Biosynthesis and degradation of altered immature forms of intestinal dipeptidyl peptidase IV in a rat strain lacking the enzyme.

We have used a strain of rat (Fischer 344) lacking brush border membrane dipeptidyl peptidase IV activity to examine its effect on the intestinal assimilation of prolyl peptides. In addition, we have examined the biochemical basis for the enzyme deficiency. An analysis of several brush border membrane hydrolases in different regions of the small intestine demonstrates that these rats lack only dipeptidyl peptidase IV. They also have a greatly reduced ability to hydrolyze and absorb in vivo peptides of the NH2-X-Pro-Y type which are known substrates for the enzyme. Immunoblot analysis with polyclonal and monoclonal antibody indicates that the animals lack an identifiable dipeptidyl peptidase IV protein in intestinal epithelial cells. Levels and types of dipeptidyl peptidase IV mRNA were analyzed in several tissues and found to be similar to that of control animals. Biosynthetic labeling of intestinal explants revealed that two distinct forms (102 and 108 kDa) of dipeptidyl peptidase IV are initially synthesized by deficient rats, in contrast to the single protein (106 kDa) observed in normal animals. Pulse-chase labeling experiments (+/- endoglycosidase H) show that these two altered forms of dipeptidyl peptidase IV, although initially glycosylated with N-linked high mannose carbohydrate, fail to be processed to the mature complex glycosylated form and undergo intracellular degradation.     

Biochemical characterization of domain-specific glycoproteins of the rat hepatocyte plasma membrane

Seven integral proteins (CE 9, HA 21, HA 116, HA 16, HA 4, HA 201, and HA 301) were isolated from rat hepatocyte plasma membranes by immunoaffinity chromatography on monoclonal antibody-Sepharose. Six of the proteins (all but HA 16) exhibit domain-specific localizations (either bile canalicular or sinusoidal/lateral) about the hepatocyte surface. We identified three of these protein antigens as leucine aminopeptidase (HA 201), dipeptidyl peptidase IV (HA 301), and the asialoglycoprotein receptor (HA 116). We also developed 125I-lectin blotting procedures that, when used in conjunction with chemical and glycosidase treatments, permitted a comparison of the types of oligosaccharides present on the seven proteins. All seven are sialoglycoproteins, based upon the effects of prior neuraminidase and periodate-aniline-cyanoborohydride treatments of blots on labeling by 125I-wheat germ agglutinin. 125I-labeled Ricinus communis agglutinin I and 125I-peanut agglutinin blotting of the desialylated proteins revealed few if any conventional O-linked oligosaccharides, suggesting that the sialyl residues represent termini of N-linked complex-type oligosaccharides. Depending upon the protein, we estimated the presence of 2-26 N-linked oligosaccharides/polypeptide chain from the Mr reductions accompanying chemical or enzymatic deglycosylation. Three of these mature plasma membrane proteins (HA 21, HA 116, and HA 4) have both high mannose-type and complex-type oligosaccharides on every copy of their polypeptide chains. The labeling of these three proteins by 125I-concanavalin A was sensitive to treatment with endoglycosidase H, and each exhibited a quantitative reduction in Mr after the treatment, as assessed independently by 125I-wheat germ agglutinin blotting. At this level of analysis, we were unable to discern differences in the types of oligosaccharides present on these seven glycoproteins that correlate with their patterns of expression within the plasma membrane domains of this polarized epithelial cell.     

