Proteomic Analysis Reveals a Role for Bcl2-associated Athanogene 3 and Major Vault Protein in Resistance to Apoptosis in Senescent Cells by Regulating ERK1/2 Activation

Senescence is a prominent solid tumor response to therapy in which cells avoid apoptosis and instead enter into prolonged cell cycle arrest. We applied a quantitative proteomics screen to identify signals that lead to therapy-induced senescence and discovered that Bcl2-associated athanogene 3 (Bag3) is up-regulated after adriamycin treatment in MCF7 cells. Bag3 is a member of the BAG family of co-chaperones that interacts with Hsp70. Bag3 also regulates major cell-signaling pathways. Mass spectrometry analysis of the Bag3 Complex revealed a novel interaction between Bag3 and Major Vault Protein (MVP). Silencing of Bag3 or MVP shifts the cellular response to adriamycin to favor apoptosis. We demonstrate that Bag3 and MVP contribute to apoptosis resistance in therapy-induced senescence by increasing the level of activation of extracellular signal-regulated kinase1/2 (ERK1/2). Silencing of either Bag3 or MVP decreased ERK1/2 activation and promoted apoptosis in adriamycin-treated cells. An increase in nuclear accumulation of MVP is observed during therapy-induced senescence and the shift in MVP subcellular localization is Bag3-dependent. We propose a model in which Bag3 binds to MVP and facilitates MVP accumulation in the nucleus, which sustains ERK1/2 activation. We confirmed that silencing of Bag3 or MVP shifts the response toward apoptosis and regulates ERK1/2 activation in a panel of diverse breast cancer cell lines. This study highlights Bag3-MVP as an important complex that regulates a potent prosurvival signaling pathway and contributes to chemotherapy resistance in breast cancer.Cellular senescence plays an important role in determining the response of tumors to cancer therapy (1). Senescence is regulated by the p53 and p16-pRB tumor suppressor pathways and characterized by irreversible cell cycle arrest and expression of the lysosomal protein, senescence associated beta galactosidase (SA-β-gal)¹. Additional characteristics of senescent cells include the presence of senescence-associated heterochromatic foci, and a senescence associated secretory phenotype (SASP) (2). Because of the SASP of senescent cells, therapy-induced senescence (TIS) may be harmful in cancer and the quantitative elimination of senescent cells could prove to be therapeutically beneficial. A recent study demonstrated that pharmacologically targeting the metabolic pathways of TIS in vivo prompted tumor regression and improved treatment outcomes (3).A characteristic of senescent cells is their ability to resist apoptosis although the responsible mechanism is poorly understood. Impairment of apoptosis in senescent cells is associated with a poor outcome in cancer (4). Manipulation of the apoptotic machinery may serve as a therapeutic means of eliminating senescent cells with harmful SASP. It has been proposed that in senescent cells, p53 may preferentially activate genes that arrest proliferation, rather than those that facilitate apoptosis. Alternatively, resistance to apoptosis may be caused by altered expression of proteins that inhibit, promote, or mediate apoptotic cell death, such as Bcl2.Bcl2 associated athanogene 3 (Bag3) is a member of the BAG family of chaperones that interacts with the ATPase domain of heat shock protein-70 (Hsp70). In addition to its BAG domain, Bag3 contains a WW domain and a proline-rich (PXXP) repeat, which mediates binding to partners other than Hsp70. Bag3 is expressed in response to cellular stress under the induction of HSF1 and is known to suppress apoptosis and regulate autophagy (5–6). Suppression of apoptosis may be partially explained by the ability of Bag3 to protect Bcl2 family members against proteasomal degradation (7). In normal cells, Bag3 is constitutively expressed in only a few cell types, including cardiomyocytes (8). Bag3 is overexpressed in leukemia and several solid tumors where it has been reported to sustain cell survival, induce resistance to therapy, and promote metastasis. The pleiotropic functions of Bag3 may reflect its ability to assemble scaffolding complexes, which participate in multiple signal transduction pathways (9).In this study, we describe a role for Bag3 in regulating cancer chemotherapy induced senescence in breast cancer cell. Using a quantitative SILAC approach, we show that Bag3 is up-regulated in TIS. Mass spectrometry analysis reveals that Bag3 binds to the Major Vault Protein (MVP) complex, a protein complex strongly associated with chemotherapy resistance. We also show that Bag3 and MVP contribute to apoptosis resistance by regulating ERK1/2 signaling in senescent MCF7 and ZR751 cells.     

