Loss of SMEK, a novel, conserved protein, suppresses MEK1 null cell polarity, chemotaxis, and gene expression defects

MEK/extracellular signal-regulated kinase (ERK) mitogen-activated protein kinase signaling is imperative for proper chemotaxis. Dictyostelium mek1(-) (MEK1 null) and erk1(-) cells exhibit severe defects in cell polarization and directional movement, but the molecules responsible for the mek1(-) and erk1(-) chemotaxis defects are unknown. Here, we describe a novel, evolutionarily conserved gene and protein (smkA and SMEK, respectively), whose loss partially suppresses the mek1(-) chemotaxis phenotypes. SMEK also has MEK1-independent functions: SMEK, but not MEK1, is required for proper cytokinesis during vegetative growth, timely exit from the mound stage during development, and myosin II assembly. SMEK localizes to the cell cortex through an EVH1 domain at its N terminus during vegetative growth. At the onset of development, SMEK translocates to the nucleus via a nuclear localization signal (NLS) at its C terminus. The importance of SMEK's nuclear localization is demonstrated by our findings that a mutant lacking the EVH1 domain complements SMEK deficiency, whereas a mutant lacking the NLS does not. Microarray analysis reveals that some genes are precociously expressed in mek1(-) and erk1(-) cells. The misexpression of some of these genes is suppressed in the smkA deletion. These data suggest that loss of MEK1/ERK1 signaling compromises gene expression and chemotaxis in a SMEK-dependent manner.     

Competition between two phosphatases fine-tunes Hedgehog signaling

Hedgehog (Hh) signaling is essential for embryonic development and adult homeostasis. How its signaling activity is fine-tuned in response to fluctuated Hh gradient is less known. Here, we identify protein phosphatase V (PpV), the catalytic subunit of protein phosphatase 6, as a homeostatic regulator of Hh signaling. PpV is genetically upstream of widerborst (wdb), which encodes a regulatory subunit of PP2A that modulates high-level Hh signaling. We show that PpV negatively regulates Wdb stability independent of phosphatase activity of PpV, by competing with the catalytic subunit of PP2A for Wdb association, leading to Wdb ubiquitination and subsequent proteasomal degradation. Thus, regulated Wdb stability, maintained through competition between two closely related phosphatases, ensures graded Hh signaling. Interestingly, PpV expression is regulated by Hh signaling. Therefore, PpV functions as a Hh activity sensor that regulates Wdb-mediated PP2A activity through feedback mechanisms to maintain Hh signaling homeostasis.     

The Role of Protein Phosphatase 4 in Regulating Microtubule Severing in the Caenorhabditis elegans Embryo

MEI-1, the catalytic subunit of the Caenorhabditis elegans “katanin” microtubule-severing complex, is required for meiotic spindle formation. However, MEI-1 must be inactivated after the completion of meiosis to allow formation of the first mitotic spindle. Recent work demonstrated that post-meiotic MEI-1 undergoes ubiquitin-dependent degradation mediated by two independent pathways. Here we describe another level of MEI-1 regulation involving the protein phosphatase 4 (PP4) complex. The PP4 R1 regulatory subunit protein phosphatase four regulatory subunit 1 (ppfr-1) was identified in an RNA interference (RNAi) screen for suppressors of a mei-1(gf) allele that is refractory to post-meiotic degradation. RNAi to the PP4 catalytic subunit PPH-4.1 or to the α4 regulatory PPFR-4 also suppressed lethality of ectopic MEI-1. These results suggest that PP4(+) activates MEI-1, and therefore loss of PP4 decreases ectopic MEI-1(gf) activity. PPH-4.1 and MEI-1 co-immunoprecipitate with one another, indicating that the PP4 complex likely regulates MEI-1 activity directly rather than through an intermediate. The ppfr-1 mutant has subtle meiotic defects indicating that PPFR-1 also regulates MEI-1 during meiosis. MBK-2 is the only kinase known to phosphorylate MEI-1 and triggers post-meiotic MEI-1 degradation. However, genetic interactions between PP4 and mbk-2 were not consistent with an antagonistic relationship between the phosphatase and kinase. Additionally, reducing PP4 in mei-1(gf) did not change the level or localization of post-meiotic MEI-1. Thus, by making use of a genetic background where MEI-1 is ectopically expressed, we have uncovered a third mechanism of MEI-1 regulation, one based on phosphorylation but independent of degradation. The redundant regulatory pathways likely contribute in different ways to the rapid and precise post-meiotic inactivation of MEI-1 microtubule-severing activity.     