Alteration in the regulation of plasma membrane glycoproteins of the hepatocyte during ontogeny

The expression of four integral membrane glycoproteins was examined in detail utilizing monospecific antibodies during liver development. These included asialoglycoprotein receptor, a hepatocyte glycoprotein residing in the sinusoidal domain, and three bile canalicular glycoproteins, leucine aminopeptidase, dipeptidyl peptidase IV, and a Mr 110,000 glycoprotein denoted GP 110. It was observed that asialoglycoprotein receptor, GP 110, and dipeptidyl peptidase IV were present in low amounts in fetal liver and reached adult levels between 1 to 3 weeks. In contrast, leucine aminopeptidase was present in nearly adult amounts in 18-day-old fetal livers. These observations were qualitatively confirmed by indirect immunofluorescent staining of frozen thin liver sections obtained from fetal and adult rats. Further, in fetal livers it was found that leucine aminopeptidase was not localized to typical bile canalicular areas. Immunoprecipitation studies performed in the presence of proteolytic inhibitors using detergent-solubilized extracts of metabolically labeled liver minces revealed that GP 110 was present in low amounts as Mr 110,000 and Mr 105,000 polypeptides in 17-day fetal livers but by 21 days of gestation the larger polypeptide was the major synthesis product. Conversely, the apparent molecular weights of leucine aminopeptidase and dipeptidyl peptidase IV were not altered during development. Experiments determining relative rates of synthesis using excess amounts of antibodies showed that the concentrations of the three bile canalicular glycoproteins in liver during ontogeny reflect their rates of synthesis. These results underscore that plasma membrane constituents of the hepatocyte undergo dramatic changes in expression and localization as the liver changes its physiological role at birth.     

Role of hepatocyte nuclear factor 1alpha and 1beta in the transcriptional regulation of human dipeptidyl peptidase IV during differentiation of Caco-2 cells

Caco-2 cells undergo differentiation to an enterocytic-like cell when maintained in a post-confluent state for 1-2 weeks. During this period Caco-2 cells begin to express high levels brush border membrane associated enzymes such as dipeptidyl peptidase IV. Using the dipeptidyl peptidase IV gene promoter in electrophoretic mobility shift assays, we have shown for the first time that levels of hepatocyte nuclear factor 1alpha increase three- to fourfold during Caco-2 cell differentiation. Transient cotransfection experiments with 3T3 cells using dipeptidyl peptidase IV promoter constructs and expression vectors containing hepatocyte nuclear factor 1alpha and beta show that the ratio of alpha and beta modulates reporter gene expression. These results suggest that the increase in levels of hepatocyte nuclear factor 1alpha that occur during intestinal cell differentiation, are important for expression of dipeptidyl peptidase IV and other intestinal proteins.     

An assay of dipeptidyl peptidase IV activity in human serum and serum of pregnant women with glycyl-L-proline-1-naphthylamide and other glycyl-L-proline-arylamides as substrates

The authors described a micromethod for measuring dipeptidyl peptidase IV activity in human serum with glycyl-L-proline-1-naphthylamide as substrate. The method requires less than 20 microliters of serum. The pH optimum for cleaving glycyl-L-proline-1-naphthylamine by the enzyme in human serum in Tris-HCl buffer was 8.0 and Km value was established as 7.2 X 10(-4) mol/l. The advantage of this substrate is the absence of spontaneous hydrolysis during the assay of enzyme activity in contrast to glycyl-L-proline-4-nitroanilide. The Km values of the latter substrates and glycyl-L-proline-2-naphthylamide in the same buffer were 1.0 X 10(-4) mol/l and 2.4 X 10(-4) mol/l, respectively. Glycyl-D-proline-4-nitroanilide was not hydrolyzed by the dipeptidyl peptidase IV present in human serum. The activities of dipeptidyl peptidase IV in the sera from 30 healthy human subjects with glycyl-L-proline-1-naphthylamide as substrate were 176.1 +/- 32.8 nkat/l (mean +/- standard deviation; range 100.2-264.1 nkat/l of serum). In this group men had significantly (P less than 0.01) higher activity of the enzyme than women. The cleaving of glycyl-L-proline-1-naphthylamide and glycyl-L-proline-4-nitro anilide by dipeptidyl peptidase IV in human sera was closely correlated (r = 0.86). During normal pregnancy the activity of dipeptidyl peptidase IV in human serum decreases markedly in the first half of pregnancy. After delivery, the serum enzyme activity returns progressively to initial levels.     

