLM neurons. (A) Schematic diagram of the ppm-2 open reading frame. Exons are shown with grey boxes and introns as lines. Deletions generated by ok2186 and tm3480 are shown below. (B) Schematic diagram of the PPM-2 protein. Conserved residues that are required for catalytic activity are highlighted. Protein sequence deleted by ok2186 and tm3480 are shown below. (C and D) Defects in axon termination of the PLM mechanosensory neurons were visualized using muIs32 (Pmec-7GFP). (C) Upper panel is a schematic diagram showing the mechanosensory neurons of C. elegans (modified from Worm Atlas). The blue box highlights the region shown below that was visualized using epifluorescent microscopy. An example of a PLM axon that overextends and hooks (hook) is shown for both ppm-2(ok2186)-/- and rpm-1-/- genotypes (arrowheads). Scale bar is 10 mm. (D) Quantitation of axon termination defects (hook represented in black, or overextension alone represented in grey) for the indicated genotypes. Averages are shown for data collected from 5–8 independent counts of 20–30 PLM neurons from young adult worms (16–20 hours post L4) grown at 23uC. Error bars represent the standard error of the mean, and significance was determined using an unpaired t-test. **p,0.01, ***p,0.001 and ns = not significant. doi:10.1371/journal.pgen.1004297.g002
  • Figure 3. ppm-2 functions cell autonomously downstream of rpm-1. The PLM axon termination defects (hook) were quantified for all genotypes shown using the transgene muIs32. (A) A cell specific promoter (Pmec-7) was used to transgenically express wild-type PPM-2, phosphatase-dead PPM-2 D59N, or PPM-2 G2A that was not N-myristoylated in the PLM neurons of ppm-2-/- fsn-1-/- double mutants. (B) A cell specific promoter (Pmec-7) was used to transgenically express PPM-2 or phosphatase-dead PPM-2 D59N in rpm-1-/- single mutants. Averages are shown for data collected from 5 or more transgenic lines for each genotype. In all experiments, young adult worms (16–20 hours post L4) grown at 23uC were analyzed. Error bars represent the standard error of the mean, and significance was determined using an unpaired t-test. ***p,0.001 and ns = not significant. doi:10.1371/journal.pgen.1004297.g003
  • Figure 4. PPM-2 negatively regulates the MAP3K DLK-1. PLM axon termination defects (hook) were quantified for the indicated genotypes using the transgene muIs32. (A) Loss of function in dlk-1 suppresses the axon termination defects in ppm-2-/- single mutants and glo-4-/-; ppm-2-/double mutants. Shown are averages for data collected from 5–8 independent counts of 20–30 PLM neurons from young adult worms (16–20 hours post L4) grown at 23uC for each genotype. (B) Transgenic overexpression of the MAP3K DLK-1, or the MAP2K MKK-4 results in PLM axon termination defects (hook). Coexpression of PPM-2 rescues defects caused by overexpression of DLK-1, but not MKK-4. Shown are averages for data pooled from 5 or more transgenic lines for the indicated genotypes; young adult worms grown at 23uC were analyzed. For A and B, error bars represent the standard error of the mean, and significance was determined using an unpaired t-test. **p,0.005, ***p,0.001 and ns = not significant. doi:10.1371/journal.pgen.1004297.g004
  • Figure 5. PPM-2 binds to DLK-1. CoIP from transgenic whole worm lysates showing that (A) PPM-2::GFP and PPM-2::GFP D59N bind to FLAG::DLK1 K162R (upper panel) (B) PPM-2::GFP R185A shows increased binding to FLAG::DLK-1 K162R compared to wild-type PPM-2::GFP (upper panel). (C) Quantitation of PPM-2::GFP coIP with FLAG::DLK-1 K162R. Note that data was acquired from 2 independently derived transgenic lines for each genotype, and histograms represent the ratio of the amount of PPM-2::GFP or PPM-2::GFP R185A in coIP to the amount of FLAG::DLK-1 K162R that was immunoprecipitated. (D) Immunoblots of whole worm lysates generated solely from transgenic worms. Catalytically inactive PPM-2::GFP