Dephosphorylation of DBC1 by Protein Phosphatase 4 Is Important for p53-Mediated Cellular Functions

Deleted in breast cancer-1 (DBC1) contributes to the regulation of cell survival and apoptosis. Recent studies demonstrated that DBC is phosphorylated at Thr454 by ATM/ATR kinases in response to DNA damage, which is a critical event for p53 activation and apoptosis. However, how DBC1 phosphorylation is regulated has not been studied. Here we show that protein phosphatase 4 (PP4) dephosphorylates DBC1, regulating its role in DNA damage response. PP4R2, a regulatory subunit of PP4, mediates the interaction between DBC1 and PP4C, a catalytic subunit. PP4C efficiently dephosphorylates pThr454 on DBC1 in vitro, and the depletion of PP4C/PP4R2 in cells alters the kinetics of DBC1 phosphorylation and p53 activation, and increases apoptosis in response to DNA damage, which are compatible with the expression of the phosphomimetic DBC-1 mutant (T454E). These suggest that the PP4-mediated dephosphorylation of DBC1 is necessary for efficient damage responses in cells.     

Human Protein Phosphatase PP6 Regulatory Subunits Provide Sit4-Dependent and Rapamycin–Sensitive Sap Function in Saccharomyces cerevisiae

In the budding yeast Saccharomyces cerevisiae the protein phosphatase Sit4 and four associated proteins (Sap4, Sap155, Sap185, and Sap190) mediate G₁ to S cell cycle progression and a number of signaling events controlled by the target of rapamycin TOR signaling cascade. Sit4 and the Sap proteins are ubiquitously conserved and their human orthologs, PP6 and three PP6R proteins, share significant sequence identity with their yeast counterparts. However, relatively little is known about the functions of the PP6 and PP6R proteins in mammalian cells. Here we demonstrate that the human PP6R proteins physically interact with Sit4 when expressed in yeast cells. Remarkably, expression of PP6R2 and PP6R3 but not expression of PP6R1 rescues the growth defect and rapamycin hypersensitivity of yeast cells lacking all four Saps, and these effects require Sit4. Moreover, PP6R2 and PP6R3 enhance cyclin G₁ gene expression and DNA synthesis, and partially abrogate the G₁ cell cycle delay and the budding defect of the yeast quadruple sap mutant strain. In contrast, the human PP6R proteins only modestly support nitrogen catabolite gene expression and are unable to restore normal levels of eIF2α phosphorylation in the quadruple sap mutant strain. These results illustrate that the human PP6-associated proteins are capable of providing distinct rapamycin-sensitive and Sit4-dependent Sap functions in the heterologous context of the yeast cell. We hypothesize that the human Saps may play analogous roles in mTORC1-PP6 signaling events in metazoans.     

Novel perspectives of target-binding by the evolutionarily conserved PP4 phosphatase

Protein phosphatase 4 (PP4) is an evolutionarily conserved and essential Ser/Thr phosphatase that regulates cell division, development and DNA repair in eukaryotes. The major form of PP4, present from yeast to human, is the PP4c-R2-R3 heterotrimeric complex. The R3 subunit is responsible for substrate-recognition via its EVH1 domain. In typical EVH1 domains, conserved phenylalanine, tyrosine and tryptophan residues form the specific recognition site for their target''s proline-rich sequences. Here, we identify novel binding partners of the EVH1 domain of the Drosophila R3 subunit, Falafel, and demonstrate that instead of binding to proline-rich sequences this EVH1 variant specifically recognizes atypical ligands, namely the FxxP and MxPP short linear consensus motifs. This interaction is dependent on an exclusively conserved leucine that replaces the phenylalanine invariant of all canonical EVH1 domains. We propose that the EVH1 domain of PP4 represents a new class of the EVH1 family that can accommodate low proline content sequences, such as the FxxP motif. Finally, our data implicate the conserved Smk-1 domain of Falafel in target-binding. These findings greatly enhance our understanding of the substrate-recognition mechanisms and function of PP4.     