Proteomic Profiling of the TRAF3 Interactome Network Reveals a New Role for the ER-to-Golgi Transport Compartments in Innate Immunity

Tumor Necrosis Factor receptor-associated factor-3 (TRAF3) is a central mediator important for inducing type I interferon (IFN) production in response to intracellular double-stranded RNA (dsRNA). Here, we report the identification of Sec16A and p115, two proteins of the ER-to-Golgi vesicular transport system, as novel components of the TRAF3 interactome network. Notably, in non-infected cells, TRAF3 was found associated with markers of the ER-Exit-Sites (ERES), ER-to-Golgi intermediate compartment (ERGIC) and the cis-Golgi apparatus. Upon dsRNA and dsDNA sensing however, the Golgi apparatus fragmented into cytoplasmic punctated structures containing TRAF3 allowing its colocalization and interaction with Mitochondrial AntiViral Signaling (MAVS), the essential mitochondria-bound RIG-I-like Helicase (RLH) adaptor. In contrast, retention of TRAF3 at the ER-to-Golgi vesicular transport system blunted the ability of TRAF3 to interact with MAVS upon viral infection and consequently decreased type I IFN response. Moreover, depletion of Sec16A and p115 led to a drastic disorganization of the Golgi paralleled by the relocalization of TRAF3, which under these conditions was unable to associate with MAVS. Consequently, upon dsRNA and dsDNA sensing, ablation of Sec16A and p115 was found to inhibit IRF3 activation and anti-viral gene expression. Reciprocally, mild overexpression of Sec16A or p115 in Hec1B cells increased the activation of IFNβ, ISG56 and NF-κB -dependent promoters following viral infection and ectopic expression of MAVS and Tank-binding kinase-1 (TBK1). In line with these results, TRAF3 was found enriched in immunocomplexes composed of p115, Sec16A and TBK1 upon infection. Hence, we propose a model where dsDNA and dsRNA sensing induces the formation of membrane-bound compartments originating from the Golgi, which mediate the dynamic association of TRAF3 with MAVS leading to an optimal induction of innate immune responses.     

AMPK Interactome Reveals New Function in Non-homologous End Joining DNA Repair

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Highlights

• •Each component of the AMPK trimeric complex was profiled by interaction proteomics.
• •The subunit composition of the AMPK complex directs interactions to distinct proteins.
• •AMPK interacts with Artemis and plays a role in Non-Homologous End Joining.

     

Sequential Elution Interactome Analysis of the Mind Bomb 1 Ubiquitin Ligase Reveals a Novel Role in Dendritic Spine Outgrowth

