Interleukin 2 production by human T lymphocytes identified by antibodies to dipeptidyl peptidase IV

T-Cell subsets identified by polyclonal and monoclonal antibodies to dipeptidyl peptidase IV (DP IV) were investigated. Analysis in a cytofluorograf revealed 63 +/- 7% positive scatter-gated T lymphocytes. DP IV-positive cells were found to be T11+, 74-81% OKT4+, and 12-19% OKT8+. DP IV-negative cells were T11+ and comprise 16-40% OKT8+, and 10-30% OKT4+ T cells. Treatment of T lymphocytes with rabbit anti-DP IV and complement as well as the presence of rabbit anti-DP IV during culture resulted in a reduction of interleukin 2 (IL-2) production. This reduction was not observed with the mouse monoclonal anti-DP IV antibody II-19-4-7. Positive enrichment of DP IV-positive lymphocytes by cell sorting revealed excellent IL-2 production of DP IV-positive cells and very poor IL-2 activity in supernatants obtained from DP IV-negative lymphocytes. Thus, DP IV may serve as cell surface marker for IL-2-producing T lymphocytes.     

Dipeptidyl peptidase IV in the immune system. Effects of specific enzyme inhibitors on activity of dipeptidyl peptidase IV and proliferation of human lymphocytes.

Dipeptidyl peptidase IV (DP IV) is a membrane peptidase playing a significant role in the process of activation and proliferation of human thymus-derived lymphocytes. This conclusion is drawn from (1) the induction of this enzyme on mitogen-activated T lymphocytes (cf. Sch?n, E. & Ansorge, S. (1990) Biol. Chem. Hoppe-Seyler 371, 699-705) and (2) the impairment of different functions of activated T cells in the presence of specific inhibitors and antibodies against DP IV (Sch?n, E. & al. (1987) Eur. J. Immunol 17, 1821-1826). This paper is aimed at testing new active site-specific peptide inhibitors for their efficiency as inhibitors of lymphocyte DP IV and DNA synthesis of mitogen-stimulated lymphocytes. These inhibitors comprise (i) diacylhydroxylamine derivatives of Xaa-Pro or Xaa-Ala peptides, (ii) different oligopeptides with N-terminal Xaa-Pro-sequences, and (iii) amino-acid amides of the pyrrolidide and the thiazolidide type. The thiazolidides of epsilon-(4-nitrobenzyloxycarbonyl)-L-lysine and of L-isoleucine as well as Ala-Pro-nitrobenzoylhydroxylamine are the most effective inhibitors in both test systems, yielding half-maximal inhibitory concentrations in the micromolar range. Cell viability was not impaired in this effective concentration range. Other inhibitors of DP IV are one to two orders of magnitude less efficient in the suppression of lymphocyte proliferation.     

Ser2]- and [SerP2] incretin analogs: comparison of dipeptidyl peptidase IV resistance and biological activities in vitro and in vivo

Glucagon-like peptide-1 (GLP-1) and glucose-dependent insulinotropic polypeptide (GIP; also known as gastric inhibitory polypeptide) are incretin hormones that reduce postprandial glycemic excursions via enhancing insulin release but are rapidly inactivated by enzymatic N-terminal truncation. As such, efforts have been made to improve their plasma stability by synthetic modification or by inhibition of the responsible protease, dipeptidyl peptidase (DP) IV. Here we report a parallel comparison of synthetic GIP and GLP-1 with their Ser2- and Ser(P)2-substituted analogs, examining receptor binding and activation, metabolic stability, and biological effects in vivo. Both incretins and their Ser2-substituted analogs showed similar EC50s (0.16-0.52 nm) and IC50s (4.3-8.1 nm) at their respective cloned receptors. Although both phosphoserine 2-modified (Ser(PO3H2); Ser(P)) peptides were able to stimulate maximal cAMP production and fully displace receptor-bound tracer, they showed significantly right-shifted concentration-response curves and binding affinities. Ser2-substituted analogs were moderately resistant to DP IV cleavage, whereas [Ser(P)2]GIP and [Ser(P)2] GLP-1 showed complete resistance to purified DP IV. It was shown that the Ser(P) forms were dephosphorylated in serum and thus in vivo act as precursor forms of Ser2-substituted analogs. When injected subcutaneously into conscious Wistar rats, all peptides reduced glycemic excursions (rank potency: [Ser(P)2]incretins > or = [Ser2] incretins > native hormones). Insulin determinations indicated that the reductions in postprandial glycemia were at least in part insulin-mediated. Thus it has been shown that despite having low in vitro bioactivity using receptor-transfected cells, in vivo potency of [Ser(P)2] incretins was comparable with or greater than that of native or [Ser2]peptides. Hence, Ser(P)2-modified incretins present as novel glucose-lowering agents.     

