Secretion of sulfated and nonsulfated forms of parathyroid chromogranin A (secretory protein-I)

Chromogranin A (secretory protein-I) is an acidic, sulfated glycoprotein found in secretory granules of most endocrine cells but not in exocrine or epithelial cells. Parathyroid chromogranin A is sulfated on tyrosine residues, whereas adrenal chromogranin A appears to be sulfated mainly on oligosaccharide residues. Chromogranin B, on the other hand, is tyrosine-sulfated in the bovine adrenal whereas this protein is absent from the parathyroid. The role of this tissue- or species-specific sulfation of chromogranin is not known. Tyrosine sulfation is a common post-translational modification of proteins in the exocytotic pathway and has been suggested to play a role in the sorting or intracellular transport of secretory proteins. To test this, porcine parathyroid tissue slices were metabolically labeled with 35SO4 and [3H]Lys, and the tissue and incubation medium analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoblotting, and immunoprecipitation with chromogranin A-specific antiserum or by radioimmunoassay for parathormone. Secretion of total and 3H-labeled chromogranin A was about 3- and 7-fold higher, respectively, at 0.5 mM than at 3.0 mM Ca2+, and secretion of 35SO4-labeled chromogranin A was 67-fold higher. This indicates that either sulfated chromogranin A is directed primarily to the Ca2+-regulated pathway or that sulfation occurs following sorting to this pathway. Sodium chlorate (1-10 mM) inhibited sulfation in a dose-dependent manner by up to 95% but it had no effect on the onset or rate of chromogranin A secretion. These data indicate that regulated secretion of parathyroid chromogranin A does not require sulfation of tyrosine residues.     

Sulfated tyrosines of thyroglobulin are involved in thyroid hormone synthesis.

Thyroid hormone synthesis is under the control of thyrotropin (TSH), which also regulates the sulfation of tyrosines in thyroglobulin (Tg). We hypothesized that sulfated tyrosine (Tyr[S]) might be involved in the hormonogenic process, since the consensus sequence required for tyrosine sulfation to occur was observed at the hormonogenic sites. Porcine thyrocytes, cultured with TSH but without iodide in the presence of [(35)S]sulfate, secreted Tg which was subjected to in vitro hormonosynthesis with increasing concentrations of iodide. A 63% consumption of Tyr[S] (1 residue) was observed at 40 atoms of iodine incorporated into Tg, corresponding to a 40% hormonosynthesis efficiency. In addition, hyposulfated Tg secreted by cells incubated with sodium chlorate was subjected to in vitro hormonosynthesis. With 0.5 Tyr[S] residue (31% of the initial content), the efficiency of the hormonosynthesis was 29%. In comparison, when hormonosynthesis was performed by cells, with only 0.25 Tyr[S] residue (16% of the initial content), the hormonosynthesis efficiency fell to 18%. These results show that there exists a close correlation between the sulfated tyrosine content of Tg and the production of thyroid hormones.     

Tyrosine modification enhances metal-ion binding

Tyrosine sulfation is a common modification of many proteins, and the ability to phosphorylate tyrosine residues is an intrinsic property of many growth-factor receptors. In the present study, we have utilized the peptide hormone CCK(8) (cholecystokinin), which occurs naturally in both sulfated and unsulfated forms, as a model to investigate the effect of tyrosine modification on metal-ion binding. The changes in absorbance and fluorescence emission on Fe(3+) binding indicated that tyrosine sulfation or phosphorylation increased the stoichiometry from 1 to 2, without greatly affecting the affinity (0.6-2.8 microM at pH 6.5). Measurement of Ca(2+) binding with a Ca(2+)-selective electrode revealed that phosphorylated CCK(8) bound two Ca(2+) ions. CCK(8) and sulfated CCK(8) each bound only one Ca(2+) ion with lower affinity. Binding of Ca(2+), Zn(2+) or Bi(3+) to phosphorylated CCK(8) did not cause any change in absorbance, but substantially increased the change in absorbance on subsequent addition of Fe(3+). The results of the present study demonstrate that tyrosine modification may increase the affinity of metal-ion binding to peptides, and imply that metal ions may directly regulate many signalling pathways.     

Identification and functional importance of tyrosine sulfate residues within recombinant factor VIII.