Purification and identification of a novel subunit of protein serine/threonine phosphatase 4

The catalytic subunit of protein serine/threonine phosphatase 4 (PP4C) has greater than 65% amino acid identity to the catalytic subunit of protein phosphatase 2A (PP2AC). Despite this high homology, PP4 does not appear to associate with known PP2A regulatory subunits. As a first step toward characterization of PP4 holoenzymes and identification of putative PP4 regulatory subunits, PP4 was purified from bovine testis soluble extracts. PP4 existed in two complexes of approximately 270-300 and 400-450 kDa as determined by gel filtration chromatography. The smaller PP4 complex was purified by sequential phenyl-Sepharose, Source 15Q, DEAE2, and Superdex 200 gel filtration chromatographies. The final product contained two major proteins: the PP4 catalytic subunit plus a protein that migrated as a doublet of 120-125 kDa on SDS-polyacrylamide gel electrophoresis. The associated protein, termed PP4R1, and PP4C also bound to microcystin-Sepharose. Mass spectrometry analysis of the purified complex revealed two major peaks, at 35 (PP4C) and 105 kDa (PP4R1). Amino acid sequence information of several peptides derived from the 105 kDa protein was utilized to isolate a human cDNA clone. Analysis of the predicted amino acid sequence revealed 13 nonidentical repeats similar to repeats found in the A subunit of PP2A (PP2AA). The PP4R1 cDNA clone engineered with an N-terminal Myc tag was expressed in COS M6 cells and PP4C co-immunoprecipitated with Myc-tagged PP4R1. These data indicate that one form of PP4 is similar to the core complex of PP2A in that it consists of a catalytic subunit and a "PP2AA-like" structural subunit.     

