Spatiotemporal regulation of ERK2 by dual specificity phosphatases

Although many stimuli activate extracellular signal-regulated kinases 1 and 2 (ERK1/2), the kinetics and compartmentalization of ERK1/2 signals are stimulus-dependent and dictate physiological consequences. ERKs can be inactivated by dual specificity phosphatases (DUSPs), notably the MAPK phosphatases (MKPs) and atypical DUSPs, that can both dephosphorylate and scaffold ERK1/2. Using a cell imaging model (based on knockdown of endogenous ERKs and add-back of wild-type or mutated ERK2-GFP reporters), we explored possible effects of DUSPs on responses to transient or sustained ERK2 activators (epidermal growth factor and phorbol 12,13-dibutyrate, respectively). For both stimuli, a D319N mutation (which impairs DUSP binding) increased ERK2 activity and reduced nuclear accumulation. These stimuli also increased mRNA levels for eight DUSPs. In a short inhibitory RNA screen, 12 of 16 DUSPs influenced ERK2 responses. These effects were evident among nuclear inducible MKP, cytoplasmic ERK MKP, JNK/p38 MKP, and atypical DUSP subtypes and, with the exception of the nuclear inducible MKPs, were paralleled by corresponding changes in Egr-1 luciferase activation. Simultaneous removal of all JNK/p38 MKPs or nuclear inducible MKPs revealed them as positive and negative regulators of ERK2 signaling, respectively. The effects of JNK/p38 MKP short inhibitory RNAs were not dependent on protein neosynthesis but were reversed in the presence of JNK and p38 kinase inhibitors, indicating DUSP-mediated cross-talk between MAPK pathways. Overall, our data reveal that a large number of DUSPs influence ERK2 signaling. Together with the known tissue-specific expression of DUSPs and the importance of ERK1/2 in cell regulation, our data support the potential value of DUSPs as targets for drug therapy.     

Epitopes of human intestinal alkaline phosphatases, defined by monoclonal antibodies

Antibody additivity assayTopology     

Adhesion regulation of stromal cell-derived factor-1 activation of ERK in lymphocytes by phosphatases

We have investigated whether chemokine signaling to the extracellular-signal-regulated kinase (ERK) was regulated by beta 1-integrin-mediated adhesion in B- and T-cell lines. Activation of ERK by the chemokine SDF-1 can be regulated by adhesion to beta 1-integrin substrates in the T-cell lines MOLT-3, Jurkat, and H9 and in the Daudi B-cell line. In Jurkat T-cells, adhesion to the immobilized alpha 4 beta 1-integrin ligand VCAM-1 or to the alpha 5 beta 1-integrin ligand fibronectin regulated stromal-cell derived factor-1 (SDF-1) activation of ERK. Adhesion control of SDF-1 signaling was a rapid event, occurring as early as 10 min after adhesion, and loss of signaling occurred within 10 min of deadhesion. In contrast, SDF-1 activation of the ERK kinase MEK was independent of adhesion. Partial restoration of signaling to ERK in suspension was accomplished by pretreatment with pharmacological inhibitors of serine/threonine or protein-tyrosine phosphatases. In addition, we used a non-radioactive phosphatase assay using phosphorylated ERK as the substrate to determine relative ERK dephosphorylation in whole cell extracts. These results showed greater relative ERK dephosphorylation in extracts from Jurkat cells treated in suspension, as compared with adherent cells. Therefore, these data suggest that adhesion influences SDF-1 activation of ERK by regulating the activity of ERK phosphatases. This identifies a novel locus of adhesion regulation of the ERK cascade.     

Involvement of phosphatases in the anchorage-dependent regulation of ERK2 activation

