Expression of individual forms of peptidylglycine alpha-amidating monooxygenase in AtT-20 cells: endoproteolytic processing and routing to secretory granules

Peptidylglycine alpha-amidating monooxygenase (PAM: EC 1.14.17.3) is a bifunctional protein which catalyzes the COOH-terminal amidation of bioactive peptides; the NH2-terminal monooxygenase and mid-region lyase act in sequence to perform the peptide alpha-amidation reaction. Alternative splicing of the single PAM gene gives rise to mRNAs generating PAM proteins with and without a putative transmembrane domain, with and without a linker region between the two enzymes, and forms containing only the monooxygenase domain. The expression, endoproteolytic processing, storage, and secretion of this secretory granule-associated protein were examined after stable transfection of AtT-20 mouse pituitary cells with naturally occurring and truncated PAM proteins. The transfected proteins were examined using enzyme assays, subcellular fractionation, Western blotting, and immunocytochemistry. Western blots of crude membrane and soluble fractions of transfected cells demonstrated that all PAM proteins were endoproteolytically processed. When the linker region was present between the monooxygenase and lyase domains, monofunctional soluble enzymes were generated from bifunctional PAM proteins; without the linker region, bifunctional enzymes were generated. Soluble forms of PAM expressed in AtT-20 cells and soluble proteins generated through selective endoproteolysis of membrane-associated PAM were secreted in an active form into the medium; secretion of the transfected proteins and endogenous hormone were stimulated in parallel by secretagogues. PAM proteins were localized by immunocytochemistry in the perinuclear region near the Golgi apparatus and in secretory granules, with the greatest intensity of staining in the perinuclear region in cell lines expressing integral membrane forms of PAM. Monofunctional and bifunctional PAM proteins that were soluble or membrane-associated were all packaged into regulated secretory granules in AtT-20 cells.     

Expression of porcine cholecystokinin cDNA in a murine neuroendocrine cell line. Proteolytic processing, sulfation, and regulated secretion of cholecystokinin peptides

The cDNA for porcine preprocholecystokinin (pre-pro-CCK) was engineered for expression in mammalian cells under the control of the Rous sarcoma virus-long terminal repeat promoter. This expression construct was transfected into the murine anterior pituitary cell line, AtT-20. A stable cell line (AtT-20/CCK) was derived that expresses CCK mRNA indistinguishable from the CCK mRNA found in pig brain or gut. The AtT-20/CCK cells carry out proteolytic processing and sulfation reactions to generate authentic sulfated CCK8 from pro-CCK. The cells also store and secrete CCK-immunoreactive peptides. This secretion can be stimulated with corticotropin releasing factor, the natural secretagogue for anterior pituitary cells. In contrast, monkey kidney epithelial cells (COS cells), which are transiently transfected to express CCK, predominantly secrete nonsulfated pro-CCK into the medium. These studies show that a murine neuroendocrine cell line contains the complete processing machinery required to generate authentic porcine CCK8. The processing events include simultaneous proteolytic processing at one and two basic amino acid sites and sulfation of tyrosine residues. The cell line thus duplicates exactly the processing patterns found to occur in pig brain cortex.     

Different secretory pathways of renin from mouse cells transfected with the human renin gene

Mammalian cells in culture, transfected with human renin gene, can provide a useful tool for studying renin biosynthesis and secretion. We transfected fibroblast cells (mouse L929 and Chinese hamster ovary cells) and pituitary tumor cells (mouse AtT-20) with the human renin gene and a selectable plasmid (pSV2Neo). Transfected fibroblasts synthesize prorenin only. Prorenin is secreted by fibroblasts constitutively and the secretion is not influenced by 8-bromo-cAMP. On the other hand, transfected AtT-20 cells synthesized both prorenin and mature active renin. Transfected AtT-20 cells release prorenin by constitutive secretion but mature renin is secreted by a regulated mechanism since the secretion of the former is not influenced by 8-bromo-cAMP but the release of the latter is significantly stimulated. Our studies demonstrate that human renin may be secreted by at least two cellular pathways: prorenin by a constitutive pathway and mature renin by a regulated pathway. These transfected cells may provide useful models for studies of human renin synthesis, processing, and secretion.     