The mind bomb 1 (Mib1) ubiquitin ligase is essential for controlling metazoan development by Notch signaling and possibly the Wnt pathway. It is also expressed in postmitotic neurons and regulates neuronal morphogenesis and synaptic activity by mechanisms that are largely unknown. We sought to comprehensively characterize the Mib1 interactome and study its potential function in neuron development utilizing a novel sequential elution strategy for affinity purification, in which Mib1 binding proteins were eluted under different stringency and then quantified by the isobaric labeling method. The strategy identified the Mib1 interactome with both deep coverage and the ability to distinguish high-affinity partners from low-affinity partners. A total of 817 proteins were identified during the Mib1 affinity purification, including 56 high-affinity partners and 335 low-affinity partners, whereas the remaining 426 proteins are likely copurified contaminants or extremely weak binding proteins. The analysis detected all previously known Mib1-interacting proteins and revealed a large number of novel components involved in Notch and Wnt pathways, endocytosis and vesicle transport, the ubiquitin-proteasome system, cellular morphogenesis, and synaptic activities. Immunofluorescence studies further showed colocalization of Mib1 with five selected proteins: the Usp9x (FAM) deubiquitinating enzyme, alpha-, beta-, and delta-catenins, and CDKL5. Mutations of CDKL5 are associated with early infantile epileptic encephalopathy-2 (EIEE2), a severe form of mental retardation. We found that the expression of Mib1 down-regulated the protein level of CDKL5 by ubiquitination, and antagonized CDKL5 function during the formation of dendritic spines. Thus, the sequential elution strategy enables biochemical characterization of protein interactomes; and Mib1 analysis provides a comprehensive interactome for investigating its role in signaling networks and neuronal development.Mind bomb 1 (Mib1)¹, an E3 ubiquitin ligase, is a critical regulator of metazoan development with a large, and ever expanding, number of functions through interactions with a variety of protein partners. Mib1 mutants were first found in zebrafish mutagenesis screens (1), in which the mutants had neurogenic defects, most notably supernumerary primary neurons, and additional deficits in the development of somites (2), ear (3), and vasculature (4). These phenotypes are predominantly the consequences of impaired Notch signaling, as Mib1 is an essential activator of Notch Delta/Serrate/lag-2 (DSL) ligands (1). Mib1 also controls the development of several other organ and tissue systems, including gastrointestinal tract (5), limb bud (6), and the immune system (7). Mib1 is highly conserved across species. For instance, zebrafish Mib1 protein is 68%, 94%, and 94% identical to its fly, mouse, and human orthologs, respectively (8). Moreover, Mib1 has a paralog (Mib2) that shares 38% identical protein sequence with Mib1 in mouse (9). Mib2 is only abundantly expressed in adult tissue, however, and thus does not function in early development. Consistently, Mib1 knockout in mice results in embryonic mortality (10), whereas Mib2 deletion has no obvious effect on mouse development (6).In addition to its role in cell fate determination during early development, Mib1 is also abundantly expressed in the adult brain (11) and plays an important role in neuronal morphogenesis (12). Neurons usually have two basic polarized structures, a single extended axon for sending signals and multiple branched dendrites (or more precisely, the somatodendritic compartment) for receiving signals. Many principle neurons in mammals further grow dendritic spines that are tiny protrusions extended from dendritic branches, creating local postsynaptic compartments for the formation of excitatory synapses. In these synapses, the postsynaptic density (PSD) is an electron-dense membrane thickening aligned with the presynaptic active zone at synaptic junctions. During neuronal morphogenesis, axonal growth and path finding (13), dendrite formation (14), dendritic spine assembly (15), and synaptogenesis (16) are independent but highly related processes controlled by genetic elements and environmental cues. Although dramatic progress has been made in identifying the signaling cascades responsible for these processes, large gaps still remain in the connection of individual signaling components as well as in the coordination of multiple pathways. Our previous proteomics analysis identified that Mib1 is highly enriched in the PSD fraction, and regulates neurite outgrowth in postmitotic neurons (12). Mib1 conditional knockout mouse studies suggest a role in long-term potentiation (LTP) and synaptic plasticity (11), and further intriguing actions of Mib1 continue to be discovered. Mib1 was found to mediate the degradation of survival motor neuron 1 (SMN1), which contributes to spinal muscular atrophy (17). Mib1 was reported to be essential for Wnt3A activation of beta-catenin signaling through the receptor RYK (18), and a recent yeast two-hybrid screen indicated that Mib1 interacts with 81 candidate proteins beyond the canonical Notch pathway (19). The ongoing identification of new Mib1 interaction partners and functions underscores the need to characterize the Mib1 interactome en masse with high confidence.The combination of affinity purification and liquid chromatography-tandem mass spectrometry (LC-MS/MS) has emerged as a powerful method for analyzing protein interaction networks. Technological advances in LC-MS/MS have continually increased the sensitivity of protein detection (20, 21), allowing for the analysis of complex samples (22). The primary advantage of this technique, however, has also proven to be its greatest weakness: without stringent washes and data filtering, a vast number of false positives are included in the resulting data sets (23). Methods such as tandem-affinity purification (24) have been developed to remove nonspecific contaminants, but two-step purification requires large quantities of starting materials and reduces sensitivity to loosely bound proteins. Removing contaminants by buffers containing high concentrations of salt and detergents can help limit false positives, but a delicate balance lies between rinsing contaminants and losing weakly bound but true interaction partners, and thus inflating false negative results. In addition, in vivo crosslinking and quantitative analysis are used to enhance the capture of transient interacting proteins (25, 26).To this end, we attempted to characterize the Mib1 interactome by combining glutathione S-transferase (GST) protein affinity purification and advanced quantitative mass spectrometry. In our sequential elution strategy, Mib1 interaction partners were bound to affinity resins coated with GST-Mib1 domains, then eluted in three sequential buffers of increasing stringency. Proteins in these three eluents were identified and quantified by an isobaric labeling Tandem Mass Tag (TMT) method (15). The elution profile of each protein reflected its binding affinity to the GST-Mib1 resins. The strategy not only provides high sensitivity to recover weakly bound partners, but also allows for the affinity-based classification of the interactome and the removal of contaminants. By this approach, we were able to recover 817 putative Mib1 binding partners in adult rat brain and accepted about half of the proteins with high confidence. This study also uncovered that Mib1 interacts with CDKL5, a protein kinase implicated in early infantile epileptic encephalopathy-2 (EIEE2), a severe form of epilepsy and mental retardation in females (28). We then found that Mib1 acts to down-regulate CDKL5 and inhibits its promotion of dendritic spine outgrowth.     