Molecular functions of the PP2A regulatory subunit Tap46 in plants

Tap42/α4 is a regulatory subunit of the protein phosphatase 2A (PP2A) family of phosphatases and plays a role in the target of rapamycin (TOR) pathway that regulates cell growth, ribosome biogenesis, translation and cell cycle progression in both yeast and mammals. We determined the cellular functions of Tap46, the plant homolog of Tap42/α4, in both Arabidopsis thaliana and Nicotiana benthamiana. Tap46 associated with the catalytic subunits of PP2A and the PP2A-like phosphatases PP4 and PP6 in vivo. Tap46 was phosphorylated by TOR in vitro, indicating that Tap46 is a direct substrate of TOR kinase. Tap46 deficiency caused cellular phenotypes that are similar to TOR-depletion phenotypes, including repression of global translation and activation of both autophagy and nitrogen recycling. Furthermore, Tap46 depletion regulated total PP2A activity in a time-dependent manner similar to TOR deficiency. These results suggest that Tap46 acts as a positive effector of the TOR signaling pathway in controlling diverse metabolic processes in plants. However, Tap46 silencing caused acute cell death, while TOR silencing only hastened senescence. Furthermore, mitotic cells with reduced Tap46 levels exhibited chromatin bridges at anaphase, while TOR depletion did not cause a similar defect. These findings suggest that Tap46 may have TOR-independent functions as well as functions related to TOR signaling in plants.Key words: acute cell death, autophagy, chromatin bridge, nitrogen mobilization, protein phosphatases, target of rapamycin (TOR)Yeast type 2A phosphatase-associated protein 42 kDa (Tap42) is a regulatory subunit that directly associates with catalytic subunits of the protein phosphatase 2A (PP2A) family of protein phosphatases to make a heterodimer and regulates the activity and substrate specificity of the intact enzyme complex.¹ Functions of Tap42 as a component of the target of rapamycin (TOR) signaling pathway have been well characterized in yeast.^1–3 Tap42-regulated phosphatase activities play a major role in signal transduction mediated by TOR. Accumulating evidence suggest that TOR regulates phosphorylation of target proteins by restraining PP2A activity through Tap42 phosphorylation.^1–3 Rapamycin inhibits TOR activity and also influences Tap42-mediated phosphatase regulation in yeast.^3–5α4, the mammalian homolog of Tap42, also associates with the catalytic subunits of PP2A, PP4 and PP6 to make a heterodimer.⁶ Rapamycin inhibits mammalian TOR (mTOR) activity, but it is not clear whether rapamycin prevents the formation of the α4/PP2Ac complex or whether α4 stimulates or represses PP2Ac activity.^7–9 Interestingly, loss of Tap42 function in Drosophila does not affect TOR-regulated activities, including cell growth, metabolism and S6 kinase activity, but results in mitotic arrest caused by spindle anomalies and subsequent activation of c-Jun N-terminal kinase signaling and apoptosis.¹⁰ Similarly, α4 deletion in mice leads to the rapid onset of apoptosis in both proliferating and differentiated cells, while rapamycin itself does not severely affect adult cells.¹¹ Furthermore, while TOR depletion causes developmental arrest and organ degeneration at the L3 stage in Caenorhabditis elegans, loss of α4 does not reproduce TOR deficiency phenotypes, but mainly leads to a fertility defect.¹² Taken together, these results suggest that the yeast Tap42/TOR paradigm is not completely conserved in higher eukaryotes and that Tap42/α4 functions may not be exclusively dependent on the Tor signaling pathway.In this study, we investigated the in vivo functions and phosphatase regulation of Tap46, the plant Tap42/α4 homolog, in relation to TOR in Nicotiana benthamiana, Arabidopsis and tobacco BY2 cells. Tap46 was shown to interact with the catalytic subunits of PP2A, PP4 and PP6 in vivo. Recombinant Tap46 protein was phosphorylated by immunoprecipitated TOR kinase and its deletion forms in vitro. Dexamethasone-induced RNAi of Tap46 caused dramatic repression of global translation and activation of both autophagy and nitrogen mobilization in the early stages of gene silencing. These phenotypes mimic those of TOR inactivation or TOR deficiency in Arabidopsis, yeast and mammals, indicating that Tap46 is a critical mediator of the Tor pathway in the regulation of these metabolic processes in plants. However, these early phenotypes of Tap46-deficient plants were soon followed by an acute and rapid programmed cell-death (PCD), while TOR silencing only led to growth retardation and premature senescence in Arabidopsis and N. benthamiana, confirming results from a previous study.¹³ The PCD caused by Tap46 deficiency is consistent with the apoptosis induced by loss of Tap42/α4 function in both Drosophila and mice.^10,11 Thus Tap42/α4/Tap46 appears to have a strong anti-apoptotic activity in higher eukaryotes. The underlying mechanisms of PCD activation caused by Tap46 depletion remain to be revealed, but it is possible that the inappropriate modulation of phosphatase activity and aberrant protein phosphorylation led to stress signaling and PCD activation.Another interesting phenotype of Tap46 deficiency is the formation of chromatin bridges in anaphase during mitosis, suggesting a role for Tap46 in plant cell mitotic progression. However, there have been no reports of anaphase bridge formation in tor mutants of any organisms. In Drosophila, loss of Tap42 function causes spindle disorganization and pre-anaphase arrest prior to the onset of apoptosis.¹⁰ In addition, Drosophila mutants with a defective regulatory subunit of PP2A exhibit an increased number of lagging chromosomes and chromatin bridges in anaphase.^14,15 Tap46 likely regulates the functions of PP2A family phosphatases during mitosis by direct association with their catalytic subunits, thereby modulating both the activity and specificity of the enzyme. Accumulating evidence reveals dynamic functions of PP2A during mitosis in both yeast and mammals: PP2A regulates kinetochore function, sister chromatid cohesion, spindle bipolarity and progression to anaphase.^15–17 Counteracting the activity of protein kinases, PP4 has also been implicated in both centrosome maturation and function during mitosis.¹⁸ Based on immunolabeling results, Tap46 was visualized as distinct spots around chromatin and mitotic spindles during mitosis in tobacco BY2 cells (Lee HS and Pai HS, unpublished results). Further studies will address the interacting partners and dynamic relocation of Tap46 during the cell cycle.Our results in this study demonstrated that Tap46 plays an important regulatory role in plant growth and metabolism; a major part of its function appears related to TOR signaling. However, we consistently observed certain phenotypic differences between Tap46-silenced and TOR-silenced Arabidopsis and N. benthamiana plants: an acute and rapid PCD occurred upon Tap46 silencing but not upon TOR silencing, despite a similar degree of gene silencing. Furthermore, we did not observe anaphase bridge formation in mitotic root-tip cells of ethanol-induced TOR RNAi Arabidopsis plants, while chromatin bridges were repeatedly observed in Tap46-silenced tobacco BY2 and Arabidopsis root-tip cells. Although an ancient Tap42/TOR paradigm observed in yeast appears to be conserved in plants, new TOR-independent functions of Tap46 might have evolved, the abrogation of which can cause massive PCD activation and anaphase bridge formation. Tap46 is a major regulator of cellular PP2A activity in plant cells by interacting with multiple phosphatase partners. Unraveling the molecular networks of Tap46 activity and interactions is essential for understanding its TOR-dependent and -independent functions in plants.     