Sulfated tyrosine residues within recombinant human factor VIII were identified by [35S]sulfate biosynthetic labeling of Chinese hamster ovary cells which express human recombinant factor VIII. Alkaline hydrolysis of purified [35S]sulfate-labeled factor VIII showed that greater than 95% of the [35S]sulfate was incorporated into tyrosine. [3H]Tyrosine and [35S]sulfate double labeling was used to quantify the presence of 6 mol of tyrosine sulfate per mole of factor VIII. Amino acid sequence analysis of thrombin and tryptic peptides isolated from [35S]sulfate-labeled factor VIII demonstrated tyrosine sulfate at residue 346 in the factor VIII heavy chain and at residues 1664 and 1680 in the factor VIII light chain. In addition, the carboxyl-terminal half of the A2 domain contained three tyrosine sulfate residues, likely at positions 718, 719, and 723. Interestingly, all sites of tyrosine sulfation border thrombin cleavage sites. The functional importance of tyrosine sulfation was examined by treatment of cells expressing factor VIII with sodium chlorate, a potent inhibitor of tyrosine sulfation. Increasing concentrations of sodium chlorate inhibited sulfate incorporation into factor VIII without affecting its synthesis and/or secretion. However, factor VIII secreted in the presence of sodium chlorate exhibited a 5-fold reduction in procoagulant activity, although the protein was susceptible to thrombin cleavage. These results suggest that tyrosine sulfation is required for full factor VIII activity and may affect the interaction of factor VIII with other components of the coagulation cascade.     

Human cationic trypsinogen is sulfated on Tyr154

The crystal structure of human pancreatic cationic trypsin showed the chemical modification of Tyr154, which was originally described as phosphorylation [Gaboriaud C, Serre L, Guy-Crotte O, Forest E & Fontecilla-Camps JC (1996) J Mol Biol259, 995-1010]. Here we report that Tyr154 is sulfated, not phosphorylated. Cationic and anionic trypsinogens were purified from human pancreatic juice and subjected to alkaline hydrolysis. Modified tyrosine amino acids were separated on a Dowex cation-exchange column and analyzed by thin layer chromatography. Both human cationic and anionic trypsinogens contained tyrosine sulfate, but no tyrosine phosphate, whereas bovine trypsinogen contained neither. Furthermore, incorporation of [(35)S]SO(4) into human cationic trypsinogen transiently expressed by human embryonic kidney 239T cells was demonstrated. Mutation of Tyr154 to Phe abolished radioactive sulfate incorporation, confirming that Tyr154 is the site of sulfation in cationic trypsinogen. Sulfated pancreatic cationic trypsinogen exhibited faster autoactivation than a nonsulfated recombinant form, suggesting that tyrosine sulfation of trypsinogens might enhance intestinal digestive zymogen activation in humans. Finally, sequence alignment revealed that the sulfation motif is only conserved in primate trypsinogens, suggesting that typsinogen sulfation is absent in other vertebrates.     

Sulfation of porcine parathyroid secretory protein I. Detection of tyrosine sulfate

Secretory Protein I (SP-I) is an acidic glycoprotein that is stored and co-secreted with parathormone by parathyroid glands. It has been found to be chemically similar, if not identical, to chromogranin A of the adrenal medulla and to be present in most endocrine cells. In the present study, 35SO4 was shown to be incorporated into SP-I and several other proteins of porcine parathyroid tissue incubated in vitro. The predominant sulfated species secreted to the medium was SP-I. Up to 20% of the tyrosine residues in secreted SP-I were labeled with 35SO4. Both the cellular and secreted forms migrated on sodium dodecyl sulfate gels as a pair of proteins with apparent molecular weights of 82,000 and 78,000. The 82-kDa protein could be converted to the 78-kDa species by treatment with neuraminidase. Sulfate exists in SP-I as tyrosine sulfate based on the identification of this amino acid by thin layer electrophoresis following alkaline hydrolysis. Extracellular Ca2+ (3 mM) greatly suppressed the secretion of 35SO4-labeled SP-I without affecting the intracellular sulfation of the molecule or the secretion of a minor sulfated protein unrelated to SP-I. The ratio of incorporated 35SO4 to 3H-amino-acid was greater in secreted SP-I than in tissue SP-I, suggesting that much sulfation of this protein occurred during or just before secretion.     