Interactome Analysis of Microtubule-targeting Agents Reveals Cytotoxicity Bases in Normal Cells

Cancer causes millions of deaths annually and microtubule-targeting agents(MTAs) are the most commonly-used anti-cancer drugs. However, the high toxicity of MTAs on normal cells raises great concern. Due to the non-selectivity of MTA targets, we analyzed the interaction network in a non-cancerous human cell. Subnetworks of fourteen MTAs were reconstructed and the merged network was compared against a randomized network to evaluate the functional richness. We found that 71.4% of the MTA interactome nodes are shared, which affects cellular processes such as apoptosis, cell differentiation, cell cycle control, stress response, and regulation of energy metabolism. Additionally, possible secondary targets were identi?ed as client proteins of interphase microtubules. MTAs affect apoptosis signaling pathways by interacting with client proteins of interphase microtubules, suggesting that their primary targets are non-tumor cells. The paclitaxel and doxorubicin networks share essential topological axes, suggesting synergistic effects.This may explain the exacerbated toxicity observed when paclitaxel and doxorubicin are used in combination for cancer treatment.     

Structure of a BAG6 (Bcl-2-associated Athanogene 6)-Ubl4a (Ubiquitin-like Protein 4a) Complex Reveals a Novel Binding Interface That Functions in Tail-anchored Protein Biogenesis

BAG6 is an essential protein that functions in two distinct biological pathways, ubiquitin-mediated protein degradation of defective polypeptides and tail-anchored (TA) transmembrane protein biogenesis in mammals, although its structural and functional properties remain unknown. We solved a crystal structure of the C-terminal heterodimerization domains of BAG6 and Ubl4a and characterized their interaction biochemically. Unexpectedly, the specificity and structure of the C terminus of BAG6, which was previously classified as a BAG domain, were completely distinct from those of the canonical BAG domain. Furthermore, the tight association of BAG6 and Ubl4a resulted in modulation of Ubl4a protein stability in cells. Therefore, we propose to designate the Ubl4a-binding region of BAG6 as the novel BAG-similar (BAGS) domain. The structure of Ubl4a, which interacts with BAG6, is similar to the yeast homologue Get5, which forms a homodimer. These observations indicate that the BAGS domain of BAG6 promotes the TA protein biogenesis pathway in mammals by the interaction with Ubl4a.     