Identification and Functional Characterization of Inhibitor-3, a Regulatory Subunit of Protein Phosphatase 1 in Plants

Protein phosphatase 1 (PP1) is a eukaryotic serine/threonine protein phosphatase, and mediates diverse cellular processes in animal systems via the association of a catalytic subunit (PP1c) with multiple regulatory subunits that determine the catalytic activity, the subcellular localization, and the substrate specificity. However, no regulatory subunit of PP1 has been identified in plants so far. In this study, we identified inhibitor-3 (Inh3) as a regulatory subunit of PP1 and characterized a functional role of Inh3 in Vicia faba and Arabidopsis (Arabidopsis thaliana). We found Inh3 as one of the proteins interacting with PP1c using a yeast two-hybrid system. Biochemical analyses demonstrated that Arabidopsis Inh3 (AtInh3) bound to PP1c via the RVxF motif of AtInh3, a consensus PP1c-binding sequence both in vitro and in vivo. AtInh3 inhibited the PP1c phosphatase activity in the nanomolar range in vitro. AtInh3 was localized in both the nucleus and cytoplasm, and it colocalized with Arabidopsis PP1c in these compartments. Disruption mutants of AtINH3 delayed the progression of early embryogenesis, arrested embryo development at the globular stage, and eventually caused embryo lethality. Furthermore, reduction of AtINH3 expression by RNA interference led to a decrease in fertility. Transformation of the lethal mutant of inh3 with wild-type AtINH3 restored the phenotype, whereas that with the AtINH3 gene having a mutation in the RVxF motif did not. These results define Inh3 as a regulatory subunit of PP1 in plants and suggest that Inh3 plays a crucial role in early embryogenesis in Arabidopsis.     

A novel, evolutionarily conserved protein phosphatase complex involved in cisplatin sensitivity

Using a combination of tandem affinity purification tagging and mass spectrometry, we characterized a novel, evolutionarily conserved protein phosphatase 4 (PP4)-containing complex (PP4cs, protein phosphatase 4, cisplatin-sensitive complex) that plays a critical role in the eukaryotic DNA damage response. PP4cs is comprised of the catalytic subunit PP4C; a known regulatory subunit, PP4R2; and a novel protein that we termed PP4R3. The Saccharomyces cerevisiae PP4R3 ortholog Psy2 was identified previously in a screen for sensitivity to the DNA-damaging agent and anticancer drug cisplatin. We demonstrated that deletion of any of the PP4cs complex orthologs in S. cerevisiae elicited cisplatin hypersensitivity. Furthermore human PP4R3 complemented the yeast psy2 deletion, and Drosophila melanogaster lacking functional PP4R3 (flfl) exhibited cisplatin hypersensitivity, suggesting a highly conserved role for PP4cs in DNA damage repair. Finally we found that PP4R3 may target PP4cs to the DNA damage repair machinery at least in part via an interaction with Rad53 (CHK2).     

