NPM-ALK phosphorylates WASp Y102 and contributes to oncogenesis of anaplastic large cell lymphoma.

Mechanisms by which NPM-ALK signaling regulates cell migration, invasion and contributes to the oncogenesis of anaplastic large cell lymphoma (ALCL) are not completely understood. In an attempt to identify novel actin signaling pathways regulated by NPM-ALK, a comprehensive phosphoproteome analysis of ALCL cell lines was performed in the presence or absence of NPM-ALK activity. Numerous phosphoproteins involved in actin dynamics including Wiskott-Aldrich syndrome protein (WASp) were regulated by NPM-ALK. Network analysis revealed that WASp is a central component of the NPM-ALK-dependent actin signaling pathway. Here we show that NPM-ALK phosphorylates WASp at its known activation site (Y290) as well as at a novel residue (Y102). Phosphorylation of WASp at Y102 negatively regulates its interaction with Wiskott-Aldrich interacting protein and decreases its protein stability. Phosphorylation of WASp at Y102 enhances anchorage-independent growth and tumor growth in an in vivo xenograft model and enhances invasive properties of ALCL. We show that knock-down of WASp or expression of Y102F mutant of WASp decreases colony formation and in vivo tumor growth. Our results show that WASp is a novel substrate of ALK and has a critical role in regulating invasiveness and oncogenesis of ALCL.

NPM-ALK signals through glycogen synthase kinase 3ß to promote oncogenesis.

Anaplastic large cell lymphoma (ALCL) is the most common type of pediatric peripheral T-cell lymphoma. In 70-80% of cases, the chromosomal aberration t(2;5)(p23;q35) results in the juxtaposition of anaplastic lymphoma kinase (ALK) with nucleophosmin (NPM) and the subsequent expression of the NPM-ALK fusion protein. NPM-ALK is a chimeric tyrosine kinase, which induces numerous signaling pathways that drive proliferation and abrogate apoptosis. However, the mechanisms that lead to activation of downstream growth regulatory molecules have not been completely elucidated. Using a mass spectrometry-based phosphoproteomic screen, we identified GSK3ß as a signaling mediator of NPM-ALK. Using a selective inhibitor of ALK, we demonstrated that the tyrosine kinase activity of ALK regulates the serine-9 phosphorylation of GSK3ß. Expression of NPM-ALK in 293T cells led to an increase of pS(9)-GSK3ß (glycogen synthase kinase 3 beta) compared with kinase-defective K210R mutant NPM-ALK, but did not affect total GSK3ß levels. Phosphorylation of pS(9)-GSK3ß by NPM-ALK was mediated by the PI3K/AKT signaling pathway. ALK inhibition resulted in degradation of GSK3ß substrates Mcl-1 and CDC25A, which was recovered upon chemical inhibition of the proteasome (MG132). Furthermore, the degradation of Mcl-1 was recoverable with inhibition of GSK3ß. ALK inhibition also resulted in decreased cell viability, which was rescued by GSK3ß inhibition. Furthermore, stable knockdown of GSK3ß conferred resistance to the growth inhibitory effects of ALK inhibition using viability and colony formation assays. pS(9)-GSK3ß and CDC25A were selectively expressed in neoplastic cells of ALK+ALCL tissue biopsies, and showed a significant correlation (P<0.001). Conversely, ALK-ALCL tissue biopsies did not show significant correlation of pS(9)-GSK3ß and CDC25A expression (P<0.2). Our results demonstrate that NPM-ALK regulates the phosphorylation of S(9)-GSK3ß by PI3K/AKT. The subsequent inhibition of GSK3ß activity results in accumulation of CDC25A and Mcl-1, which confers the advantage of growth and protection from apoptosis. These findings provide support for the role of GSK3ß as a mediator of NPM-ALK oncogenesis.

Expression and mutagenesis of the novel serpin endopin 2 demonstrates a requirement for cysteine-374 for dithiothreitol-sensitive inhibition of elastase.