Processing of the gastrin precursor. Modulation of phosphorylated, sulfated, and amidated products.

Post-translational processing of the precursor for rat gastrin yields products that include peptides phosphorylated at Ser96, amidated at Phe92, and sulfated at Tyr87 or Tyr103. The phosphorylation site is immediately adjacent to the processing point that gives rise to the biologically active amidated gastrins. We have examined changes in post-translational processing which occur in gastrin cells from rats that are physiologically stimulated (by feeding) or unstimulated (by fasting). Peptides were identified using site-directed radioimmunoassays and chromatographic systems that resolve phosphorylated, amidated, and sulfated progastrin products, including intermediates generated prior to amidation (i.e. C-terminal glycine-extended variants). Assays for Phe92-amidated peptides and for the C-terminal tryptic fragment of progastrin indicated decreases in the total tissue concentrations of immunoreactive peptide with fasting; in contrast, the tissue concentrations of glycine-extended biosynthetic intermediates were similar in fasted and fed rats. Taken together the data suggest a relative failure in amidation mechanisms in unstimulated cells. The endopeptidase cleavage of progastrin was not influenced significantly by fasting. However, the phosphorylation of peptide products containing Ser96 was depressed significantly in fasted rats. The proportions of amidated peptides sulfated at Tyr87 were generally lower than their corresponding glycine-extended biosynthetic precursors, but in both cases the proportion of peptide in the sulfated form was lower than for peptides sulfated at Tyr103. Feeding did not change the sulfation of amidated heptadecapeptide gastrin or its glycine-extended variant. The results suggest that the mechanisms determining phosphorylation and amidation of progastrin-related peptides depend on the patterns of stimulation of gastrin cells. The observation that decreased phosphorylation is associated with a failure to produce active amidated products is consistent with a regulatory function for phosphorylation in gastrin production.     

Differences in the apical and basolateral pathways for glycosaminoglycan biosynthesis in Madin-Darby canine kidney cells

Serglycin with a green fluorescent protein tag (SG-GFP) expressed in epithelial Madin-Darby canine kidney cells is secreted mainly (85%) into the apical medium, but the glycosaminoglycan (GAG) chains on the SG-GFP protein core secreted basolaterally (15%) carry most of the sulfate added during biosynthesis (Tveit et al. (2005) J. Biol. Chem., 280, 29596-29603). Here we report further differences in apical and basolateral GAG synthesis. The less intensely sulfated chondroitin sulfate (CS) chains on apically secreted SG-GFP are longer than CS chains attached to basolateral SG-GFP, whereas the heparan sulfate (HS) chains are of similar lengths. When the supply of 3'-phosphoadenosine-5'-phosphosulfate (PAPS) is limited by chlorate treatment, the synthesis machinery maintains sulfation of HS chains on basolateral SG-GFP until it is inhibited at 50 mM chlorate, whereas basolateral CS chains lose sulfate already at 12.5 mM chlorate and become longer. Apically, incorporation of 35S-sulfate into CS is reduced to a lesser extent at higher chlorate concentrations than basolateral CS, although apical CS is less intensely sulfated than basolateral CS in control cells. Similar to what was found for basolateral HS, sulfation of apical HS was not reduced at chlorate concentrations below 50 mM. Also, protein-free, xyloside-based GAG chains secreted basolaterally are more intensely sulfated than their apical counterpart, supporting the view that separate apical and basolateral pathways exist for GAG synthesis and sulfation. Introduction of benzyl beta-d-xyloside (BX) to the GAG synthesis machinery reduces the apical secretion of SG-GFP dramatically and also the modification of SG-GFP by HS.     

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.     

In vivo expression and stoichiometric sulfation of the artificial protein sulfophilin, a polymer of tyrosine sulfation sites.