Protein Phosphatase 2A (PP2A) Regulatory Subunits ParA and PabA Orchestrate Septation and Conidiation and Are Essential for PP2A Activity in Aspergillus nidulans

Protein phosphatase 2A (PP2A) is a major intracellular protein phosphatase that regulates multiple aspects of cell growth and metabolism. Different activities of PP2A and subcellular localization are determined by its regulatory subunits. Here we identified and characterized the functions of two protein phosphatase regulatory subunit homologs, ParA and PabA, in Aspergillus nidulans. Our results demonstrate that ParA localizes to the septum site and that deletion of parA causes hyperseptation, while overexpression of parA abolishes septum formation; this suggests that ParA may function as a negative regulator of septation. In comparison, PabA displays a clear colocalization pattern with 4′,6-diamidino-2-phenylindole (DAPI)-stained nuclei, and deletion of pabA induces a remarkable delayed-septation phenotype. Both parA and pabA are required for hyphal growth, conidiation, and self-fertilization, likely to maintain normal levels of PP2A activity. Most interestingly, parA deletion is capable of suppressing septation defects in pabA mutants, suggesting that ParA counteracts PabA during the septation process. In contrast, double mutants of parA and pabA led to synthetic defects in colony growth, indicating that ParA functions synthetically with PabA during hyphal growth. Moreover, unlike the case for PP2A-Par1 and PP2A-Pab1 in yeast (which are negative regulators that inactivate the septation initiation network [SIN]), loss of ParA or PabA fails to suppress defects of temperature-sensitive mutants of the SEPH kinase of the SIN. Thus, our findings support the previously unrealized evidence that the B-family subunits of PP2A have comprehensive functions as partners of heterotrimeric enzyme complexes of PP2A, both spatially and temporally, in A. nidulans.     

PP2A-A/在金鱼及斑马鱼发育中的分化表达模式

以金鱼和斑马鱼为研究对象,运用RT-PCR和Western Blot技术分析蛋白磷酸酶2A(PP2A)结构亚基A(PP2A-A/)在金鱼、斑马鱼成体9种组织和12个发育时期胚胎中mRNA和蛋白水平的表达情况,得到其分化表达模式为:(1)在mRNA水平上,PP2A-A/在金鱼、斑马鱼9种组织中具有较强表达;种属差异性和组织差异性均较大;结构亚基A的两亚型A和A的表达存在差异。(2)在蛋白水平上,PP2A-A/在金鱼、斑马鱼9种组织中均有表达;种属差异性不大但出现明显的组织差异性。(3)PP2A-A/mRNA在金鱼和斑马鱼卵裂期到囊胚期胚胎中大量存在,PP2A-AmRNA在金鱼眼色素期量剧增推测其对金鱼眼色素的形成至关重要。(4)PP2A-A/基因在金鱼、斑马鱼12个发育时期胚胎中均有较高水平的蛋白存在,提示其为维持胚胎的正常发育发挥重要作用。       

Leucine methylation of protein phosphatase PP4C at C-terminal is critical for its cellular functions

Background

Protein phosphatase 4 (PP4) has been known to have critical functions in DNA double strand break (DSB) repair and cell cycle by the regulation of phosphorylation of its target proteins, such as H2AX, RPA2, KAP-1, 53BP1. However, it is largely unknown how PP4 itself is regulated.

Methods

We examined the PP4C methylation on L307 at C-terminal by using methylated-leucine specific antibody. Then with PP4C L307A mutant, we explored that how nonmethylated form of PP4C affects its known cellular functions by immunoprecipitation, immunofluorescence, and DNA DSB repair assays.

Results

Here we show that PP4C is methylated on its C-terminal leucine residue in vivo and this methylation is important for cellular functions mediated by PP4. In the cells PP4C L307A mutant has significantly low activity of dephosphorylation against its known target proteins, and the loss of interaction between L307A PP4 mutant and regulatory subunits, R1, R2, or R3α/β causes the dissociation from its target proteins. Moreover, PP4C L307A mutant loses its role in both DSB repair pathways, HR (homologous recombination) and NHEJ (non-homologous end joining), which phenocopies PP4C depletion.