The primary sequence of the serpin endopin 2 predicts a reactive site loop (RSL) region that possesses high homology to bovine elastase inhibitor, suggesting inhibition of elastase. Moreover, endopin 2 possesses two cysteine residues that implicate roles for reduced Cys residue(s) for inhibitory activity. To test these predicted properties, mutagenesis and chemical modification of recombinant endopin 2 were performed to examine the influence of dithiothreitol (DTT), a reducing agent, on endopin 2 activity. Endopin 2 inhibited elastase in a DTT-dependent manner, with enhanced inhibition in the presence of DTT. The stoichiometry of inhibition in the presence of DTT occurred at a molar ratio of endopin 2 to elastase of 8/1, resulting in complete inhibition of elastase. However, a higher molar ratio (25/1) was required in the absence of DTT. DTT enhanced the formation of SDS-stable complexes of endopin 2 and elastase, a characteristic property of serpins. Site-directed mutagenesis of endopin 2, with substitution of Ala for Cys-232 or Cys-374, demonstrated that Cys-374 (but not Cys-232) was required for the DTT-sensitive nature of endopin 2. Chemical modification of Cys-374 by bis(maleimido)ethane also reduced inhibitory activity. Modified electrophoretic mobilities of mutant endopin 2 suggested the presence of intramolecular disulfide bonds; in addition, chemical modification suggested that Cys-374 influences the electrophoretic and conformational properties of endopin 2. Moreover, the reducing agent glutathione enhanced endopin 2 activity, suggesting that glutathione can function as an endogenous reducing agent for endopin 2 in vivo. These findings demonstrate the importance of Cys-374 for DTT-sensitive inhibition of elastase by endopin 2.

Molecular cloning of endopin 1, a novel serpin localized to neurosecretory vesicles of chromaffin cells. Inhibition of basic residue-cleaving proteases by endopin 1.

Serpins represent a diverse class of endogenous protease inhibitors that regulate important biological functions. In consideration of the importance of regulated proteolysis within secretory vesicles for the production of peptide hormones and neurotransmitters, this study revealed the molecular identity of a novel serpin, endopin 1, that is localized to neurosecretory vesicles of neuropeptide-containing chromaffin cells (chromaffin granules). Endopin 1 of 68-70 kDa was present within isolated chromaffin granules. Stimulated cosecretion of endopin 1 with chromaffin granule components, [Met]enkephalin and a cysteine protease known as "prohormone thiol protease," demonstrated localization of endopin 1 to functional secretory vesicles. Punctate, discrete immunofluorescence cellular localization of endopin 1 in chromaffin cells was consistent with its secretory vesicle localization. Endopin 1 contains a unique reactive site loop with Arg as the predicted P1 residue, suggesting inhibition of basic residue-cleaving proteases; indeed, trypsin was potently inhibited (K(i(app)) of 5 nM), and plasmin was moderately inhibited. Although endopin 1 possesses homology with alpha(1)-antichymotrypsin, chymotrypsin was not inhibited. Moreover, endopin 1 inhibited the chromaffin granule prohormone thiol protease (involved in proenkephalin processing). These results suggest a role for the novel serpin, endopin 1, in regulating basic residue-cleaving proteases within neurosecretory vesicles of chromaffin cells.

Alpha1-antichymotrypsin-like proteins I and II purified from bovine adrenal medulla are enriched in chromaffin granules and inhibit the proenkephalin processing enzyme "prohormone thiol protease".

Proteolytic processing of inactive proenkephalin and proneuropeptides is essential for the production of biologically active enkephalins and many neuropeptides. The incomplete processing of proenkephalin in adrenal medulla suggests that endogenous protease inhibitors may inhibit proenkephalin processing enzymes. This study demonstrates the isolation and characterization of two isoforms of adrenal medullary alpha1-antichymotrypsin (ACT), referred to as ACT-like proteins I and II, which are colocalized with enkephalin in chromaffin granules and which inhibit the proenkephalin processing enzyme known as prohormone thiol protease (PTP). Subcellular fractionation demonstrated enrichment of 56- and 60-kDa ACT-like proteins I and II, respectively, to enkephalin-containing chromaffin granules (secretory vesicles). Immunofluorescence cytochemistry of chromaffin cells indicated a discrete, punctate pattern of ACT immunostaining that resembles that of [Met]enkephalin that is stored in secretory vesicles. Chromatography of adrenal medullary extracts through DEAE-Sepharose and chromatofocusing resulted in the separation of ACT-like proteins I and II that possess different isoelectric points of 5.5 and 4.0, respectively. The 56-kDa ACT-like protein I was purified to apparent homogeneity by Sephacryl S200 chromatography; the 60-kDa ACT-like protein II was isolated by butyl-Sepharose, Sephacryl S200, and concanavalin A-Sepharose columns. The proenkephalin processing enzyme PTP was potently inhibited by ACT-like protein I, with a K(i,app) of 35 nM, but ACT-like protein II was less effective. ACT-like proteins I and II had little effect on chymotrypsin. These results demonstrate the biochemical identification of two secretory vesicle ACT-like proteins that differentially inhibit PTP. The colocalization of the ACT-like proteins and PTP within chromaffin granules indicates that they could interact in vivo. Results from this study suggest that these ACT-like proteins may be considered as candidate inhibitors of PTP, which could provide a mechanism for limited proenkephalin processing in adrenal medulla.

