Protein Kinase A-anchoring Inhibitor Peptides Arrest Mammalian Sperm Motility
Cyclic AMP-dependent protein kinase (PKA) is anchored at specific subcellular sites through the interaction of the regulatory subunit (R) with protein kinase A-anchoring proteins (AKAPs) via an amphipathic helix binding motif. Synthetic peptides containing this amphipathic helix domain competitively disrupt PKA binding to AKAPs and cause a loss of PKA modulation of cellular responses. In this report we use S-Ht31, a cell-permeant anchoring inhibitor peptide, to study the role of PKA anchoring in sperm. Our analysis of three species of mammalian sperm detected three isoforms of PKA (RIIalpha, RIIbeta, and RIbeta) and one 110-kDa AKAP. The addition of S-Ht31 to bovine caudal epididymal sperm inhibits motility in a time- and concentration-dependent manner. A control peptide, S-Ht31-P, identical to S-Ht31 except for a proline for isoleucine substitution to prevent amphipathic helix formation, had no effect on motility. The inhibition of motility by S-Ht31 is reversible but only if calcium is present in the suspension buffer, suggesting a role for PKA anchoring in regulating cellular calcium homeostasis. Surprisingly, inhibition of PKA catalytic activity had little effect on basal motility or motility stimulated by agents previously thought to work via PKA activation. These data suggest that the interaction of the regulatory subunit of PKA with sperm AKAPs, independent of PKA catalytic activity, is a key regulator of sperm motility and that disruption of this interaction using cell-permeable anchoring inhibitor peptides may form the basis of a sperm-targeted contraceptive.
ADP-Glo is a novel bioluminescent, homogeneous assay for monitoring ADP producing biochemical reactions and thus it is an ideal assay for detecting enzyme activity using a wide variety of substrates. It is a universal assay that can be used with protein kinases, lipid kinases, sugar kinases, and many more kinases as well as ATPases. Because of its high sensitivity, it is suitable for monitoring enzyme activities at very early substrate conversions requiring very low amount of enzymes. Furthermore, as the assay is applicable to a broad range of ATP and substrate concentrations, it is optimal for enzymes that require high ATP and substrate concentrations. This is critical since inhibitor potency has to be demonstrated at the cellular level where ATP is present at millimolar concentrations. ADP-Glo is performed in 2 steps upon completion of kinase reaction: a combined termination of kinase reaction and depletion of remaining ATP in the first step, and conversion of generated ADP to ATP and the newly produced ATP to light output using luciferase/luciferin reaction in the second step. The luminescent signal generated is proportional to the ADP concentration produced and is correlated with the kinase activity. Due to its high signal to background and luminescent readout, this assay is less susceptible to generation of false hits and thus it is applicable to not only primary and secondary screening but also kinase profiling.
The methyltransferase Glo is nonradioactive, antibody-free and homogenous, universal assay to determine enzyme activity of diverse families of methyltransferases. The assay is formatted to meet the requirements of high-throughput screening in drug discovery programs searching for modulators of methyltransferases.
Sperm motility is regulated by protein phosphorylation. We have recently shown that a serine/threonine phosphatase system is involved in motility regulation. Two of the components of the phosphatase system, GSK-3 and PP1gamma2, are regulated by tyrosine phosphorylation. During our investigation of sperm tyrosine-phosphorylated proteins we discovered a 55-kDa protein whose tyrosine phosphorylation correlates closely to the motility state of sperm. This protein is tyrosine phosphorylated to a much higher degree in motile caudal than in immotile caput epididymal sperm. Motility inhibition of caudal epididymal sperm by protein kinase A (PKA) anchoring inhibition or by ionomycin-induced calcium overload led to the virtual disappearance of tyrosine phosphorylation of the 55-kDa protein. Conversely, treatment of sperm with motility activators, isobutylmethylxanthine or 8-bromo-cAMP, resulted in increased tyrosine phosphorylation of the protein. The protein was present in the soluble 100 000 x g supernatants of sperm extracts and was heat labile. Chromatography through diethylaminoethyl-cellulose and Western blot analysis showed that this 55-kDa protein is not a regulatory subunit of PKA or alpha-tubulin. Our results represent the identification of a soluble protein whose tyrosine phosphorylation varies directly with motility and suggest that motility regulation may involve cross talk between PKA, calcium, and tyrosine kinase pathways.