Expression of mutant ELH prohormones in AtT-20 cells: the relationship between prohormone processing and sorting

Posttranslational processing of many proteins is essential to the synthesis of fully functional molecules. The ELH (egg-laying hormone) prohormone is cleaved by endoproteases in a specific order at a variety of basic residue processing sites to produce mature peptides. The prohormone is first cleaved at a unique tetrabasic site liberating two intermediates (amino and carboxy) which are sorted to different classes of dense core vesicles in the bag cell neurons of Aplysia. When expressed in AtT-20 cells, the ELH prohormone is also first cleaved at the tetrabasic site. The amino-terminal intermediate is then sorted to the constitutive pathway, and a portion of the carboxy-terminal intermediate is sorted to the regulated pathway. Here, we use mutant constructs of the ELH prohormone expressed in AtT-20 cells to examine the relationship between prohormone processing and consequent sorting. Prohormone which has a dibasic site in place of the tetrabasic site is processed and sorted similarly to wild type. Furthermore, mutant prohormone which lacks the tetrabasic site is processed at an alternative site comprising three basic residues. In these mutant prohormones, mature ELH is still produced and stored in dense core vesicles while amino-terminal products are constitutively secreted. However, deletion of the tetrabasic and tribasic sites results in the rerouting of the amino-terminal intermediate products from the constitutive pathway to the regulated secretory pathway. Thus, in the ELH prohormone, the location of the proteolytic processing events within the secretory pathway and the order of cleavages regulate the sorting of peptide products.     

Cell-type specific processing of neuroendocrine precursor proteins using vaccinia recombinants

The cell-type specific processing of human pro-enkephalin was determined using a vaccinia recombinant (VV:hPE). The results show that all cell types infected with VV:hPE efficiently synthesize pro-enkephalin following cleavage of the signal peptide after Ala24. In addition, pro-enkephalin is shown to undergo N-linked glycosylation as well as other post-translational modifications. However, only one cell line. AtT-20, was able to efficiently cleave pro-enkephalin to smaller peptides including Met-enkephalin. Some results have been previously reported (Science 232, 1641-1643).     

Expression and post-translational processing of gastrin in heterologous endocrine cells

The biosynthesis of gastrin involves a complex series of post-translational processing reactions that result in the formation of a biologically active secretory product. To study the mechanisms for two specific reactions in gastrin processing, namely dibasic cleavage and amidation, we infected AtT-20, GH3, and Rin5-f cells with the retroviral expression vector, pZip-NeoSV(X), containing human gastrin cDNA. We detected gastrin and its glycine extended post-translational processing intermediates (G-gly) in the media and cell extracts of successfully infected cells. Characterization of the molecular forms of gastrin in these cell lines revealed that GH3 and Rin5-f processed gastrin in a manner similar to antral G-cells but the cleavage of the Lys74-Lys75 bond that converts G34 to G17 appeared to be suppressed in AtT-20 cells. Even after conversion of this site to Arg74-Arg75 via site-directed mutagenesis, the At-20 cells synthesized G34 predominantly. All of the infected cells amidated gastrin but the gastrin/G-gly ratio, a reflection of amidation within the cells, was enhanced in GH3 and Rin5-f cells but diminished in AtT-20 cells upon treatment with dexamethasone (10(-4) M) for 3 days. The dibasic cleavage of gastrin was uneffected by dexamethasone. Our data suggest that the activities of post-translational processing reactions responsible for the synthesis of biologically active gastrin exhibit considerable tissue and substrate specificity.     

Human renin is correctly processed and targeted to the regulated secretory pathway in mouse pituitary AtT-20 cells

Renin is formed by intracellular processing of prorenin and catalyzes the conversion of angiotensinogen to angiotensin I, the precursor to angiotensin II. Several tissues synthesize prorenin. However, in man, the kidney is the only known source of circulating renin, raising the possibility that the processing enzyme is unique to that tissue. We have transfected a gene that directs prorenin synthesis in pituitary AtT-20 cells, which are capable of processing other prohormones. The results demonstrate that transfected AtT-20 cells can secrete inactive prorenin, accurately process prorenin to active renin, and be stimulated to release active renin in response to a secretagogue. These data imply that cellular elements capable of directing the processing of prorenin to renin and its correct subcellular compartmentalization may be present in nonrenal cell types and that critical elements of the regulated release of renin that occur in the kidney can be reconstituted in cells in culture.     