Proteomic identification of Bcl2-associated athanogene 2 as a novel MAPK-activated protein kinase 2 substrate

The p38 MAPK cascade is activated by various stresses or cytokines. Downstream of p38 MAPKs, there are diversification and extensive branching of signaling pathways. Fluorescent two-dimensional difference gel electrophoresis of phosphoprotein-enriched samples from HeLa cells in which p38 MAPK activity was either suppressed or activated enabled us to detect approximately 90 candidate spots for factors involved in p38-dependent pathways. Among these candidates, here we identified four proteins including Bcl-2-associated athanogene 2 (BAG2) by peptide mass fingerprintings. BAG family proteins are highly conserved throughout eukaryotes and regulate Hsc/Hsp70-mediated molecular chaperone activities and apoptosis. The results of two-dimensional immunoblots suggested that the phosphorylation of BAG2 was specifically controlled in a p38 MAPK-dependent manner. Furthermore, BAG2 was directly phosphorylated at serine 20 in vitro by MAPK-activated protein kinase 2 (MAPKAP kinase 2), which is known as a primary substrate of p38 MAPK and mediates several p38 MAPK-dependent processes. We confirmed that MAPKAP kinase 2 is also required for phosphorylation of BAG2 in vivo. Thus, p38 MAPK-MAPKAP kinase 2-BAG2 phosphorylation cascade may be a novel signaling pathway for response to extracellular stresses.     

Involvement of a chaperone regulator, Bcl2-associated athanogene-4, in apolipoprotein B mRNA editing

Apobec-1 is the catalytic subunit of a multicomponent editosome complex that mediates apolipoprotein B (apoB) mRNA editing. We isolated a novel apobec-1-interacting protein by yeast two-hybrid cloning and identified the protein as BAG-4. BAG-4, a chaperone-regulating protein, also known as SODD (silencer of death domains), is a member of the BAG family of proteins. In this report, we found that apobec-1 is localized in the perinucleolar compartment in HepG2 cells and rat liver MCR-RH7777 cells. BAG-4 binds to apobec-1 via its N-terminal region independent of the BAG domain. It is ubiquitously expressed with predominant occurrence in human pancreas, heart, brain, and placenta. Immunoprecipitation experiments confirmed that BAG-4 interacts with Hsc70/Hsp90 in HepG2 cells. BAG-4 tagged with green fluorescent protein (GFP) or FLAG was localized both in cytoplasm of mouse BNLCL.2 liver cells and human liver hepatoma HepG2 cells. After heat shock, GFP-BAG-4 co-localizes with Hsc70 in the nucleus in HepG2 cells, whereas GFP-BAG-4 mutants lacking the BAG domain remain perinuclear. BAG-4 has no effects on apoB mRNA editing in vitro. However, unlike other apobec-1 complementation factors studied to date, antisense knockdown of BAG-4 in BNLCL.2 cells and in MCR-RH7777 cells increases rather than decreases endogenous apoB mRNA editing. Overexpression of BAG-4 in MCR-RH7777 cells also suppresses apoB mRNA editing. ApoB-48 production also increases with antisense BAG-4 expression in MCR-RH7777 cells. We previously showed that apoB mRNA editing is an intranuclear event (Lau, P. P., Xiong, W. J., Zhu, H. J., Chen, S. H., and Chan, L. (1991) J. Biol. Chem. 266, 20550-20554). Thus, BAG-4 overexpression down-regulates apoB mRNA editing by shuttling apobec-1 from the intranuclear perinucleolar compartment to the cytoplasm. We propose that BAG-4 functions as a negative regulator for apobec-1-mediated apoB mRNA editing through its ability to suppress the Hsp/Hsc70 chaperone activity and thereby editosome formation and, as a consequence, prevents nuclear localization of the apobec-1 editosome.     