Activation of extracellular signal-regulated kinase (ERK) is known to be regulated by cell adhesion, namely "anchorage dependence". Most studies on the anchorage-dependent regulation have focused on the upstream activating components. We previously reported that the focal adhesion protein vinexin beta can induce the anchorage-independent activation of ERK2. We show here that vinexin beta-induced anchorage-independent activation of ERK2 involves prevention of the dephosphorylation of ERK2, but not the promotion of MEK1 or Raf1 activity. Furthermore, knockdown of vinexin beta resulted in a faster dephosphorylation of ERK2 in A549 cells. Moreover, the coexpression of MKP3/rVH6, an ERK2 specific phosphatase, suppressed the anchorage-independent activation of ERK2 induced by vinexin beta. These results suggest that vinexin beta can prevent the dephosphorylation of ERK2 stimulated by cell detachment, leading to the anchorage-independent activation of ERK2. Furthermore, we found that phosphatase activity directed against activated ERK2 was higher in suspended cells than in adherent cells. In addition, orthovanadate efficiently induces anchorage-independent activation of ERK2 without marked activation of MEK1 in NIH3T3 cells. These observations suggest that the anchorage dependence of ERK1/2 activation is regulated not only by upstream kinases, Raf1 and MEK, but also by phosphatases acting against ERK1/2 and that vinexin beta can induce anchorage-independent activation of ERK by preventing the inactivation of ERK1/2.     

ERK phosphorylation: spatial and temporal regulation by G protein-coupled receptors

G protein-coupled receptors (GPCRs) are a major target in the drug discovery process. One important response that results from activation of a wide range of GPCRs is activation of the ERK signalling cascade. Given the abundance of both upstream activators and downstream targets of ERK1/2, the precise spatiotemporal control of ERK1/2 phosphorylation is crucial for maintaining the specificity of the physiological outcome. ERK activity is regulated via a number of mechanisms including compartmentalisation and scaffolding proteins. These scaffolding proteins can enhance the transduction of a specific signalling pathway by targeting pathway components to particular intracellular locations or signalling complexes. Recently, a number of fluorescent indicators of ERK1/2 phosphorylation have been developed that allow the regulation of this pathway to be investigated with greater spatiotemporal resolution than was previously possible. These fluorescent probes in conjunction with those for other signalling cascades should help unravel the spatiotemporal organisation of this pathway.     

Detection of glucagon in pancreatic A-cells by monoclonal antibodies

Summary The production of a mouse monoclonal antibody from a hybrid myeloma and its use for the detection of glucagon in tissue sections is reported. The hybrid clone isolated after fusion of mouse myeloma cells with hyperimmune spleen cells from a mouse previously immunized with poreine glucagon allowed us a standardized and permanent source of monoclonal antibodies in a culture cell system. The monoclonal antibody (3 GL 31) specifically reacts with pancreatic A-cells in several species including pig, rabbit, tupaia belangeri and sheep. No immunoreactivity is observed against gut cells and neurons.Supported by the Deutsche Forschungsgemeinschaft, Carvas SFB 90     

Detection of glucagon in pancreatic A-cells by monoclonal antibodies

The production of a mouse monoclonal antibody from a hybrid myeloma and its use for the detection of glucagon in tissue sections is reported. The hybrid clone isolated after fusion of mouse myeloma cells with hyperimmune spleen cells from a mouse previously immunized with porcine glucagon allowed us a standardized and permanent source of monoclonal antibodies in a culture cell system. The monoclonal antibody (3 GL 31) specifically reacts with pancreatic A-cells in several species including pig, rabbit, tupaia belangeri and sheep. No immunoreactivity is observed against gut cells and neurons.     

Detection of catalytic monoclonal antibodies.

Several laboratories have now shown that monoclonal antibodies having enzyme-like properties can be generated. The generation of catalytic antibodies makes use of the same basic procedures that have been used for the generation of binding monoclonal antibodies, yet the process involves an additional crucial step: screening for catalytic activity. In this paper we address the unique problems involved in the detection of inefficient catalytic activity that is accompanied by uncatalyzed background reaction. An analysis that allows optimization of assay conditions and estimation of the minimal antibody concentration required to observe catalysis is presented. The results indicate that the structure of the substrate should be optimized to increase its affinity (i.e., decrease its Km) and reduce its concentration to pseudo-first-order conditions (S(O) much less than Km) so that the signal observed in the presence of a catalytic antibody (delta Pcat) is significantly higher than that of the background (delta P(uncat)). Other factors involved in the screening procedures, e.g., sensitivity of the assay, solubility and reactivity of the substrate, and purity of the antibody preparation, are also discussed. The effect of these assay parameters on the ability to detect catalytic activity is demonstrated with p-nitrophenyl ester-hydrolyzing antibodies.     