Processing of proaugurin is required to suppress proliferation of tumor cell lines

Augurin is a secretory molecule produced in pituitary, thyroid, and esophagus and implicated in a wide array of physiological processes, from ACTH release to tumor suppression. However, the specific proaugurin-derived peptides present in various cell types are not yet known. In order to shed light on the posttranslational modifications required for biological activity, we here describe the posttranslational processing of proaugurin in AtT-20 and Lovo cells and identify proaugurin-derived products generated by convertases. In vitro cleavage of proaugurin with proprotein convertases produced multiple peptides, including a major product with a mass of 9.7 kDa by mass spectrometry. Metabolic labeling of C-terminally tagged proaugurin in AtT-20 and AtT-20/PC2 cells resulted in a major 15-kDa tagged form on SDS-PAGE, which likely corresponds to the 9.7-kDa in vitro fragment, with the added tag, its linker, and posttranslational modification(s). The secretion of neither proaugurin nor this cleavage product was stimulated by forskolin, indicating its lack of storage in regulated secretory granules and lack of cleavage by PC2. Incubation of cells with the furin inhibitor nona-d-arginine resulted in impaired cleavage of proaugurin, whereas metalloprotease inhibitors did not affect proaugurin proteolysis. These data support the idea that proaugurin is cleaved by furin and secreted via the constitutive secretory pathway. Interestingly, proaugurin was sulfated during trafficking; sulfation was completely inhibited by brefeldin A. Proliferation assays with three different tumor cell lines demonstrated that only furin-cleaved proaugurin could suppress cell proliferation, suggesting that proteolytic cleavage is a posttranslational requirement for proaugurin to suppress cell proliferation.     

Biosynthesis of the prohormone convertase mPC1 in AtT-20 cells.

A new family of mammalian subtilisin-like enzymes, probably involved in the processing of proproteins in regulated and constitutive cells at paired basic residues, has recently been discovered. Little information exists as yet concerning the biosynthesis of these endogenous subtilisin-like enzymes. In the present work the biosynthesis and release of the endogenous prohormone convertase PC1 in AtT-20 cells were studied. As predicted from mRNA studies, AtT-20 cells contain high levels of PC1 protein. Through immunoblotting, 87-kilodalton (kDa) and 66-kDa bands were detected with an amino terminally directed antiserum; however, only the 87-kDa product was detected with carboxyl terminally directed antiserum, indicating carboxyl terminal truncation. Pulse-chase experiments, using [35S]methionine/cysteine, showed that after 20 min pulse the main product in the cells was the 87-kDa protein. Cells chased for varying amounts of time exhibited a progressive increase in the intensity of a 66-kDa band, along with a corresponding decrease of the 87-kDa band. The 87-66 kDa conversion was nearly complete after 4 h of chase. This posttranslational processing was inhibited by the ionophore monensin, a Golgi disruptor, with a corresponding accumulation of the 87-kDa protein within the cell. Both the 87 kDa- and 66 kDa-labeled proteins were detected as membrane-bound rather than soluble proteins. The 87-kDa protein was the main product secreted by nonstimulated AtT-20 cells, while the 66-kDa product was only released when the cells were stimulated with CRF or BaCl2 and Bromo-cAMP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transient expression of wild type and mutant human apolipoprotein AI in COS cells

A human apolipoprotein AI (apo AI) minigene and two mutants were cloned into the vector pUHD10-1 for expression studies in COS cells under the control of the strong CMV (cytomegalovirus) enhancer and the own apo AI promoter. In the mutated apo AI minigene (mutant M1) the positions of the triplets of Gln(-2)-Gln-1 at the C-terminus of the prosequence were exchanged against Gln(-8)-Ala-7, the recognition site of the signal peptidase of the wild type human apo AI. The prosequence has been deleted in mutant M2 and the presequence linked directly to the N-terminus of the mature apo AI form. We report here on expression studies in COS cells, a cell line, which does not express apo AI. They were transfected by electroporation with pUHD10-1 constructs, which contain a) the wild type apo AI minigene and b) the two mutant apo AI minigenes with mutations described above. The following results were obtained: a) the wild type and mutant apo AI constructs were efficiently transcribed and translated in COS cells, b) the expression of the wild type preproapo AI minigene in COS cells led to the secretion of proapo AI (29 kDa), that of the mutant (M2) gene, devoid of the prosequence of mature apo AI (28.4 kDa), whereas the product of mutant gene M1 (31 kDa) with the recognition site of the signal peptides transposed to the C-terminus of the prosequence remained uncleaved within the COS cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