Caspase-3 Cleaves Specific 19 S Proteasome Subunits in Skeletal Muscle Stimulating Proteasome Activity

With muscle wasting, caspase-3 activation and the ubiquitin-proteasome system act synergistically to increase the degradation of muscle proteins. Whether proteasome activity is also elevated in response to catabolic conditions is unknown. We find that caspase-3 increases proteasome activity in myotubes but not in myoblasts. This difference is related to the cleavage of specific 19 S proteasome subunits. In mouse muscle or myotubes, caspase-3 cleaves Rpt2 and Rpt6 increasing proteasome activity. In myoblasts, caspase-3 cleaves Rpt5 to decrease proteasome activity. To confirm the caspase-3 dependence, caspase-3 cleavage sites in Rpt2, Rpt6, or Rpt5 were mutated. This prevented the cleavage of these subunits by caspase-3 as well as the changes in proteasome activity. During differentiation of myoblasts to myotubes, there is an obligatory, transient increase in caspase-3 activity, accompanied by a corresponding increase in proteasome activity and cleavage of Rpt2 and Rpt6. Therefore, differentiation changes the proteasome type from sensitivity of Rpt5 to caspase-3 in myoblasts to sensitivity of Rpt2 and Rpt6 in myotubes. This novel mechanism identifies a feed-forward amplification that augments muscle proteolysis in catabolic conditions. Indeed, we found that in mice with a muscle wasting condition, chronic kidney disease, there was cleavage of subunits Rpt2 and Rpt6 and stimulation of proteasome activity.     

Notch3 Interactome Analysis Identified WWP2 as a Negative Regulator of Notch3 Signaling in Ovarian Cancer

The Notch3 signaling pathway is thought to play a critical role in cancer development, as evidenced by the Notch3 amplification and rearrangement observed in human cancers. However, the molecular mechanism by which Notch3 signaling contributes to tumorigenesis is largely unknown. In an effort to identify the molecular modulators of the Notch3 signaling pathway, we screened for Notch3-intracellular domain (N3-ICD) interacting proteins using a human proteome microarray. Pathway analysis of the Notch3 interactome demonstrated that ubiquitin C was the molecular hub of the top functional network, suggesting the involvement of ubiquitination in modulating Notch3 signaling. Thereby, we focused on functional characterization of an E3 ubiquitin-protein ligase, WWP2, a top candidate in the Notch3 interactome list. Co-immunoprecipitation experiments showed that WWP2 interacted with N3-ICD but not with intracellular domains from other Notch receptors. Wild-type WWP2 but not ligase-deficient mutant WWP2 increases mono-ubiquitination of the membrane-tethered Notch3 fragment, therefore attenuating Notch3 pathway activity in cancer cells and leading to cell cycle arrest. The mono-ubiquitination by WWP2 may target an endosomal/lysosomal degradation fate for Notch3 as suggested by the fact that the process could be suppressed by the endosomal/lysosomal inhibitor. Analysis of The Cancer Genome Atlas dataset showed that the majority of ovarian carcinomas harbored homozygous or heterozygous deletions in WWP2 locus, and there was an inverse correlation in the expression levels between WWP2 and Notch3 in ovarian carcinomas. Furthermore, ectopic expression of WWP2 decreased tumor development in a mouse xenograft model and suppressed the Notch3-induced phenotypes including increase in cancer stem cell-like cell population and platinum resistance. Taken together, our results provide evidence that WWP2 serves as a tumor suppressor by negatively regulating Notch3 signaling in ovarian cancer.     

Characterization of the Cardiac Overexpression of HSPB2 Reveals Mitochondrial and Myogenic Roles Supported by a Cardiac HspB2 Interactome

