Vinculin but not α-actinin is a target of PKC phosphorylation during junctional assembly induced by calcium
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ABSTRACT The establishment of the junctional complex in epithelial cells requires the presence of extracellular calcium, and is controlled by a network of reactions involving G-proteins, phospholipase C and protein kinase C. Since potential candidates for phosphorylation are the tight junction associated proteins ZO1, ZO2 and ZO3, in a previous work we specifically explored these molecules but found no alteration in their phosphorylation pattern. To continue the search for the target of protein kinase C, in the present work we have studied the subcellular distribution and phosphorylation of vinculin and α-actinin, two actin binding proteins of the adherent junctions. We found that during the junctional sealing induced by Ca2+, both proteins move towards the cell periphery and, while there is a significant increase in the phosphorylation of vinculin, α-actinin remains unchanged. The increased phosphorylation of vinculin is due to changes in phosphoserine and phosphothreonine content and seems to be regulated by protein kinase C, since: (1) DiC8 (a kinase C stimulator) added to monolayers cultured without calcium significantly increases the vinculin phosphorylation level; (2) H7 and calphostin C (both protein kinase C inhibitors) completely abolish this increase during a calcium switch; (3) inhibition of phosphorylation during a calcium switch blocks the subcellular redistribution of vinculin and α-actinin. These results therefore suggest that vinculin phosphorylation by protein kinase C is a crucial step in the correct assembly of the epithelial junctional complex.Keywords:
Vinculin
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Abstract Human progesterone receptor (PR) is phosphorylated on multiple serine residues (at least seven sites) in a manner that involves distinct groups of sites coordinately regulated by hormone and different kinases. Progress on defining a functional role for PR phosphorylation has been hampered both by the complexity of phosphorylation and the lack of simple, nonradioactive methods to detect the influence of ligands and other signaling pathways on specific PR phosphorylation sites in vivo. Toward this end, we have produced monoclonal antibodies (MAbs) that recognize specific phosphorylation sites within human PR including a basal site at Ser 190 (MAb P190) and a hormone-induced site at Ser 294 (MAb P294). Biochemical experiments showed the differential reactivity of the P190 and P294 MAbs for phosphorylated and unphosphorylated forms of PR. Both MAbs recognize specific phosphorylated forms of PR under different experimental conditions including denatured PR protein by Western blots and PR in its native conformation in solution or complexed to specific target DNA. As detected by Western blot of T47D cells treated with hormone for different times, hormone-dependent down-regulation of total PR and the Ser 190 phosphorylation site occurred in parallel, whereas the Ser 294 phosphorylation site was down-regulated more rapidly. This difference in kinetics suggests that the Ser 294 site is more labile than basal sites and is acted upon by distinct phosphatases. A strong preferential hormone-dependent phosphorylation of Ser 294 was observed on PR-B as compared with the amino-terminal truncated A form of PR. This was unexpected because Ser 294 and flanking sequences are identical on both proteins, suggesting that a distinct conformation of the N-terminal domain of PR-A inhibits phosphorylation of this site. That Ser 294 lies within an inhibitory domain that mediates the unique repressive functions of PR-A raises the possibility that differential phosphorylation of Ser 294 is involved in the distinct functional properties of PR-A and PR-B.
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Post-translational phosphorylation is one of the most common protein modifications. Phosphoserine, threonine and tyrosine residues play critical roles in the regulation of many cellular processes. The fast growing number of research reports on protein phosphorylation points to a general need for an accurate database dedicated to phosphorylation to provide easily retrievable information on phosphoproteins. Phospho.ELM http://phospho.elm.eu.org is a new resource containing experimentally verified phosphorylation sites manually curated from the literature and is developed as part of the ELM (Eukaryotic Linear Motif) resource. Phospho.ELM constitutes the largest searchable collection of phosphorylation sites available to the research community. The Phospho.ELM entries store information about substrate proteins with the exact positions of residues known to be phosphorylated by cellular kinases. Additional annotation includes literature references, subcellular compartment, tissue distribution, and information about the signaling pathways involved as well as links to the molecular interaction database MINT. Phospho.ELM version 2.0 contains 1703 phosphorylation site instances for 556 phosphorylated proteins. Phospho.ELM will be a valuable tool both for molecular biologists working on protein phosphorylation sites and for bioinformaticians developing computational predictions on the specificity of phosphorylation reactions.