Antigenic determinants of human placental and testicular placental-like alkaline phosphatases as mapped by monoclonal antibodies

Placental alkaline phosphatase (PLAP) in humans shows a high degree of genetic polymorphism as disclosed by electrophoretic analysis. Human testes contain trace amounts of a PLAP-like enzyme, that although immunologically cross-reactive with PLAP, shows unique catalytic properties. As an alternative approach to study enzyme polymorphism we have developed monoclonal antibodies to purified allelic variants of PLAP. Five different monoclonal antibodies are described in this report. The antibodies react with different epitopes on the PLAP molecule. Both conformational dependent and independent determinants are detected. Two epitopes are modified when comparing the S and F allelic variants of PLAP. One epitope is common to PLAP and the intestinal isoenzyme of alkaline phosphatase. The five epitopes appear to be mapped on two rather distant antigenic domains. Combinations of any two antibodies binding to different domains give immunoprecipitates with PLAP on Ouchterlony tests and give good response in sandwich enzyme-linked immunosorbent assays. A study of PLAP-like enzyme in 32 individual testis samples indicates differences in four of the epitopes when compared with PLAP. Four types of testicular enzymes can be distinguished based on their reactivities. These results indicate structural differences between the testicular PLAP-like enzyme and PLAP. These differences are compatible with an underlying genetic mechanism.     

Detection of fos protein during osteogenesis by monoclonal antibodies.

We have generated monoclonal antibodies by using a synthetic peptide corresponding to amino acid positions 4 to 17 of the human fos protein. The antibodies detected both v- and c-fos proteins by immunoprecipitation, immunoblotting, and indirect immunofluorescence. The monoclonal antibodies not only identified the fos protein complex with the cellular 39-kilodalton protein, but also recognized the modified forms of the mouse, rat, and human fos proteins. In day-17 rat embryos, nuclear-staining fos protein could be identified in the cartilage by immunohistochemical staining.     

Epidermal growth factor receptor and protein kinase C signaling to ERK2: spatiotemporal regulation of ERK2 by dual specificity phosphatases

Spatiotemporal aspects of ERK activation are stimulus-specific and dictate cellular consequences. They are dependent upon dual specificity phosphatases (DUSPs) that bind ERK via docking domains and can both inactivate and anchor ERK in cellular compartments. Using high throughput fluorescence microscopy in combination with a system where endogenous ERKs are removed and replaced with wild-type or mutated ERK2-green fluorescent protein (GFP), we show that ERK2 activation responses to epidermal growth factor (EGF) and protein kinase C (PKC) are transient and sustained, respectively. PKC-mediated ERK2 activation is associated with prolonged nuclear localization in the dephosphorylated form, whereas EGF-stimulated ERK2 activation mediates only transient nuclear accumulation. By using short inhibitory RNAs to nuclear inducible DUSP1, -2, or -4 (alone or in combination), we demonstrate that all three of these enzymes contribute to the dephosphorylation of PKC (but not EGF)-activated ERK2 in the nucleus but that they have opposing effects on localization. DUSP2 and -4 inactivate and anchor ERK2, whereas DUSP1 dephosphorylates ERK in the nucleus but allows its traffic back to the cytoplasm. Overexpression of DUSP1, -2, or -4 prevented ERK2 activation, but only DUSP2 and -4 caused ERK2-GFP nuclear accumulation or could be immunoprecipitated with ERK2. Furthermore, protein synthesis inhibition or replacement of wild-type ERK2-GFP with docking domain mutants selectively increased PKC effects on ERK activity and altered ERK2-GFP localization. These mutations also impaired the ability of ERK2-GFP to bind DUSP2 and -4. Together, our data reveal a novel, stimulus-specific, and phosphatase-specific mechanism of ERK2 regulation in the nucleus by DUSP1, -2, and -4.     