Small Heat Shock Proteins (sHSPs) are molecular chaperones that transiently interact with other proteins, thereby assisting with quality control of proper protein folding and/or degradation. They are also recruited to protect cells from a variety of stresses in response to extreme heat, heavy metals, and oxidative-reductive stress. Although ten human sHSPs have been identified, their likely diverse biological functions remain an enigma in health and disease, and much less is known about non-redundant roles in selective cells and tissues. Herein, we set out to comprehensively characterize the cardiac-restricted Heat Shock Protein B-2 (HspB2), which exhibited ischemic cardioprotection in transgenic overexpressing mice including reduced infarct size and maintenance of ATP levels. Global yeast two-hybrid analysis using HspB2 (bait) and a human cardiac library (prey) coupled with co-immunoprecipitation studies for mitochondrial target validation revealed the first HspB2 “cardiac interactome” to contain many myofibril and mitochondrial-binding partners consistent with the overexpression phenotype. This interactome has been submitted to the Biological General Repository for Interaction Datasets (BioGRID). A related sHSP chaperone HspB5 had only partially overlapping binding partners, supporting specificity of the interactome as well as non-redundant roles reported for these sHSPs. Evidence that the cardiac yeast two-hybrid HspB2 interactome targets resident mitochondrial client proteins is consistent with the role of HspB2 in maintaining ATP levels and suggests new chaperone-dependent functions for metabolic homeostasis. One of the HspB2 targets, glyceraldehyde 3-phosphate dehydrogenase (GAPDH), has reported roles in HspB2 associated phenotypes including cardiac ATP production, mitochondrial function, and apoptosis, and was validated as a potential client protein of HspB2 through chaperone assays. From the clientele and phenotypes identified herein, it is tempting to speculate that small molecule activators of HspB2 might be deployed to mitigate mitochondrial related diseases such as cardiomyopathy and neurodegenerative disease.     

FXYD2c Plays a Potential Role in Modulating Na+/K+-ATPase Activity in HK-2 Cells Upon Hypertonic Challenge

Na⁺/K⁺-ATPase (NKA) is a widely found and important transporter in mammals. The kidney is a major osmoregulatory organ of which the proximal tubules play a crucial role in the maintenance of ionic homeostasis functioning via salt and water reabsorption. FXYD (FXYD domain-containing protein) 2, the γ-subunit of NKA, is the first identified and the most abundant member of FXYD family, affecting the sodium/potassium affinity of NKA in the kidney. Based on DNA microarray analysis, the expression levels of fxyd2 gene are markedly increased upon hypertonic challenge. Combined with bioinformatic analysis using the NCBI database, we identified an unnamed protein with 145 amino acids, of which the N-terminus involved the FXYD sequence similar to FXYD2a and FXYD2b, and thus, named as FXYD2c. However, the role of FXYD2c protein in the regulation of NKA expression in the kidney has not been elucidated. In this study, we found that the mRNA and protein levels of FXYD2c were significantly increased upon hypertonic challenge. Immunoprecipitation data revealed that FXYD2c interacts with the NKA α1 subunit. Subsequently, the functional inhibition of fxyd2c using short hairpin RNA abrogated NKA activity. Taken together, our study offers novel insight into the potential function of FXYD2c in promoting NKA activity upon hypertonic challenge in HK-2 cells.     

A Novel Phosphopeptide Microarray Based Interactome Map in Breast Cancer Cells Reveals Phosphoprotein-GRB2 Cell Signaling Networks

The architecture of cellular proteins connected to form signaling pathways in response to internal and external cues is much more complex than a group of simple protein-protein interactions. Post translational modifications on proteins (e.g., phosphorylation of serine, threonine and tyrosine residues on proteins) initiate many downstream signaling events leading to protein-protein interactions and subsequent activation of signaling cascades leading to cell proliferation, cell differentiation and cell death. As evidenced by a rapidly expanding mass spectrometry database demonstrating protein phosphorylation at specific motifs, there is currently a large gap in understanding the functional significance of phosphoproteins with respect to their specific protein connections in the signaling cascades. A comprehensive map that interconnects phospho-motifs in pathways will enable identification of nodal protein interactions that are sensitive signatures indicating a disease phenotype from the physiological hemostasis and provide clues into control of disease. Using a novel phosphopeptide microarray technology, we have mapped endogenous tyrosine-phosphoproteome interaction networks in breast cancer cells mediated by signaling adaptor protein GRB2, which transduces cellular responses downstream of several RTKs through the Ras-ERK signaling cascade. We have identified several previously reported motif specific interactions and novel interactions. The peptide microarray data indicate that various phospho-motifs on a single protein are differentially regulated in various cell types and shows global downregulation of phosphoprotein interactions specifically in cells with metastatic potential. The study has revealed novel phosphoprotein mediated signaling networks, which warrants further detailed analysis of the nodes of protein-protein interaction to uncover their biomarker or therapeutic potential.     