Biogenesis of plasma membrane glycoproteins. Tracer kinetic study of two rat liver plasma membrane glycoproteins in vivo

Antibodies to purified nucleotide pyrophosphatase (NPPase) and dipeptidyl peptidase IV (DPP IV) were used to study the biogenesis of these rat liver plasma membrane glycoproteins in vivo. Following injection of tritiated leucine, the radioactivity in NPPase and DPP IV decayed at markedly different rates in the plasma membrane, with apparent half-lives of about 1 and 5 days, respectively. In short term experiments, labeling of total plasma membrane proteins was rapid and insensitive to colchicine, while labeling of both NPPase and DPP IV showed a lag of about 15 min, followed by colchcine-sensitive/cycloheximide-insensitive increases to half-maximal and maximal values at about 1 and 2 h, respectively. A peak of labeled DPP IV in rough microsomes at 15 min showed increased mobility on polyacrylamide gels and was largely inaccessible to antibodies in intact microsomes, consistent with its being an underglycosylated precursor, exposed on the cisternal side of the rough endoplasmic reticulum. In contrast, the behavior of unlabeled DPP IV in preparations of rough microsomes and Golgi was consistent with its being contributed by contaminating right-side-out plasma membrane vesicles. This conclusion was also necessary to fit the tracer kinetic data to a simple membrane-flow model, which gave precursor pools (1 microgram/g of liver) and fluxes (1 microgram/h/g of liver) for both DPP IV and NPPase which were about 3 orders of magnitude less than those for the synthesis of rat serum albumin. Thus, unlike hepatoma tissue culture cells (Doyle, D., Baumann, H., England, B., Friedman, E., Hou, E., and Tweto, J. (1978) J. Biol. Chem. 253, 967-973), normal rat liver does not contain large amounts of preformed intracellular plasma membrane precursors.     

Dipeptidyl peptidase IV of human lymphocytes. Evidence for specific hydrolysis of glycylproline p-nitroanilide in T-lymphocytes.

Glycylproline p-nitroanilide is hydrolysed in lymphocytes from human blood exclusively by dipeptidyl peptidase IV. This was demonstrated by specific inhibition with N-alanylprolyl-O-(4-nitrobenzoyl)hydroxylamine and di-isopropyl phosphorofluoridate and by studying the membrane localization of dipeptidyl peptidase IV and determining specific dipeptidyl peptidase II activity. Additional evidence that dipeptidyl peptidase IV is a marker for T-lymphocytes, obtained from determinations of biochemical activity on intact lymphocyte preparations and correlation studies with other T-cell markers, is also presented.     

The establishment of hepatocyte cell surface polarity during fetal liver development

Antibodies to six glycoproteins present in different domains of the hepatocyte plasma membrane were used to study the establishment of cell surface polarity during rat fetal liver development. The proteins were immunoprecipitated from fetal liver homogenates between 14 and 21 days of gestation and quantified by immunoblotting. Aminopeptidase N, CE 9, and HA 321, which reside in the apical, basolateral, and lateral plasma membrane in the adult hepatocyte, respectively, were present in high concentrations at 14 days of gestation and remained high until birth. In contrast, two apical proteins (HA 4 and dipeptidyl peptidase IV) and two basolateral proteins (ASGP receptor and EGF receptor) were first detected between 16 and 18 days of gestation and increased linearly until birth. HA 4 was the only molecule for which the fetal and adult forms differed, with the former having a faster mobility on SDS-PAGE, due to differences in N-linked oligosaccharides. With two exceptions, the localization of the molecules from earliest detection was restricted to the same domain as that in the adult. At 15 days of gestation, HA 321 and a small portion of aminopeptidase were detected on the basolateral membrane. By 21 days both molecules had assumed their adult localization pattern. Our results indicate that the biogenesis of cell surface polarity is an early event, implying that the mechanisms for sorting plasma membrane molecules are functional very early in development. Furthermore, the different patterns of appearance of the six molecules, irrespective of domain, indicate that the biochemical composition of the cell surface changes dramatically during fetal liver development.     