Nuclear casein kinase 2 (CK‐2) activity in human normal, benign hyperplastic, and cancerous prostate
In previous work, we had observed that chromatin-associated nonhistone protein phosphorylation, catalyzed by intrinsic protein kinase reaction in chromatin preparations from human benign prostatic hyperplasia (BPH) prostate samples was markedly elevated, compared with the normal prostate chromatin samples [Rayan et al: Cancer Res 45:2277-2282, 1985]. The properties of this protein kinase reaction were suggestive of the involvement of casein kinase(s). By employing the specific synthetic substrate for casein kinase 2 (CK-2) for assays in cellular fractions, we have shown that this protein kinase is present in human prostate chromatin. Its activity is increased in BPH chromatin by about 25-fold, as compared with its activity in the normal prostate chromatin. This suggests that CK-2 is a possible mediator of the enhanced phosphorylation of chromosomal proteins in BPH chromatin. By comparison, CK-2 activity in chromatin preparations from prostatic carcinoma samples was markedly less elevated than that of the BPH chromatin. Immunohistochemical analysis of the enzyme in human frozen sections of prostate tissue samples showed that the enzyme immunostaining was diffuse in the cytoplasm, but more intense in the nucleus, especially in the nucleoli. In general, the staining corresponded with the enzymic data. However, sections from prostatic carcinoma samples appeared to show differential staining, depending on the Gleason's grade of the sample. The samples with higher Gleason's grade showed less intense immunostain in the nucleus, compared with samples of lower Gleason's grade. Further, regions of sections in samples with higher Gleason's grade did not show any immunostaining. These differences in the characteristics of CK-2 expression in prostatic carcinoma samples may be potentially significant, but need to be evaluated further for their significance to the pathobiology of prostatic neoplasia.
The extracellular signal-regulated kinase (ERK), a member of the mitogen-activated protein kinases (MAPKs), is essential for cellular proliferation and differentiation, and thus there exists great interest to develop specific and selective inhibitors of this enzyme. Whereas small molecule inhibitors PD098095 and U0126 have been used to study MAPK/ERK kinase (MEK), their target selectivity has been questioned recently. The cross-reactivity of ATP-directed inhibitors with other protein kinases prompted us to develop structure-based selective peptide inhibitors of ERK activation. Based on a MEK1-derived peptide, we developed inhibitors of ERK activation in vitro and in vivo. The inclusion of either an alkyl moiety or a membrane-translocating peptide sequence facilitated the cellular uptake of the peptide inhibitor and prevented ERK activation in 4-phorbol 12-myristate 13-acetate-stimulated NIH 3T3 cells or nervegrowthfactor-treatedPC12cellsinaconcentration-dependent manner. In addition, cell-permeable peptides inhibited ERK-mediated activation of the transcriptional activity of ELK1. The peptides did not have an inhibitory effect on the activity of two other closely related classes of MAPKs, c-Jun amino-terminal kinase or p38 protein kinase. Thus, these peptides may serve as valuable tools for investigating ERK activation and for selective investigation of ERK-mediated responses. With the knowledge of other kinase interacting domains, it would be possible to design cell-permeable inhibitors for investigating diverse cellular signaling mechanisms and for possible therapeutic applications.Protein phosphorylation plays a critical role in cellular signaling in response to a variety of hormones, growth factors, neurotransmitters, and a wide range of stimuli. Mitogen-activated protein kinases (MAPKs) 1 play a pivotal role in these processes, particularly in stimulus-mediated cellular responses (1-3). The activation of these enzymes requires a cascade-like mechanism in which each MAPK is phosphorylated on two amino acid residues (Thr/Tyr) by an upstream protein kinase, MAPKK (MEK), and the latter in turn is phosphorylated on two amino acid residues (Ser/Thr) by a third protein kinase, MAPKK kinase (MEKK). There are at least three such protein kinase modules in mammalian cells as follows: extracellular signal-regulated kinases (ERKs), c-Jun amino-terminal kinases (JNKs), and the p38 MAP kinases (p38). The dual phosphorylation of MAPKs by MEKs is necessary for their activation (4) and is considered an essential step in the signaling pathways in response to growth factors and mitogenic stimuli, stress-causing agents, and cytokines. For phosphorylation-dependent activation of MAPKs to occur, MAPK must first associate with its cognate upstream kinase, MEK. Thus, disrupting this interaction using a peptide derived from an association domain of either enzyme (5, 6) would be predicted to block the activation of the downstream protein kinase. To test this hypothesis, we evaluated the ability of a peptide corresponding to the ami...