Aging Reveals a Role for Nigral Tyrosine Hydroxylase ser31 Phosphorylation in Locomotor Activity Generation

Background

Tyrosine hydroxylase (TH) regulates dopamine (DA) bioavailability. Its product, L-DOPA, is an established treatment for Parkinson''s disease (PD), suggesting that TH regulation influences locomotion. Site-specific phosphorylation of TH at ser31 and ser40 regulates activity. No direct evidence shows that ser40 phosphorylation is the dominating mechanism of regulating TH activity in vivo, and physiologically-relevant stimuli increase L-DOPA biosynthesis independent of ser40 phosphorylation. Significant loss of locomotor activity occurs in aging as in PD, despite less loss of striatal DA or TH in aging compared to the loss associated with symptomatic PD. However, in the substantia nigra (SN), there is equivalent loss of DA or TH in aging and at the onset of PD symptoms. Growth factors increase locomotor activity in both PD and aging models and increase DA bioavailability and ser31 TH phosphorylation in SN, suggesting that ser31 TH phosphorylation status in the SN, not striatum, regulates DA bioavailability necessary for locomotor activity.

Methodology and Principal Findings

We longitudinally characterized locomotor activity in young and older Brown-Norway Fischer 344 F₁ hybrid rats (18 months apart in age) at two time periods, eight months apart. The aged group served as an intact and pharmacologically-naïve source of deficient locomotor activity. Following locomotor testing, we analyzed DA tissue content, TH protein, and TH phosphorylation in striatum, SN, nucleus accumbens, and VTA. Levels of TH protein combined with ser31 phosphorylation alone reflected inherent differences in DA levels among the four regions. Measures strictly pertaining to locomotor activity initiation significantly correlated to DA content only in the SN. Nigral TH protein and ser31 phosphorylation together significantly correlated to test subject''s maximum movement number, horizontal activity, and duration.

Conclusions/Significance

Together, these results show ser31 TH phosphorylation regulates DA bioavailability in intact neuropil, its status in the SN may regulate locomotor activity generation, and it may represent an accurate target for treating locomotor deficiency. They also show that neurotransmitter regulation in cell body regions can mediate behavioral outcomes and that ser31 TH phosphorylation plays a role in behaviors dependent upon catecholamines, such as dopamine.     

A Golgi PKD Activity Reporter Reveals a Crucial Role of PKD in Nocodazole-Induced Golgi Dispersal

The protein kinase D (PKD) family comprises multifunctional serine/threonine-specific protein kinases with three mammalian isoforms: PKD1, PKD2 and PKD3. A prominent PKD function is the regulation of basolateral-targeted transport carrier fission from the trans -Golgi network (TGN). To visualize site-specific PKD activation at this organelle, we designed a molecular reporter consisting of a PKD-specific substrate sequence fused to enhanced green fluorescent protein (EGFP), specifically targeted to the TGN via the p230 GRIP domain. Quantitative analyses using a phosphospecific antibody and ratiometric fluorescence imaging revealed that Golgi-specific phosphorylation of the reporter was strictly dependent on stimulation of endogenous PKD or transient expression of active PKD constructs. Conversely, PKD-specific pharmacological inhibitors and siRNA-mediated PKD knockdown suppressed reporter phosphorylation. Using this reporter we investigated a potential role for PKD in the regulation of Golgi complex morphology. Interestingly, nocodazole-induced Golgi complex break-up and dispersal was associated with local PKD activation as measured by reporter phosphorylation and this was efficiently blocked by expression of a dominant-negative PKD mutant or PKD depletion. Our data thus identify a novel link between PKD activity and the microtubule cytoskeleton, whereby Golgi complex integrity is regulated.