Remodeling of a rat hepatocyte plasma membrane glycoprotein. De- and reglycosylation of dipeptidyl peptidase IV

The present paper demonstrates the terminal de- and reglycosylation of a rat hepatocyte plasma membrane glycoprotein, dipeptidyl peptidase IV (DPP IV). Cultured hepatocytes were used in pulse-chase experiments with [3H]L-fucose and [14C]N-acetyl-D-mannosamine as markers for terminal carbohydrates, [3H]D-mannose as marker of a core-sugar, and [35S]L-methionine for labeling the protein backbone. Membrane DPP IV was immunoprecipitated with a polyclonal antibody which bound selectively at 4 degrees C to the cell-surface glycoprotein. The times of maximal labeling of hepatocyte plasma membrane DPP IV were 6-9 min for [3H]L-fucose, 20 min for [3H]D-mannose, and 25 min for [35S]L-methionine. When antibodies were bound to cell-surface DPP IV at 4 degrees C, the immune complex remained stable for more than 1 h after rewarming to 37 degrees C, despite ongoing metabolic and membrane transport processes. This was shown by pulse labeling with [35S]L-methionine at 37 degrees C, followed by cooling to 4 degrees C, and addition of antibody against plasma membrane DPP IV. During rewarming, the radioactivity in the complex remained constant. In a similar experiment with [3H]L-fucose, the radioactivity in the immune complex declined rapidly, indicating a defucosylation of the plasma membrane glycoprotein. Using the same experimental design with [3H]D-mannose, the radioactivity in the immune complex remained constant, showing that the core-sugar D-mannose is not cleaved from the membrane glycoprotein. Terminal reglycosylation (refucosylation and resialylation) was demonstrated as follows. Hepatocytes were maintained at 37 degrees C in a medium supplemented with tunicamycin in order to block the de novo synthesis of N-glycosidically bound carbohydrate chains. At 4 degrees C the antibody against DPP IV bound only to cell surface glycoprotein. During the rewarming period at 37 degrees C, radioactivity from [3H]L-fucose and [14C]N-acetyl-D-mannosamine became incorporated into the immune complex. This indicates a fucosylation and sialylation of the glycoprotein originally present at the cell surface. The mechanisms whereby terminal de- and reglycosylation of plasma membrane glycoproteins may occur during membrane recycling are discussed.     

Specific localization of membrane dipeptidase and dipeptidyl peptidase IV in secretion granules of two different pancreatic islet cells.

Endocrine cells require several protein convertases to process the precursors of hormonal peptides that they secrete. In addition to the convertases, which have a crucial role in the maturation of prohormones, many other proteases are present in endocrine cells, the roles of which are less well established. Two of these proteases, dipeptidyl peptidase IV (EC 3.4.14.5) and membrane dipeptidase (EC 3.4.13.19), have been immunocytochemically localized in the endocrine pancreas of the pig. Membrane dipeptidase was present exclusively in cells of the islet of Langerhans that were positive for the pancreatic polypeptide, whereas dipeptidyl peptidase IV was restricted to cells positive for glucagon. Both enzymes were observed in the content of secretory granules and therefore would be released into the interstitial space as the granules undergo exocytosis. At this location they could act on secretions of other islet cells. The relative concentration of dipeptidyl peptidase IV was lower in dense glucagon granules, where the immunoreactivity to glucagon was higher, and vice versa for light granules. This suggests that, in A-cells, dipeptidyl peptidase IV could be sent for degradation in the endosomal/lysosomal compartment during the process of granule maturation or could be removed from granules for continuous release into the interstitial space. The intense proteolytic activity that takes place in the endocrine pancreas could produce many potential dipeptide substrates for membrane dipeptidase. (J Histochem Cytochem 47:489-497, 1999)     

Are diprotin A (Ile-Pro-Ile) and diprotin B (Val-Pro-Leu) inhibitors or substrates of dipeptidyl peptidase IV?