Differentiation of human adult and fetal intestinal alkaline phosphatases with monoclonal antibodies

Two forms of intestinal alkaline phosphatase have been recognized in humans. They are very similar in a number of biochemical and immunologic characteristics, but the exact genetic relationship between them remains unclear. To further study this problem, six monoclonal antibodies and a polyclonal rabbit antiserum to human fetal intestinal alkaline phosphatase have been produced. All of the monoclonal antibodies and the rabbit antiserum crossreact with adult intestinal alkaline phosphatase and with the intestinal-like alkaline phosphatase found in D98/AH-2 human tissue-culture cells. Four of the monoclonal antibodies and the rabbit antiserum crossreact with placental alkaline phosphatase, while none of the antibodies or the antiserum recognize liver or kidney alkaline phosphatase. Four of the monoclonal antibodies can distinguish between adult and fetal intestinal alkaline phosphatase in electrophoretic titration-binding studies, with the relative binding of adult enzyme being significantly greater than that of the fetal enzyme in each case. One of these antibodies, which also reacts with placental alkaline phosphatase, can distinguish the type 3 allelic variant of the placental enzyme from types 1 and 2. This indicates that the antibody detects a structural difference in the protein moiety of one of the allelic forms of the enzyme. These data suggest that adult and fetal intestinal alkaline phosphatases represent structurally distinct proteins, either encoded for by different genes or produced by differential processing of a common precursor molecule determined by a single gene.     

Multiple forms of ram and bull sperm hyaluronidase revealed by using monoclonal antibodies

Two monoclonal anti-sperm hyaluronidase-producing cell lines were isolated following inoculation of mice with ram sperm hyaluronidase monomer. Both lines produced antibodies of the IgG1 class; these bound to ram hyaluronidase after 'Western blotting' but did not recognize the native enzyme. Whereas the 1A4 antibody was specific for ram hyaluronidase, and did not react with 'blotted' bull, boar or rabbit hyaluronidase, the 1D6 antibody recognized bull as well as ram hyaluronidase. The antibodies could be used for immunocytochemical localization of hyaluronidase in fixed spermatozoa. However, although some form of denaturation was required to unmask or form the epitopes with which the antibodies reacted, the degree and type of fixation required was critical, for the epitopes were readily destroyed; in particular, they were very sensitive to chemical modification such as glutaraldehyde treatment. It could be demonstrated that, like ram, bull spermatozoa contained an extended oligomeric family of hyaluronidase forms, apparently the result of intermolecular disulphide cross-linking of monomers. In spermatozoa of both species, the enzyme was confined to the anterior acrosomal region of the head.     

Detection of private and recurrent idiotopes on natural anti-tubulin antibodies by monoclonal anti-idiotopic antibodies

Two monoclonal anti-idiotopic antibodies (anti-Id) were raised in mice against a human monoclonal IgA,K displaying a monospecific anti-tubulin (anti-alpha- and anti-beta-tubulin) activity. One anti-Id (IgG,K) recognized a private idiotope, TID 3.2, present only on the IgA,K immunogen, close to or within the antigen-combining site. The other anti-Id (IgM,K) recognized a recurrent idiotope, TID 7.1, outside the paratope and present in normal human and BALB/c mouse serum, on 2 of 11 polyspecific human monoclonal immunoglobulins and on 6 of 11 murine natural monoclonal auto-antibodies exhibiting a widespread anticytoskeletal protein-binding activity. Both the idiotopes were absent on two induced anti-tubulin antibodies exhibiting a monospecific anti-alpha- and anti-beta-tubulin specificity. Utilizing competitive and additivity immunoassays, we could show that the polyspecific human and mouse anticytoskeletal antibodies tested, whether bearing the TID 7.1 Id or not, appeared to compete in variable degrees for epitopes on the tubulin molecule recognized by the monoclonal IgA,K but distinct from the epitopes recognized by the induced monospecific anti-tubulin antibodies. The high incidence of the recurrent TID 7.1 idiotope in man and mouse suggests an important physiologic and perhaps regulatory function of this idiotope. Furthermore our data suggest that a restricted family of germ-line genes, highly conserved during phylogeny, may encode for these idiotope-bearing Ig molecules.     