To gain insight into the structural requirements for tyrosine sulfation in vivo, we have constructed and expressed an artificial gene encoding a polypeptide substrate for tyrosylprotein sulfotransferase. This gene codes for a protein, referred to as sulfophilin, which consists of a 12-times repeated heptapeptide unit corresponding to the identified tyrosine sulfation site of chromogranin B (secretogranin I), Glu-Glu-Pro-Glu-Tyr-Gly-Glu. The gene was fused to the signal sequence of secretogranin II to direct the sulfophilin protein to the secretory pathway. Stable expression of the artificial gene in NIH 3T3 cells resulted in the secretion of sulfated sulfophilin. Analysis of the stoichiometry of sulfation revealed that each of the 12 tyrosyl residues in sulfophilin was sulfated. Remarkably, up to 50% of the total protein-bound tyrosine sulfate secreted by the cells was contained in sulfophilin. The results indicate that the structural information contained in the heptapeptide motif is sufficient for stoichiometric tyrosine sulfation to occur in the living cell.     

Tyrosine sulfation: a post-translational modification of proteins destined for secretion?

Protein sulfation was studied in germ-free rats by prolonged in vivo labeling with [35S]sulfate. Specific sets of sulfated proteins were observed in all tissues examined, in leucocytes, and in blood plasma. No protein sulfation was detected in erythrocytes. Analysis of the type of sulfate linkage showed that sulfated proteins secreted into the plasma contained predominantly tyrosine sulfate, whereas sulfated proteins found in tissues contained largely carbohydrate sulfate. This implies some kind of selection concerning the intracellular processing, secretion, turnover or re-uptake of sulfated proteins which is responsible for the enrichment of tyrosine-sulfated proteins in the plasma.     

Expression, tyrosine sulfation, and secretion of yolk protein 2 of Drosophila melanogaster in mouse fibroblasts

Tyrosine sulfation is a post-translational modification in the trans Golgi that has been found in all animal species studied. In the preceding paper (Baeuerle, P. A., Lottspeich, F., and Huttner, W. B. (1988) J. Biol. Chem. 263, 14925-14929), we have identified the site of tyrosine sulfation in an insect secretory protein, yolk protein 2 (YP2) of Drosophila melanogaster. In the present report, tyrosine sulfation of this protein was examined after expression in a heterologous mammalian cell system. Mouse fibroblasts, transfected with Drosophila YP2 genomic DNA inserted into the eucaryotic expression vector pSV2, secreted the fly protein in sulfated form. Analyses of Drosophila YP2 produced by the mouse cells showed that the features of sulfation of this protein were identical to those previously determined for YP2 isolated from flies. YP2 secreted from mouse fibroblasts was found to be exclusively sulfated on tyrosine residues. The stoichiometry of tyrosine sulfation was approximately 1 mol of sulfate/mol of YP2. Sulfate was linked to the same tyrosine residue as in YP2 isolated from flies, tyrosine 172. These results show that essential parameters of the tyrosine sulfation reaction are very similar in insects and mammals and thus highly conserved in evolution.     

Inhibition of tyrosine sulfation in the trans-Golgi retards the transport of a constitutively secreted protein to the cell surface

The effect of tyrosine sulfation on the transport of a constitutively secreted protein, yolk protein 2 (YP2) of Drosophila melanogaster, to the cell surface was investigated after expression of YP2 in mouse fibroblasts. Inhibition of YP2 sulfation was achieved by two distinct approaches. First, the single site of sulfation in YP2, tyrosine 172, was changed to phenylalanine by oligonucleotide-directed mutagenesis. Second, L cell clones stably expressing YP2 were treated with chlorate, a reversible inhibitor of sulfation. Pulse-chase experiments with transfected L cell clones showed that the half-time of transport from the rough endoplasmic reticulum to the cell surface of the unsulfated mutant YP2 and the unsulfated wild-type YP2 produced in the presence of chlorate was 15-18 min slower than that of the sulfated wild-type YP2. Control experiments indicated (a) that the tyrosine to phenylalanine change itself did not affect YP2 transport, (b) that the retardation of YP2 transport by chlorate occurred only with sulfatable but not with unsulfatable YP2, (c) that the transport difference between wild-type and mutant YP2 was not due to the level of YP2 expression, and (d) that transport of the endogenous secretory protein fibronectin was the same in L cell clones expressing wild-type and mutant YP2. Since the half-time of transport of wild-type YP2 from the intracellular site of sulfation, the trans-Golgi, to the cell surface was found to be 10 min, the 15-18-min retardation seen upon inhibition of tyrosine sulfation reflected a two- to threefold increase in the half-time of trans-Golgi to cell surface transport, which was most probably caused by an increased residence time of unsulfated YP2 in the trans-Golgi. The results demonstrate a role of tyrosine sulfation in the intracellular transport of a constitutively secreted protein.     