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Protein phosphorylation is involved in posttranslational control of essentially all biological processes. Using mass spectrometry, recent analyses of whole phosphoproteomes led to the identification of numerous new phosphorylation sites. However, the function of most of these sites remained unknown. We chose the Drosophila Bicaudal-D protein to estimate the importance of individual phosphorylation events. Being involved in different cellular processes, BicD is required for oocyte determination, for RNA transport during oogenesis and embryogenesis, and for photoreceptor nuclei migration in the developing eye. The numerous roles of BicD and the available evidence for functional importance of BicD phosphorylation led us to identify eight phosphorylation sites of BicD, and we tested a total of 14 identified and suspected phosphoserine residues for their functional importance in vivo in flies. Surprisingly, all these serines turned out to be dispensable for providing sufficient basal BicD activity for normal growth and development. However, in a genetically sensitized background where the BicDA40V protein variant provides only partial activity, serine 103 substitutions are not neutral anymore, but show surprising differences. The S103D substitution completely inactivates the protein, whereas S103A behaves neutral, and the S103F substitution, isolated in a genetic screen, restores BicDA40V function. Our results suggest that many BicD phosphorylation events may either be fortuitous or play a modulating function as shown for Ser103. Remarkably, amongst the Drosophila serines we found phosphorylated, Ser103 is the only one that is fully conserved in mammalian BicD.
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BAD (Bcl-2 antagonist of cell death, Bcl-2 associated death promoter) is a pro-apoptotic member of the Bcl-2 protein family that is regulated by phosphorylation in response to survival factors. Although much attention has been devoted to the identification of phosphorylation sites in murine BAD (mBAD), little data are available with respect to phosphorylation of human BAD (hBAD) protein. In this work, we investigated the quantitative contribution of BAD targeting kinases in phosphorylating serines 75, 99 and 118 of hBAD (Chapter 3.1). Our results indicate that RAF kinases phosphorylate hBAD in vivo at these established serine residues. RAF-induced phosphorylation of hBAD was not prevented by MEK inhibitors but could be reduced to control levels by use of the RAF inhibitor Sorafenib (BAY 43-9006). Consistently, expression of active RAF suppressed apoptosis induced by hBAD and the inhibition of colony formation caused by hBAD could be prevented by RAF. In addition, using surface plasmon resonance technique we analyzed the direct consequences of hBAD phosphorylation by RAF with respect to complex formation of BAD with 14-3-3 proteins and Bcl-XL. Phosphorylation of hBAD by active RAF promotes 14-3-3 protein association, whereby the phosphoserine 99 represents the major binding site. Furthermore, we demonstrate in this work that hBAD forms channels in planar bilayer membranes in vitro. This pore-forming capacity is dependent on phosphorylation status and interaction with 14-3-3 proteins. Additionally, we show that hBAD pores possess a funnel-shaped geometry that can be entered by ions and non-charged molecules up to 200 Da (Chapter 3.2). Since both lipid binding domains of hBAD (LBD1 and LBD2) are located within the C-terminal region, we investigated this part of the protein with respect to its structural properties (Chapter 3.3). Our results demonstrate that the C-terminus of hBAD possesses an ordered β-sheet structure in aqueous solution that adopts helical disposition upon interaction with lipid membranes. Additionally, we show that the interaction of the C-terminal segment of hBAD with the BH3 domain results in the formation of permanently open pores, whereby the phosphorylation of serine 118 proved to be necessary for effective pore-formation. In contrast, phosphorylation of serine 99 in combination with 14-3-3 association suppresses formation of channels. These results indicate that the C-terminal part of hBAD controls hBAD function by structural transitions, lipid binding and phosphorylation. Using mass spectrometry we identified in this work, besides the established in vivo phosphorylation sites at serines 75, 99 and 118, several novel hBAD phosphorylation sites (serines 25, 32/34, 97, 124 and 134, Chapter 3.1). To further analyze the regulation of hBAD function, we investigated the role of these newly identified phosphorylation sites on BAD-mediated apoptosis. We found that in contrast to the N-terminal phosphorylation sites, the C-terminal serines 124 and 134 act in an anti-apoptotic manner (Chapter 3.4). Our results further indicate that RAF kinases and PAK1 effectively phosphorylate BAD at serine 134. Notably, in the presence of wild type hBAD, co-expression of survival kinases, such as RAF and PAK1, leads to a strongly increased proliferation, whereas substitution of serine 134 by alanine abolishes this process. Furthermore, we identified hBAD serine 134 to be strongly involved in survival signaling in B-RAF-V600E containing tumor cells and found phosphorylation of this residue to be crucial for efficient proliferation in these cells. Collectively, our findings provide new insights into the regulation of hBAD function by phosphorylation and its role in cancer signaling.