Dipeptidyl peptidase IV preferably hydrolyzes peptides and proteins with a penultimate proline residue. Umezawa and co-workers (Umezawa et al. (1984) J. Antibiotics 37, 422-425) reported that diprotin A (Ile-Pro-Ile) and diprotin B (Val-Pro-Leu) are inhibitors for dipeptidyl peptidase IV. We could show that both compounds as well as other tripeptides with a penultimate proline residue are substrates for dipeptidyl peptidase IV. An apparent competitive inhibition by those compounds is a kinetic artifact due to the substrate-like structure of such tripeptides.     

Comparative effects of GLP-1 and GIP on cAMP production, insulin secretion, and in vivo antidiabetic actions following substitution of Ala8/Ala2 with 2-aminobutyric acid

The two major incretin hormones, glucagon-like peptide-1 (GLP-1), and glucose-dependent insulinotropic polypeptide (GIP), are currently being considered as prospective drug candidates for treatment of type 2 diabetes. Interest in these gut hormones was initially spurred by their potent insulinotropic activities, but a number of other antihyperglycaemic actions are now established. One of the foremost barriers in progressing GLP-1 and GIP to the clinic concerns their rapid degradation and inactivation by the ubiquitous enzyme, dipeptidyl peptidase IV (DPP IV). Here, we compare the DPP IV resistance and biological properties of Abu8/Abu2 (2-aminobutyric acid) substituted analogues of GLP-1 and GIP engineered to impart DPP IV resistance. Whereas (Abu8)GLP-1 was completely stable to human plasma (half-life >12 h), GLP-1, GIP, and (Abu2)GIP were rapidly degraded (half-lives: 6.2, 6.0, and 7.1 h, respectively). Native GIP, GLP-1, and particularly (Abu8)GLP-1 elicited significant adenylate cyclase and insulinotropic activity, while (Abu2)GIP was less effective. Similarly, in obese diabetic (ob/ob) mice, GIP, GLP-1, and (Abu8)GLP-1 displayed substantial glucose-lowering and insulin-releasing activities, whereas (Abu2)GIP was only weakly active. These studies illustrate divergent effects of penultimate amino acid Ala8/Ala2 substitution with Abu on the biological properties of GLP-1 and GIP, suggesting that (Abu8)GLP-1 represents a potential candidate for future therapeutic development.     

Dipeptidyl peptidase IV activity and/or structure homologs: Contributing factors in the pathogenesis of rheumatoid arthritis?

Several of the proinflammatory peptides involved in rheumatoid arthritis pathogenesis, including peptides induced downstream of tumor necrosis factor-α as well as the monocyte/T cell-attracting chemokines RANTES and stromal cell-derived factor (SDF)-1α and the neuropeptides vasoactive intestinal peptide (VIP) and substance P, have their biological half-lives controlled by dipeptidyl peptidase IV (DPPIV). Proteolysis by DPPIV regulates not only the half-life but also receptor preference and downstream signaling. In this article, we examine the role of DPPIV homologs, including CD26, the canonical DPPIV, and their substrates in the pathogenesis of rheumatoid arthritis. The differing specific activities of the DPPIV family members and their differential inhibitor response provide new insights into therapeutic design.     

Biosynthesis and metabolism of dipeptidylpeptidase IV in primary cultured rat hepatocytes and Morris hepatoma 7777 cells.