7B2 facilitates the maturation of proPC2 in neuroendocrine cells and is required for the expression of enzymatic activity

The prohormone convertase PC2, which is thought to mediate the proteolytic conversion of many peptide hormones, has recently been shown to interact with the neuroendocrine-specific polypeptide 7B2 in Xenopus intermediate lobe (Braks, J. A. M., and G. J. M. Martens. Cell. 78:263. 1994). In the present work we have stably transfected neuroendocrine cell lines with rat 7B2 constructs and found that overexpression of 27 kD 7B2 greatly facilitates the kinetics of maturation of proPC2, both in AtT-20/PC2 cells and in Rin5f cells. The half-life of conversion of proPC2 was reduced from 2.7 to 1.7 h in AtT- 20/PC2 cells stably transfected with 27 kD 7B2 cDNA. The previously proposed "chaperone" domain was not sufficient for this facilitation event; however, a construct corresponding to the 21-kD 7B2 protein (which represents the naturally occurring maturation product) functioned well. A 7B2 construct in which maturation of 27 kD 7B2 to its 21-kD form was blocked was unable to facilitate maturation of proPC2. To correlate effects on PC2 maturation with the actual generation of PC2 enzymatic activity, a similar transfection of 21 kD 7B2 was performed using CHO cells previously amplified for the expression of proPC2. Enzymatic activity cleaving the fluorogenic substrate Cbz-Arg-Ser-Lys-Arg-AMC was highly correlated with the expression of immunoreactive 21 kD 7B2 in the conditioned medium; medium obtained from the parent cell line was completely inactive. Enzymatic activity was identified as PC2 on the basis of inhibition by the carboxy-terminal peptide of 7B2, which has previously been shown to represent a potent and specific PC2 inhibitor. Taken together, our in vivo results indicate that the interesting secretory protein 7B2 is a bifunctional molecule with an amino-terminal domain involved in proPC2 transport as well as activation.     

Major role of cathepsin L for producing the peptide hormones ACTH, beta-endorphin, and alpha-MSH, illustrated by protease gene knockout and expression

The pituitary hormones adrenocorticotropic hormone (ACTH), beta-endorphin, and alpha-melanocyte stimulating hormone (alpha-MSH) are synthesized by proteolytic processing of their common proopiomelanocortin (POMC) precursor. Key findings from this study show that cathepsin L functions as a major proteolytic enzyme for the production of POMC-derived peptide hormones in secretory vesicles. Specifically, cathepsin L knock-out mice showed major decreases in ACTH, beta-endorphin, and alpha-MSH that were reduced to 23, 18, and 7% of wild-type controls (100%) in pituitary. These decreased peptide levels were accompanied by increased levels of POMC consistent with proteolysis of POMC by cathepsin L. Immunofluorescence microscopy showed colocalization of cathepsin L with beta-endorphin and alpha-MSH in the intermediate pituitary and with ACTH in the anterior pituitary. In contrast, cathepsin L was only partially colocalized with the lysosomal marker Lamp-1 in pituitary, consistent with its extralysosomal function in secretory vesicles. Expression of cathepsin L in pituitary AtT-20 cells resulted in increased ACTH and beta-endorphin in the regulated secretory pathway. Furthermore, treatment of AtT-20 cells with CLIK-148, a specific inhibitor of cathepsin L, resulted in reduced production of ACTH and accumulation of POMC. These findings demonstrate a prominent role for cathepsin L in the production of ACTH, beta-endorphin, and alpha-MSH peptide hormones in the regulated secretory pathway.     

Ionic milieu controls the compartment-specific activation of pro-opiomelanocortin processing in AtT-20 cells.