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The phosphorylation profile of ciliary proteins under basal conditions and after stimulation by extracellular ATP was investigated in intact tissue and in isolated cilia from porcine airway epithelium using anti-phosphoserine and anti-phosphothreonine specific antibodies. In intact tissue, several polypeptides were serine phosphorylated in the absence of any treatment (control conditions). After stimulation by extracellular ATP, changes in the phosphorylation pattern were detected on seven ciliary polypeptides. Serine phosphorylation was enhanced for three polypeptides (27, 37, and 44 kD), while serine phosphorylation was reduced for four polypeptides (35, 69, 100, and 130 kD). Raising intracellular Ca2+ with ionomycin induced identical changes in the protein phosphorylation profile. Inhibition of the NO pathway by inhibiting either NO synthase (NOS), guanylyl cyclase (GC), or cGMP-dependent protein kinase (PKG) abolished the changes in phosphorylation induced by ATP. The presence of PKG within the axoneme was demonstrated using a specific antibody. In addition, in isolated permeabilized cilia, submicromolar concentrations of cGMP induced protein phosphorylation. Taken together, these results suggest that the axoneme is an integral part of the intracellular NO pathway. The surprising observation that ciliary activation is accompanied by sustained dephosphorylation of ciliary proteins via NO pathway was not detected in isolated cilia, suggesting that the protein phosphatases were either lost or deactivated during the isolation procedure. This work reveals that any pharmacological manipulation that abolished phosphorylation and dephosphorylation also abolished the enhancement of ciliary beating. Thus, part or all of the phosphorylated polypeptides are likely directly involved in axonemal regulation of ciliary beating.
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The in vivo phosphorylation state of glycogen synthase was re‐examined by fast‐atom‐bombardment mass spectrometry and a procedure in which phosphoserine residues are first converted to S ‐ethylcysteine. In animals injected with the β‐adrenergic antagonist propranolol, the phosphorylation sites in the N‐terminal (N) and C‐terminal (C) cyanogen bromide peptides were identified as the serine residues at N7, the region C28‐C39, C42, C46 and C100. In animals injected with adrenalin, the phosphorylation of N7 increased from 0.6 to 0.8 mol/mol, the region C28‐C39 from 0.7 to 1.2 mol/mol and C100 from 0.3 to 0.6 mol/mol. The phosphorylation states of C42 (0.7 mol/mol) and C46 (0.9 mol/mol) were unchanged. In addition, two further serine residues became phosphorylated at positions N10 (0.5 mol/mol) and C87 (0.5 mol/mol), which were not phosphorylated in the absence of adrenalin. Residues N10 and C42 have not been recognized as in vivo sites of phosphorylation previously. The results suggest that N10 is phosphorylated by a novel protein kinase which may be activated by cyclic‐AMP‐dependent protein kinase. The phosphorylation of C42 is likely to be catalysed by glycogen synthase kinase 3. The protein kinases responsible for phosphorylating N7, the region C28–C39, C46, C87 and C100 in vivo and the molecular mechanisms by which adrenalin inactivates glycogen synthase in vivo are discussed. Residue N3, a major site phosphorylated by casein kinase‐I in vitro is not phosphorylated in vivo . This and other evidence indicates that casein kinase‐I is not a glycogen synthase kinase in vivo.
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Abstract The specific targeting of protein‐protein interactions by phosphoserine‐containing small molecules has been scarce due to the dephosphorylation of phosphoserine and its charged nature at physiological pH, which hinder its uptake into cells. To address these issues, we herein report the synthesis of phosphoserine aryloxy triester phosphoramidates as phosphoserine prodrugs that are enzymatically metabolized to release phosphoserine. This phosphoserine‐masking approach was applied to a phosphoserine‐containing inhibitor of 14‐3‐3 dimerization, and the generated prodrugs exhibited improved pharmacological activity. Collectively, this provided a proof of concept that the masking of phosphoserine with biocleavable aryloxy triester phosphoramidate masking groups is a viable intracellular delivery system for phosphoserine‐containing molecules. Ultimately, this will facilitate the discovery of phosphoserine‐containing small‐molecule therapeutics.
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The interaction between the Drosophila cadherins fat and dachsous is regulated by phosphorylation of their respective ectodomains, a process catalysed by the atypical kinase four‐jointed. Given that many signalling functions are conserved between Drosophila and vertebrate Fat cadherins, we sought to determine whether ectodomain phosphorylation is conserved in FAT1 cadherin, and also whether FJX1, the vertebrate orthologue of four‐jointed, was involved in such phosphorylation events. Potential Fj consensus phosphorylation motifs were identified in FAT1 and biochemical experiments revealed the presence of phosphoserine and phosphothreonine residues in its extracellular domain. However, silencing FJX1 did not influence the levels of FAT1 ectodomain phosphorylation, indicating that other mechanisms are likely responsible.
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