Effect of phenylalanine on pancreatic amylase secretion in chicks (Gallus domesticus).

1. Effect of phenylalanine (Phe) on pancreatic amylase secretion in growing chicks was investigated in four experiments. 2. In Experiment 1, birds were injected through a wing vein with 0.25 ml Phe at 0, 0.1, 0.5, 2.5 and 12.5 mM in physiological saline. No significant difference was observed in amylase secretion among treatments. 3. Effect of various concentrations of Phe with cholecystokinin (CCK, 0.31 Crick unit) on amylase secretion was investigated in Experiment 2. Amylase secretion increased with time, although no significant effect was detected in Phe treatment. 4. Efficacy of Phe and tyrosine (Tyr) injection with CCK on amylase secretion was compared. There was no significant difference between Phe and Tyr treatments. 5. Birds were injected intraperitoneally with dl-p-chlorophenylalanine (p-CP), which is an inhibitor of phenylalanine hydroxylase, or saline 1 day before the collection of pancreatic amylase in Experiment 4. Both chicks showed increased amylase secretion with CCK (0.31 Crick unit), whereas the response was at a drastically reduced rate in chicks with the p-CP treatment.     

Distinct linkage between post-translational processing and differential secretion of progastrin derivatives in endocrine cells

Prohormones often undergo extensive cellular processing prior to secretion. These post-translational processing events occur in organelles of the constitutive or regulated secretory pathway. The aim of this study was to examine the relationship between post-translational modifications and the secretory pathways taken by peptides derived from progastrin, the prohormone of gastrin, which in vivo is secreted by cells of the pyloric glands and stimulates the release of gastric acid. Targeting progastrin to compartments of the early secretory pathway shows that endoproteolytic processing is initiated in a pre-trans-Golgi network compartment of endocrine but not non-endocrine cells. The resulting N-terminal fragments of progastrin are secreted via the constitutive pathway, whereas endoproteolytically processed C-terminal fragments are secreted via the regulated or constitutive-like pathways. C-terminal fragments derived from progastrin differ in characteristic manners in levels and patterns of carboxyamidation and tyrosine sulfation in accordance with the secretory pathway taken. Point mutations introduced into a sorting motif disrupt these patterns, suggesting that differences in post-translational modifications are attributable to differential intracellular sorting of precursors. The results suggest a two-step sorting mechanism for progastrin leading to differential secretion of processed fragments via different secretory pathways.     

Enhanced release of cholecystokinin in chickens fed diets high in phenylalanine or tyrosine.

1. Whether the ingestion of excess phenylalanine (Phe) or tyrosine (Tyr) in diets alters the release of cholecystokinin (CCK) into the blood was investigated in chickens. A single meal of control, Phe excess, or Tyr excess diets was given through a stomach tube, followed by the CCK determination with specific CCK-8 antibody. 2. Plasma CCK level increased significantly at 30 min after feeding the diets: about 2.5 times the basal level in the control group and about 3 times the basal level in both of the experimental groups. 3. The Phe excess diet significantly delayed crop emptying rates compared to the control diet, while the Tyr diet on the contrary enhanced the emptying rate. 4. Enhanced plasma CCK levels and delayed crop emptying by Phe excess diet are suggested to be associated with depressed food intake.     

Tyrosine sulfation of arylsulfatase A and its peptide

Purified human liver arylsulfatase A (ASA) as well as an ASA peptide (residues 28-39) were sulfated by tyrosyl protein sulfotransferase in vitro. The media, but not the cell lysate, of normal human fibroblasts contained a tyrosine sulfated protein (pI = 4.5-5.5). This protein was not present in either media or cell lysate of human fibroblasts lacking ASA protein. These results suggest that tyrosine sulfation facilitates secretion of ASA and that this may have pathophysiological consequences.     