Different modes of dipeptidyl peptidase IV (CD26) inhibition by oligopeptides derived from the N-terminus of HIV-1 Tat indicate at least two inhibitor binding sites.

Dipeptidyl peptidase IV (DP IV, CD26) plays an essential role in the activation and proliferation of lymphocytes, which is shown by the immunosuppressive effects of synthetic DP IV inhibitors. Similarly, both human immunodeficiency virus-1 (HIV-1) Tat protein and the N-terminal peptide Tat(1-9) inhibit DP IV activity and T cell proliferation. Therefore, the N-terminal amino acid sequence of HIV-1 Tat is important for the inhibition of DP IV. Recently, we characterized the thromboxane A2 receptor peptide TXA2-R(1-9), bearing the N-terminal MWP sequence motif, as a potent DP IV inhibitor possibly playing a functional role during antigen presentation by inhibiting T cell-expressed DP IV [Wrenger, S., Faust, J., Mrestani-Klaus, C., Fengler, A., St?ckel-Maschek, A., Lorey, S., K?hne, T., Brandt, W., Neubert, K., Ansorge, S. & Reinhold, D. (2000) J. Biol. Chem.275, 22180-22186]. Here, we demonstrate that amino acid substitutions at different positions of Tat(1-9) can result in a change of the inhibition type. Certain Tat(1-9)-related peptides are found to be competitive, and others linear mixed-type or parabolic mixed-type inhibitors indicating different inhibitor binding sites on DP IV, at the active site and out of the active site. The parabolic mixed-type mechanism, attributed to both non-mutually exclusive inhibitor binding sites of the enzyme, is described in detail. From the kinetic investigations and molecular modeling experiments, possible interactions of the oligopeptides with specified amino acids of DP IV are suggested. These findings give new insights for the development of more potent and specific peptide-based DP IV inhibitors. Such inhibitors could be useful for the treatment of autoimmune and inflammatory diseases.     

Down-regulation of T cell activation following inhibition of dipeptidyl peptidase IV/CD26 by the N-terminal part of the thromboxane A2 receptor

Using synthetic inhibitors, it has been shown that the ectopeptidase dipeptidyl peptidase IV (DP IV) (CD26) plays an important role in the activation and proliferation of T lymphocytes. The human immunodeficiency virus-1 Tat protein, as well as the N-terminal nonapeptide Tat(1-9) and other peptides containing the N-terminal sequence XXP, also inhibit DP IV and therefore T cell activation. Studying the effect of amino acid exchanges in the N-terminal three positions of the Tat(1-9) sequence, we found that tryptophan in position 2 strongly improves DP IV inhibition. NMR spectroscopy and molecular modeling show that the effect of Trp(2)-Tat(1-9) could not be explained by significant alterations in the backbone structure and suggest that tryptophan enters favorable interactions with DP IV. Data base searches revealed the thromboxane A2 receptor (TXA2-R) as a membrane protein extracellularly exposing N-terminal MWP. TXA2-R is expressed within the immune system on antigen-presenting cells, namely monocytes. The N-terminal nonapeptide of TXA2-R, TXA2-R(1-9), inhibits DP IV and DNA synthesis and IL-2 production of tetanus toxoid-stimulated peripheral blood mononuclear cells. Moreover, TXA2-R(1-9) induces the production of the immunosuppressive cytokine transforming growth factor-beta1. These data suggest that the N-terminal part of TXA2-R is an endogenous inhibitory ligand of DP IV and may modulate T cell activation via DP IV/CD26 inhibition.     