Newly synthesized prohormones and their processing enzymes transit through the same compartments before being packaged into regulated secretory granules. Despite this coordinated intracellular transport, prohormone processing does not occur until late in the secretory pathway. In the mouse pituitary AtT-20 cell line, conversion of pro-opiomelanocortin (POMC) to mature adrenocorticotropic hormone involves the prohormone convertase PC1. The mechanism by which this proteolytic processing is restricted to late secretory compartments is unknown; PC1 activity could be regulated by compartment-specific activators/inhibitors, or through changes in the ionic milieu that influence its activity. By arresting transport in a semi-intact cell system, we have addressed whether metabolically labeled POMC trapped in early secretory compartments can be induced to undergo conversion if the ionic milieu in these compartments is experimentally manipulated. Prolonged incubation of labeled POMC trapped in the endoplasmic reticulum or Golgi/trans-Golgi network did not result in processing, thereby supporting the theory that processing is normally a post-Golgi/trans-Golgi network event. However, acidification of these compartments allowed effective processing of POMC to the intermediate and mature forms. The observed processing increased sharply at a pH below 6.0 and required millimolar calcium, regardless of the compartment in which labeled POMC resided. These conditions also resulted in the coordinate conversion of PC1 from the 84/87 kDa into the 74-kDa and 66-kDa forms. We propose that POMC processing is predominantly restricted to acidifying secretory granules, and that a change in pH within these granules is both necessary and sufficient to activate POMC processing.     

Cleavage-site mutagenesis alters post-translation processing of Pro-CCK in AtT-20 cells

Cholecystokinin (CCK) is expressed in the central and peripheral nervous systems and functions as a neurotransmitter and neuroendocrine hormone. The in vivo forms of CCK include CCK-83, -58, -39, -33, -22, -12, and -8. Tissues in the periphery produce the larger forms of CCK, such as CCK-58, whereas the brain primarily produces CCK-8. The different biologically active forms of CCK observed in vivo may result from cell-specific differences in endoproteolytic cleavage during post-translational processing. Evidence suggests that cleavages of pro-CCK occur in a specific sequential order. To further delineate the progression of cleavages during pro-CCK maturation, mutagenesis was used to disrupt putative mono- and dibasic cleavage sites. AtT-20 cells transfected with wild-type rat prepro-CCK secret CCK-22 and -8. Mutagenesis of the cleavage sites of pro-CCK had profound effects on the products that were produced. Substitution of basic cleavage sites with nonbasic amino acids inhibits cleavage and leads to the secretion of pathway intermediates such as CCK-83, -33, and -12. These results suggest that CCK-58 is cleaved to both CCK-33 and -22. Furthermore, CCK-8 and -12 are likely derived from cleavage of CCK-33 but not CCK-22. Alanine substitution at the same site completely blocked production of amidated products, whereas serine substitution did not. The cleavages observed at nonbasic residues in this study may represent the activity of enzymes other than PC1 and carboxypeptidase E, such as the enzyme SKI-1. A model for the progression of pro-CCK processing in AtT-20 cells is proposed. The findings in this study further supports the hypothesis that pro-CCK undergoes parallel pathways of proteolytic cleavages.     

A targeting sequence for dense secretory granules resides in the active renin protein moiety of human preprorenin

Human renin plays an important role in blood pressure homeostasis and is secreted in a regulated manner from the juxtaglomerular apparatus of the kidney in response to various physiological stimuli. Many aspects of the regulated release of renin (including accurate processing of prorenin to renin, subcellular targeting of renin to dense secretory granules, and regulated release of active renin) can be reproduced in mouse pituitary AtT-20 cells transfected with a human preprorenin expression vector. Using protein engineering, we have attempted to define the roles of various structures in prorenin that affect its production and trafficking to dense core secretory granules, resulting in its activation and regulated secretion. Replacement of the native signal peptide of human preprorenin with that of a constitutively secreted protein (immunoglobulin M) had no apparent effect on either the constitutive secretion of prorenin or the regulated secretion of active renin in transfected AtT-20 cells. Removal of the pro segment resulted in a marked reduction in total renin secretion, but did not prevent renin from entering the regulated secretory pathway. Single or combined mutations in the two glycosylation sites of human renin did not prevent its regulated secretion; however, the complete elimination of glycosylation resulted in a significant increase in the ratio of renin/prorenin secreted by the transfected cells. Thus, these results suggest that 1) at least one of the sequences that target human renin to dense secretory granules lies within the protein moiety of active renin; 2) the presence of the pro segment is important for efficient prorenin and renin production; and 3) glycosylation can quantitatively affect the proportion of active renin secreted.     