D59N was consistently expressed at elevated levels compared to wild-type PPM-2::GFP (upper panel). (E) Immunoblots of whole worm lysates generated solely from transgenic worms. The level of wild-type PPM-2::GFP was elevated when coexpressed with FLAG::DLK-1 K162R, compared to when it was coexpressed with mCherry (upper panel). (F) Quantitation of PPM-2::GFP levels from lysates of the indicated transgenic genotypes. Shown are the average levels of PPM-2 acquired from 4 independently derived transgenic lines for each genotype normalized to MPK-1 (loading control). Error bars represent the standard error of the mean, and significance was determined using an unpaired t-test. **p,0.01, ***p,0.001, ns = not significant. doi:10.1371/journal.pgen.1004297.g005
  • Figure 6. PPM-2 regulates DLK-1 by acting on S874. (A) Quantitation of PLM axon termination defects (hook) caused by transgenic overexpression of DLK-1 and phosphomimetic DLK-1 point mutants. Note that coexpression of PPM-2 rescues defects caused by overexpression of DLK-1, but not defects caused by overexpression of DLK-1 S874E S878E and DLK-1 S874E. Shown are averages of data pooled from 5 or more transgenic lines for the indicated genotypes; young adult worms (16–20 hours post L4) grown at 23uC were analyzed. (B) CoIP from transgenic whole worm lysates showing that FLAG::DLK-1L K162R coprecipitates with GFP::DLK-1S, and binding of DLK-1L to DLK-1S is not altered in ppm-2-/- mutants (upper panel). (C) Quantitation of FLAG::DLK-1L K162R coIP with GFP::DLK-1S for the indicated genotypes normalized to amount of GFP::DLK-1S precipitated. Shown are the average levels of FLAG::DLK-1 K162R coprecipitating with GFP::DLK-1S acquired from 3 independently derived transgenic lines for each genotype. Error bars represent the standard error of the mean, and significance was determined using an unpaired t-test. **p,0.01, ***p,0.001, ns = not significant. doi:10.1371/journal.pgen.1004297.g006
  • Figure 7. ppm-2 regulates synapse formation by GABAergic motor neurons. (A) Upper panel is a schematic diagram modified from Worm Atlas showing the GABAergic DD neurons that innervate the dorsal muscles (DD cell body and axon in purple, and presynaptic terminals shown in green). A transgene, juIs1 (Punc-25SNB-1::GFP), and epifluorescent microscopy was used to visualize the presynaptic terminals of the DD motor neurons for the indicated genotypes. Arrows note regions of the dorsal cord where presynaptic terminals are absent. Arrowheads highlight abnormal aggregation of presynaptic terminals. Scale bar is 10 mm. (B) Quantitation of synapse formation defects. Shown are averages for data collected from 3 or more independent experiments performed at 25uC in which 15–20 synchronized, young adult worms (16–20 hours post L4) were analyzed. Error bars represent the standard error of the mean, and significance was determined using an unpaired t-test. *p,0.05, ***p,0.001 and ns = not significant. doi:10.1371/journal.pgen.1004297.g007
  • Figure 8. PPM-2 localizes to the presynaptic terminal. (A) PPM-2::GFP was transgenically expressed in the GABAergic motor neurons using a cell specific promoter (Punc-25). Epifluorescent microscopy was used to visualize PPM-2::GFP puncta in the dorsal and ventral cords. (B) Transgenic worms expressing PPM-2::GFP and SNB-1::dsRED in the GABAergic motor neurons were analyzed by confocal microscopy. Shown are the presynaptic terminals of the DD neurons on the dorsal side of the animal. Scale bar is 10 mm. doi:10.1371/journal.pgen.1004297.g008

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Baker, S. T., Opperman, K. J., Tulgren, E. D., Turgeon, S. M., Bienvenut, W., & Grill, B. (2014). RPM-1 Uses Both Ubiquitin Ligase and Phosphatase-Based Mechanisms to Regulate DLK-1 during Neuronal Development. PLoS Genetics, 10(5). https://doi.org/10.1371/journal.pgen.1004297

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