N-Glycosylation, biosynthesis and degradation of dipeptidylpeptidase IV (EC 3.4.14.5) (DPP IV) were comparatively studied in primary cultured rat hepatocytes and Morris hepatoma 7777 cells (MH 7777 cells). DPP IV had a molecular mass of 105 kDa in rat hepatocytes and of 103 kDa in MH 7777 cells as assessed by SDS/PAGE under reducing conditions. This difference in molecular mass was caused by differences in covalently attached N-glycans. DPP IV from hepatoma cells contained a higher proportion of N-glycans of the oligomannosidic or hybrid type and therefore migrated at a slightly lower molecular mass. In both cell types DPP IV was initially synthesized as a 97-kDa precursor which was completely susceptible to digestion with endo-beta-N-acetylglucosaminidase H converting the molecular mass to 84 kDa. The precursor was processed to the mature forms of DPP IV, glycosylated with N-glycans mainly of the complex type with a half-life of 20-25 min. The transit of newly synthesized DPP IV to the cell surface displayed identical or very similar kinetics in both cell types with the major portion of DPP IV appearing at the cell surface after 60 min. DPP IV molecules were very slowly degraded in hepatocytes as well as in hepatoma cells with half-lives of approximately 45 h. Inhibition of oligosaccharide processing with 1-deoxymannojirimycin led to the formation of DPP IV molecules containing N-glycans of the oligomannosidic type. This glycosylation variant was degraded with the same half-life as complex-type glycosylated DPP IV. By contrast, inhibition of N-glycosylation with tunicamycin resulted into rapid degradation of non-N-glycosylated DPP IV molecules in both cell types. Non-N-glycosylated DPP IV could not be detected at the cell surface indicating an intracellular proteolytic process soon after biosynthesis.     

Quantitative immunogold localization of dipeptidyl peptidase IV (DPP IV) in rat liver cells

We investigated ultrastructural localization of dipeptidyl peptidase IV (DPP IV) [EC3.4.14 5] in rat liver cells quantitatively by post embedding protein A-gold technique. In the hepatocyte, DPP IV was mainly localized on the bile canalicular surface and the lysosomal membranes, but were scarcely detectable on the sinusoid-lateral surface. A small number of DPP IV was also detected in the trans region of the Golgi apparatus, suggesting that this part may play important roles in intracellular transport or recycling of this enzyme. In the endothelial cell, DPP IV existed on the whole surface of the plasma membrane and the lysosomes. In the Kupffer cell DPP IV was mainly localized in lysosomes and a few were detected on the plasma membrane.     

Demonstration of two molecular forms of dipeptidyl peptidase IV in normal human serum

The heterogeneity of dipeptidyl peptidase IV (EC 3.4.14.5) was investigated in normal human serum. Thin-layer analytical isoelectric focusing revealed the presence of multiple molecular forms of the enzyme, their isoelectric points being in the pH range of 3.30-4.25. The maximum of enzyme activity appeared around pH 3.50. After treatment with neuraminidase the pI shifted to 4.70-5.40 with two maxima at pH 5.00 and 5.15. The Triton X-100 solubilized as well as the papain-treated-Triton X-100 solubilized enzyme from the whole human adult jejunal biopsy were also found to be heterogeneous. They focused--both before and after neuraminidase treatment--at pH values different from those of the enzyme of normal human serum. There was almost no pI shift after neuraminidase treatment of the intestinal enzyme from adult enterobiopsy. Electrophoresis in continuous polyacrylamide gradient gels as well as gel chromatography on Bio-Gel A-1.5m revealed two molecular forms of dipeptidyl peptidase IV in normal human serum. The estimated relative molecular mass of the major enzyme form was 250 000 in both the separation techniques used. On the other hand, the apparent relative molecular mass of the minor enzyme form was 450 000 as assessed by gradient gel electrophoresis, and 550 000, when estimated by gel chromatography. The Km values for glycyl-L-proline-4-nitroanilide as substrate with the major and minor forms of the serum enzyme were 1.60 +/- 0.39 X 10(-4) mol/l and 1.60 +/- 0.13 X 10(-4) mol/l, respectively. Our results indicate that the dipeptidyl peptidase IV in normal human serum is a heterogeneous enzyme as far as its charge and molecular size are concerned.     