P-selectin, a granule membrane protein of platelets and endothelial cells, follows the regulated secretory pathway in AtT-20 cells

P-selectin (PADGEM, GMP-140, CD62) is a transmembrane protein specific to alpha granules of platelets and Weibel-Palade bodies of endotheial cells. Upon stimulation of these cells, P-selectin is translocated to the plasma membrane where it functions as a receptor for monocytes and neutrophils. To investigate whether the mechanism of targeting of P-selectin to granules is specific for megakaryocytes and endothelial cells and/or dependent on von Willebrand factor, a soluble adhesive protein that is stored in the same granules, we have expressed the cDNA for P-selectin in AtT-20 cells. AtT-20 cells are a mouse pituitary cell line that can store proteins in a regulated fashion. By double-label immunofluorescence, P-selectin was visible as a punctate pattern at the tips of cell processes. This pattern closely resembled the localization of ACTH, the endogenous hormone produced and stored by the AtT-20 cells. Fractionation of the transfected cells resulted in the codistribution of P-selectin and ACTH in cellular compartments of the same density. Immunoelectron microscopy using a polyclonal anti-P-selectin antibody demonstrated immunogold localization in dense granules, morphologically indistinguishable from the ACTH granules. Binding experiments with radiolabeled monoclonal antibody to P-selectin indicated that there was also surface expression of P-selectin on the AtT-20 cells. After stimulation with the secretagogue 8-Bromo-cAMP the surface expression increased twofold, concomitant with the release of ACTH. In contrast, the surface expression of P-selectin transfected into CHO cells, which do not have a regulated pathway of secretion, did not change with 8-Br-cAMP treatment. In conclusion, we provide evidence for the regulated secretion of a transmembrane protein (P-selectin) in a heterologous cell line, which indicates that P-selectin contains an independent sorting signal directing it to storage granules.     

Biosynthesis and packaging of carboxypeptidase D into nascent secretory vesicles in pituitary cell lines.

Metallocarboxypeptidase D (CPD) is a membrane-bound trans-Golgi network (TGN) protein. In AtT-20 cells, CPD is initially produced as a 170-kDa endoglycosidase H-sensitive glycoprotein. Within 30 min of chase, the CPD increases to 180 kDa and is resistant to endoglycosidase H as a result of carbohydrate maturation. CPD also undergoes an activation step required for binding to a substrate affinity resin. Blocking the protein exit from the endoplasmic reticulum inhibits the increase in molecular mass but not the step required for affinity column binding, suggesting that enzyme activation precedes carbohydrate maturation and that these reactions occur in distinct intracellular compartments. Only the higher molecular weight mature CPD enters nascent secretory vesicles, which bud from the TGN of permeabilized AtT-20 and GH3 cells. The budding efficiency of CPD into vesicles is 2-3-fold lower than that of endogenous proopiomelanocortin in AtT-20 cells or prolactin in GH3 cells. In contrast, the packaging of a truncated form of CPD, which lacks the cytoplasmic tail and transmembrane domain, was similar to that of proopiomelanocortin. Taken together, the results support the proposal that CPD functions in the TGN in the processing of proteins that transit the secretory pathway and that the C-terminal region plays a major role in TGN retention.     

Isolation of the boar sperm acrosin peptide released during the conversion of alpha-form into beta-form

The sperm proteinase acrosin occurs in several enzymatically active forms which differ from each other in molecular mass. The high-molecular-mass alpha-form (53 kDa) is converted into the low-molecular-mass beta-form (38 kDa) by auto-proteolysis. As these two forms possess identical N-termini and identical A-chains (light chains) the difference must reside in the C-terminal parts of their B-chains (heavy chains). It could be demonstrated by gel electrophoresis that on incubation of alpha-acrosin, in addition to beta-acrosin, a main degradation product of approx. 18 kDa was formed. This fragment was isolated by gel filtration chromatography. The amino-acid composition of the fragment corresponded to the difference between that of alpha-acrosin and of beta-acrosin, and showed a strikingly high proportion of proline. It is suggested that this hydrophobic segment from the C-terminal region of alpha-acrosin accounts for the special membrane-associating property of the enzyme.