Arginine and lysine aminopeptidase activities in chromaffin granules of bovine adrenal medulla: relevance to prohormone processing.

Conversion of prohormones and neuropeptide precursors to smaller, biologically active peptides requires specific proteolytic processing at paired basic residues, which generates intermediate peptides with NH2 and COOH termini extended with Lys or Arg residues. These basic residues are then removed by aminopeptidase and carboxypeptidase activities, respectively. Among the proteases involved in prohormone processing, the basic residue aminopeptidase activity has not been well studied. This report demonstrates arginine and lysine aminopeptidase activities detected with Arg-methylcoumarinamide (Arg-MCA) and Lys-MCA substrates in neurosecretory vesicles of bovine adrenal medulla [chromaffin granules (CG)], which contain endoproteolytic processing enzymes co-localized with [Met]enkephalin and other neuropeptides. These arginine and lysine aminopeptidase activities showed many similarities and some differences. Both arginine and lysine aminopeptidase activities were stimulated by the reducing agent beta-mercaptoethanol (beta-ME) and inhibited by p-hydroxymercuribenzoate, suggesting involvement of reduced cysteinyl residues. The arginine aminopeptidase activity was stimulated by NaCl (150 mM), but the lysine aminopeptidase activity was minimally affected. Moreover, characteristic beta-ME/NaCl-stimulated Arg-MCA cleaving activity and beta-ME-stimulated Lys-MCA cleaving activity were detected only in CG and not in other subcellular fractions; these findings indicate the localization of these particular basic residue aminopeptidase activities to secretory vesicles. The arginine and lysine aminopeptidase activities showed pH optima at 6.7 and 7.0, respectively. Km(app) values for the arginine and lysine aminopeptidase activities were 104 and 160 microM, respectively. Inhibition by the aminopeptidase inhibitors bestatin, amastatin, and arphamenine was observed for Arg-MCA and Lys-MCA cleaving activities. Inhibition by the metal ion chelators indicated that metalloproteases were involved; Co2+ stimulated the arginine aminopeptidase activity but was less effective in stimulating lysine aminopeptidase activity. In addition, the lysine aminopeptidase activity was partially inhibited by Ni2+ and Zn2+ (1 mM), whereas the arginine aminopeptidase activity was minimally affected. These results demonstrate the presence of related arginine and lysine thiol metalloaminopeptidase activities in CG that may participate in prohormone processing.

Proteases and the emerging role of protease inhibitors in prohormone processing.

Peptide hormones and neurotransmitters constitute a large class of neurohumoral agents that mediate cell-cell communication in neuroendocrine systems. Their biosynthesis requires proteolytic processing of inactive protein precursors into active neuropeptides. Elucidation of the proteolytic components required for prohormone processing is important for identifying key proteases that may control the production of neuropeptides. This article compares the subtilisin-like PC1/3 and PC2 processing enzymes identified through molecular biological approaches, and several candidate processing enzymes identified biochemically, including the 'proopiomelanocortin converting enzyme' (PCE) and the 'prohormone thiol protease' (PTP), as well as others of different classes (aspartyl, cysteine, metallo, and serine proteases). A role for PTP in cellular proenkephalin processing is suggested by blockade of forskolin-stimulated (Met)enkephalin production by Ep453 that is converted intracellularly to E-64c, a selective cysteine protease inhibitor that potently inhibits PTP. A possible role for endogenous protease inhibitors in prohormone processing represents a new aspect of cellular mechanisms that may regulate neuropeptide biosynthesis. Future studies of the enzymology and molecular biology of processing enzymes and endogenous protease inhibitors will be necessary to elucidate mechanisms of prohormone processing.