Stimulation of mammalian cells results in subcellular relocalization of Ras pathway enzymes, in which extracellular signal-regulated protein kinases rapidly translocate to nuclei. In this study, we define conditions for nuclear localization of mitogen-activated protein kinase kinase 1 (MKK1) by examining effects of perturbing the nuclear export signal (NES), the regulatory phosphorylation sites Ser 218 and Ser 222, and a regulatory domain at the N terminus. After disrupting the NES (⌬32-37), nuclear uptake of MKK was enhanced when quiescent cells were activated with serum-phorbol 12-myristate 13-acetate or BXB-Raf-1 cotransfection. Uptake was enhanced by mutation of Ser 218and Ser 222 to Glu and Asp, respectively, and blocked by mutation of these residues to Ala, although mutation of Lys 97 to Met, which renders MKK catalytically inactive, did not interfere with uptake. Therefore, nuclear uptake of MKK requires incorporation of phosphate or negatively charged residues at the activation lip but not enzyme activity. On the other hand, uptake of an active MKK mutant with disrupted NES (⌬32-51) was elevated in quiescent as well as stimulated cells, and pretreatment of cells with the MKK inhibitor 1,4-diamino-2,3-dicyano-1,4-bis[2-aminophenylthio]butadiene blocked nuclear uptake. Thus, signaling downstream of MKK is also necessary for translocation. Finally, wild type MKK containing an intact NES translocates to nuclei during mitosis before envelope breakdown. Comparison of mutants with Ser to Glu and Asp or Ala substitutions indicates that Ser phosphorylation is also required for mitotic nuclear uptake of MKK.Among the key signaling pathways regulating mammalian cell growth and differentiation is the MAP 1 kinase cascade, comprising MAP kinases, ERKs 1 and 2, and MAP kinase kinases MKK1 and 2 (for review, see Refs. 1 and 2). This pathway is activated by many different extracellular stimuli through p21 Ras-coupled mechanisms. Enhancement of MKK or ERK activity in response to cell stimulation involves phosphorylation at residues located within the activation lip of each kinase. In the case of human MKK, phosphorylation at two serine residues ( In addition to kinase activation, several studies have demonstrated that the components in this pathway undergo regulated subcellular relocalization. After cell stimulation, ERKs are taken up into nuclei within 5-30 min and are retained for several hours (3-5). This enables transmission of signaling to the nucleus, where an important end result is transcriptional control. The involvement of ERK in phosphorylation and regulation of a number of nuclear factors suggests that redistribution of ERK from cytosolic to nuclear compartments is necessary for signaling (for review, see Ref. 6). In addition, stable nuclear localization of ERK has been correlated with differentiation of PC12 cells, a process involving phosphorylation of nuclear transcription factors involved in neuronal gene expression (7)(8)(9).Initial studies failed to show a similar translocation of MKK in response to si...
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