Reconstitution of purified dipeptidyl peptidase IV. A comparison with aminopeptidase N with respect to morphology and influence of anchoring peptide on function

The pig small intestinal dipeptidyl peptidase IV was asymmetrically integrated into egg phosphatidylcholine and microvillar lipid vesicles prepared by a beta-octylglucoside dialysis method. The enzyme molecules appeared dumbell-shaped ((11.0-11.5) X (5.0-5.5)nm) and were separated from the liposomal membrane by a stain-filled gap of about 2.5 nm, representing the 'junctional segment'. The influence of lipid bilayer and detergents on the kinetic parameters of amphiphilic and hydrophilic forms of aminopeptidase N and dipeptidyl peptidase IV was studied. Since the lipid bilayer and detergents, which interact only with the anchoring root, had no crucial effect on the kinetic parameters of the different forms of the enzymes, it is concluded that the anchoring roots exert little effect on the catalytic domain of the stalked integral membrane proteins.     

Distribution of peptidases in cultured cells from middle ear mucosa: prolyl endopeptidase is localized in fibroblasts and dipeptidyl peptidase IV and II in epithelial cells.

To examine the distribution of prolyl endopeptidase (PEP), dipeptidyl peptidase IV (DPP IV), and dipeptidyl peptidase II (DPP II) in specific cell types, fibroblasts and epithelial cells were selectively cultured from middle ear mucosal tissues of guinea pigs. In fibroblasts, PEP had the highest activity, 12.28 +/- 4.00 nmole/min/mg protein (mean +/- SD), 45-fold higher than corresponding DPP II levels. In epithelial cells, DPP IV activity was the highest, 6.48 +/- 0.90 nmole/min/mg protein. This communication describes, for the first time, the distribution of the enzyme activities of PEP, DPP IV, and DPP II in fibroblasts and epithelial cells, and the occurrence of PEP in fibroblasts.     

Extended investigation of the substrate specificity of dipeptidyl peptidase IV from pig kidney.

The substrate specificity of dipeptidyl peptidase IV (dipeptidyl peptide hydrolase, EC 3.4.14.5) from pig kidney was investigated, using a series of substrates, in which the amino-acid residue in position P1, a structural derivative of proline, was altered with respect to ring size and substituents. It was demonstrated that dipeptidyl peptidase IV hydrolyses substrates of the type Ala-X-pNA, where X is proline (Pro), (R)-thiazolidine-4-carboxylic acid (Thz), (S)-pipecolic acid (Pip), (S)-oxazolidine-4-carboxylic acid (Oxa), or (S)-azetidine-2-carboxylic acid (Aze). The ring size and ring structure of the residue in the P1 position influence the rate of enzyme-catalysed hydrolysis of the substrate. The highest kcat value (814 s-1) was found for Ala-Aze-pNA. In contrast, the kcat value for Ala-Pro-pNA is nearly 55 s-1. With all substrates of this series, the rate-limiting step of the hydrolysis by dipeptidyl peptidase IV is the deacylation reaction. Compounds of substrate-like structure, in which the P2 residue has an R-configuration, are not hydrolysed by dipeptidyl peptidase IV.     

The degradation of bioactive peptides and proteins by dipeptidyl peptidase IV from human placenta

The degradation of several bioactive peptides and proteins by purified human dipeptidyl peptidase IV is reported. It was hitherto unknown that human gastrin-releasing peptide, human chorionic gonadotropin, human pancreatic polypeptide, sheep prolactin, aprotinin, corticotropin-like intermediate lobe peptide and (Tyr-)melanostatin are substrates of this peptidase. Kinetic constants were determined for the degradation of a number of other natural peptides, including substance P, the degradation of which has been described earlier in a qualitative manner. Generally, small peptides are degraded much more rapidly than proteins. However, the Km-values seem to be independent of the peptide chain length. The influence of the action of dipeptidyl peptidase IV on the biological function of peptides and proteins is discussed.