Identification of the site of sulfation of the fourth component of human complement

The alpha-chain of the fourth component of complement (C4) contains tyrosine sulfate (Karp, D.R. (1983) J. Biol. Chem. 258, 12745-12748). Here we have determined the site and stoichiometry of sulfation of C4 secreted by the human hepatoma-derived cell line Hep G2. C4 was labeled with [35S]sulfate and isolated from culture medium by immunoprecipitation. C4 digested with trypsin and chymotrypsin and analyzed by reverse-phase high-performance liquid chromatography contained a single sulfate-labeled peptide. Digestion of C4 with trypsin alone yielded two major sulfate-labeled peptides, suggesting that there may be some sequence variability in C4 near the site of sulfation. Sequential Edman degradation of tryptic peptides labeled with [3H]tyrosine and [35S]sulfate detected tyrosine residues at positions 5, 13, 16, and 18. Chymotrypsin cleaved 5 residues off the NH2-terminal end of tryptic peptides, yielding a peptide with tyrosine at positions 8, 11, and 13. Comparison of the position of tyrosine residues with the reported sequence of C4 identified the sites of sulfation as tyrosine residues at positions 738, 741, and 743 in the alpha-chain of C4. All 3 of these tyrosine residues appeared to be sulfated. When sulfation of C4 was partially inhibited by addition of catechol to culture medium, three different forms of the peptide were resolved by high-performance liquid chromatography, consistent with peptides containing 1, 2, or 3 sulfates. Comparison of the quantities of tyrosine and tyrosine sulfate in C4 which had been labeled with [3H]tyrosine and digested with Pronase also indicated that C4 contained an average of 2-3 residues of tyrosine sulfate/molecule. These results suggest that the biologically active form of the protein is sulfated.     

Heterogeneity in the tyrosine sulfation of Chinese hamster ovary cell produced recombinant FVIII

By the use of recombinant technology, several stable Chinese hamster ovary (CHO) cell lines expressing human FVIII were established. Thrombin treatment and SDS-PAGE analysis of the purified recombinant FVIII (rFVIII) revealed a striking difference from plasma-derived FVIII (pFVIII). A 43-kDa fragment of the FVIII heavy chain appears as a double band from rFVIII, while a single band from pFVIII is observed. All other fragments from the two samples appeared similar by SDS-PAGE. The heterogeneity is caused by incomplete tyrosine sulfation of one or more of the three potential tyrosine sulfation sites (Tyr718, Tyr719, Tyr723). To investigate if there is a general limitation and heterogeneity in the tyrosine sulfation of rFVIII, two other potential tyrosine sulfation sites on the FVIII light chain (Tyr1664, Tyr1680) were analyzed. The results show that both sites on the pFVIII light chain and on the rFVIII light chain are completely sulfated. The limitation of CHO cells to tyrosine sulfate rFVIII is therefore only restricted to a few sites. The two sulfated forms of rFVIII can easily be separated by ion-exchange chromatography, indicating the importance of the sulfate groups on the charge and/or conformation of FVIII. Both forms of rFVIII possess identical in vitro coagulation activity, von Willebrand factor binding, and thrombin activation profile. However, the difference in tyrosine sulfation may change other biological properties of FVIII.     

Patterns of prohormone processing. Order revealed by a new procholecystokinin-derived peptide.

An 83-amino acid cholecystokinin peptide with a sulfated tyrosine and an amidated carboxyl terminus (CCK-83) was purified from human intestinal mucosa. The purified peptide was chemically characterized, and its bioactivity was compared to CCK-8. Several post-translational processing steps such as cleavage at basic residues, sulfation, and amidation are necessary to form biologically active cholecystokinin from its nascent prepropeptide. The discovery of CCK-83 gives new insight into the order of preprohormone processing. The processing of prepro-CCK appears to be in the order of: 1) signal peptidase cleavage, 2) tyrosine sulfation, 3) cleavage after a carboxyl-terminal pair of basic residues, 4) carboxypeptidase B-like cleavage of these basic residues, 5) amidation (which results in the formation of CCK-83), and 6) cleavage at monobasic residues by endopeptidases (which results in the smaller molecular forms of cholecystokinin). The characterization of biologically active CCK-83 with a sulfated tyrosine and an amidated carboxyl terminus establishes the site of signal peptidase action and suggests an order of post-translational modifications that give rise to the various molecular forms of cholecystokinin.