Regulation of natural killer cell activity by anti-I-region monoclonal antibodies

The effects of a monoclonal antibody directed against immune response gene products on mouse NK activity were examined. In vivo administration of an anti-I-A^k antibody to C3H/He (H-2^k) mice modulated their peritoneal cell (PC) and spleen cell (SC) natural killer (NK) activity against YAC-1 lymphoma target cells in vitro. No such effect was observed when BALB/c (H-2^d) mice were treated with this antibody. Administration of anti-I-A^k antibody to mice before and after infection with Toxoplasma or treatment with poly(I:C) leads to suppression of NK activity in comparison to NK activity of mice infected with Toxoplasma or injected with poly(I:C) alone. A similar treatment regimen with M5/114 antibody which reacts with I-A^b, I-A^d, I-E^d, and I-E^k molecules resulted in decreased NK activity in B10.D2 (H-2^d) but not in B10.BR (H-2^k) mice. Serum and cell culture supernatant interferon (IFN) concentrations were not altered as a result of anti-I-A^k treatment. Removal of adherent cells did not restore NK activity of anti-I-A^k-treated Toxoplasma-infected mice to levels obtained with mice infected with Toxoplasma. In contrast, depletion of Ly 2.1⁺ cells from nylon-wool nonadherent SC of mice treated with anti-I-A^k antibody, before and after infection with Toxoplasma, resulted in restoration of NK activity to the same level as that observed in Toxoptasma-infected mice.     

Detection by using monoclonal antibodies of Yersinia enterocolitica in artificially-contaminated pork

Monoclonal antibodies against Yersinia enterocolitica were produced by fusion of NS‐1 mouse myeloma cells with spleen cells of ICR mice immunized with heat‐killed and heat‐killed plus SDS‐mercaptoethanol treated forms of Y. enterocolitica ATCC 27729 alone or mixed with Y. enterocolitica MU. The twenty‐five MAbs obtained from five fusions were divided into nine groups according to their specificities to different bacterial strains and species, as determined by dot blotting. The first five groups of MAbs were specific only to Y. enterocolitica, but did not recognize all of the isolates tested. MAbs in groups 6 and 7 reacted with all isolates of Y. enterocolitica tested but showed cross‐reaction with some Yersinia spp. and Edwardsiella tarda, especially in the case of group 7. MAbs in groups 8 and 9 reacted with all isolates of Y. enterocolitica and Yersinia spp., as well as other Gram‐negative bacteria that belong to the family Enterobacteriaceae. These MAbs recognized Y. enterocolitica antigens with apparent molecular weights ranging from 10 – 43 kDa by Western blotting, and could detect Y. enterocolitica from ～10³– 10⁵ colony forming units (CFUs) by dot blotting. The hybridoma clone YE38 was selected for detection of Y. enterocolitica in pork samples which had been artificially‐contaminated by inoculation with Y. enterocolitica ATCC 27729 at concentrations of ～10⁴– 10⁶ CFUs/g and incubation in peptone sorbitol bile broth at 4°C. Samples were collected and applied on a nitrocellulose membrane for dot blotting with trypticase soy and cefsulodin‐Irgasan‐novobiocin agars. After 48 hr of incubation, the detection limit was ～10²– 10³ CFU/g by dot blotting.     

Temporal and spatial regulation of the phosphatidate phosphatases lipin 1 and 2

Lipins are the founding members of a novel family of Mg(2+)-dependent phosphatidate phosphatases (PAP1 enzymes) that play key roles in fat metabolism and lipid biosynthesis. Despite their importance, there is still little information on how their activity is regulated. Here we demonstrate that the functions of lipin 1 and 2 are evolutionarily conserved from unicellular eukaryotes to mammals. The two lipins display distinct intracellular localization in HeLa M cells, with a pool of lipin 2 exhibiting a tight membrane association. Small interfering RNA-mediated silencing of lipin 1 leads to a dramatic decrease of the cellular PAP1 activity in HeLa M cells, whereas silencing of lipin 2 leads to an increase of lipin 1 levels and PAP1 activity. Consistent with their distinct functions in HeLa M cells, lipin 1 and 2 exhibit reciprocal patterns of protein expression in differentiating 3T3-L1 adipocytes. Lipin 2 levels increase in lipin 1-depleted 3T3-L1 cells without rescuing the adipogenic defects, whereas depletion of lipin 2 does not inhibit adipogenesis. Finally, we show that the PAP1 activity of both lipins is inhibited by phosphorylation during mitosis, leading to a decrease in the cellular PAP1 activity during cell division. We propose that distinct and non-redundant functions of lipin 1 and 2 regulate lipid production during the cell cycle and adipocyte differentiation.