Conclusion

Our results demonstrate the key site of PP4C methylation and establish the physiological importance of this regulation.     

Myosin phosphatase: Unexpected functions of a long-known enzyme

Myosin phosphatase (MP) holoenzyme is a Ser/Thr specific enzyme, which is the member of protein phosphatase type 1 (PP1) family and composed of a PP1 catalytic subunit (PP1c/PPP1CB) and a myosin phosphatase targeting subunit (MYPT1/PPP1R12A). PP1c is required for the catalytic activity of the holoenzyme, while MYPT1 regulates MP through targeting the holoenzyme to its substrates. Above the well-characterized function of MP, as the major regulator of smooth muscle contractility mediating the dephosphorylation of 20 kDa myosin light chain, accumulating data support its role in other, non-contractile functions. In this review, we summarize the scaffold function of MP holoenzyme and its roles in processes such as cell cycle, development, gene expression regulation and neurotransmitter release. In particular, we highlight novel interacting proteins of MYPT1 and pathophysiological functions of MP relevant to tumorigenesis, insulin resistance and neurodegenerative disorders.This article is part of a Special Issue entitled: Protein Phosphatases as Critical Regulators for Cellular Homeostasis edited by Prof. Peter Ruvolo and Dr. Veerle Janssens.     

Dephosphorylation of endogenous GABAB receptor R2 subunit and AMPK α subunits which were measured by in vitro method using transfer membrane

Protein phosphorylation can be regulated by changes in kinase activity, phosphatase activity, or both. GABA_B receptor R2 subunit (GABA_BR2) is phosphorylated at S783 by 5′-AMP-activated-protein kinase (AMPK), and this phosphorylation modulates GABA_B receptor desensitization. Since the GABA_B receptor is an integral membrane protein, solubilizing GABA_BR2 is difficult. To circumvent this problem and to identify specific phosphatases that dephosphorylate S783, we employed an in vitro assay based on dephosphorylation of proteins on PVDF membranes by purified phosphatases. Our method allowed us to demonstrate that S783 in GABA_BR2 is directly dephosphorylated by PP2A (but not by PP1, PP2B nor PP2C) in a dose-dependent and okadaic acid-sensitive manner. We also show that the level of phosphorylation of the catalytic subunit of AMPK at T172 is reduced by PP1, PP2A and PP2C. Our data indicate that PP2A dephosphorylates GABA_BR2(S783) less efficiently than AMPK(T172), and that additional phosphatases might be involved in S783 dephosphorylation.     

The role of Cullin3-mediated ubiquitination of the catalytic subunit of PP2A in TRAIL signaling

Protein phosphatase 2A (PP2A) is the major serine-threonine phosphatase that regulates a number of cell signaling pathways. PP2A activity is controlled partially through protein degradation; however, the underlying mechanism is not fully understood. Here we show that PP2A/C, a catalytic subunit of PP2A, is degraded by the Cullin3 (Cul3) ligase-mediated ubiquitin-proteasome pathway. In response to death receptor signaling by tumor-necrosis factor-related apoptosis-inducing ligand (TRAIL), PP2A/C, caspase-8 and Cul3, a subunit of the cullin family of E3 ligases, are recruited into the death-inducing signaling complex (DISC) where the Cul3 ligase targets PP2A/C for ubiquitination and subsequent degradation. Functionally, knockdown of PP2A/C expression by siRNA or pharmacological inhibition of PP2A activity increases TRAIL-induced apoptosis. In cancer cells that have developed acquired TRAIL resistance, PP2A phosphatase activity is increased, and PP2A/C protein is resistant to TRAIL-induced degradation. Thus, this work identifies a new mechanism by which PP2A/C is regulated by Cul3 ligase-mediated degradation in response to death receptor signaling and suggests that inhibition of PP2A/C degradation may contribute to resistance of cancer cells to death receptor-induced apoptosis.