Applications of dipeptidyl peptidase IV inhibitors in diabetes mellitus

A number of alternative therapies for type 2 diabetes are currently under development that take advantage of the actions of the incretin hormones glucagon-like peptide-1 and glucose-dependent insulinotropic polypeptide on the pancreatic beta-cell. One such approach is based on the inhibition of dipeptidyl peptidase IV (DP IV), the major enzyme responsible for degrading the incretins in vivo. DP IV exhibits characteristics that have allowed the development of specific inhibitors with proven efficacy in improving glucose tolerance in animal models of diabetes and type 2 human diabetics. While enhancement of insulin secretion, resulting from blockade of incretin degradation, has been proposed to be the major mode of inhibitor action, there is also evidence that inhibition of gastric emptying, reduction in glucagon secretion and important effects on beta-cell differentiation, mitogenesis and survival, by the incretins and other DP IV-sensitive peptides, can potentially preserve beta-cell mass, and improve insulin secretory function and glucose handling in diabetics.     

Transcellular proteolysis demonstrated by novel cell surface-associated substrates of dipeptidyl peptidase IV (CD26)

Proteolytic enzymes contribute to the regulation of cellular functions such as cell proliferation and death, cytokine production, and matrix remodeling. Dipeptidyl peptidase IV (DP IV) catalyzes the cleavage of several cytokines and thereby contributes to the regulation of cytokine production and the proliferation of immune cells. Here we show for the first time that cell surface-bound DP IV catalyzes the cleavage of specific substrates that are associated with the cellular surface of neighboring cells. Rhodamine 110 (R110), a highly fluorescent xanthene dye, was used to synthesize dipeptidyl peptidase IV (DP IV/CD26) substrates Gly(Ala)-Pro-R110-R, thus facilitating a stable binding of the fluorescent moiety on the cell surface. The fixation resulted from the interaction with the reactive anchor rhodamine and allowed the quantification of cellular DP IV activity on single cells. The reactivity, length, and hydrophobicity of rhodamine was characterized as the decisive factor that facilitated the determination of cellular DP IV activity. Using fluorescence microscopy, it was possible to differentiate between different DP IV activities. The hydrolysis of cell-bound substrates Xaa-Pro-R110-R by DP IV of neighboring cells and by soluble DP IV was shown using flow cytometry. These data demonstrate that ectopeptidases such as DP IV may be involved in communication between blood cells via proteolysis of cell-associated substrates.     

The role of dipeptidyl peptidase IV (DP IV) enzymatic activity in T cell activation and autoimmunity

Activated T lymphocytes express high levels of dipeptidyl peptidase IV (DP IV)/CD26. Recent studies support the notion that DP IV may play an important role in the regulation of differentiation and growth of T lymphocytes. This article gives a short overview on DP IV/CD26 expression and effects on immune cells in vitro and in vivo. A major focus of this review are clinical aspects of the function of CD26 on hematopoietic cells and the potential usage of synthetic DP IV inhibitors as therapeutics in inflammatory disorders.     

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.     

Dipeptidyl peptidase IV in the immune system. Cytofluorometric evidence for induction of the enzyme on activated T lymphocytes.

Dipeptidyl peptidase IV (DP IV) is a membrane peptidase with essential functional significance in thymus derived lymphocytes. This conclusion is drawn from 1) the induction of this enzyme after stimulation of T lymphocytes in vitro and 2) the impairment of T cell functions in presence of active site-specific inhibitors of the enzyme. The first item will be addressed in this paper, whereas the second one will be treated in a forthcoming article. Using flow cytofluorometry we investigated the expression of dipeptidyl peptidase IV on activated lymphocytes and the phenotype of lymphocytes expressing this enzyme. After stimulation by mitogenic lectins the number of epitopes on the cell surface binding polyclonal antibodies against DP IV increases 4 to 6 times. By means of double fluorescence staining the enzyme has been shown to be restricted nearly exclusively to T lymphocytes even after mitogenic stimulation. The highest density of DP IV epitopes has been found in cells coexpressing activation markers like receptors for interleukin 2 or transferrin in a high density.     

Amino-terminal truncation of procalcitonin, a marker for systemic bacterial infections, by dipeptidyl peptidase IV (DP IV)

Increased concentrations of procalcitonin (PCT) are found in the plasma of patients with thermal injury and in patients with sepsis and severe infection, making this molecule important as a diagnostic and prognostic marker in these diseases. Interestingly, only the truncated form of PCT, PCT(3-116), is present in the plasma of these patients. The enzyme responsible for this truncation is unknown as yet. Here, using capillary zone electrophoresis, mass spectrometry and Edman sequence analysis, we demonstrate that dipeptidyl peptidase IV (DP IV, EC 3.4.14.5) is capable of catalyzing the hydrolysis of PCT(1-116), releasing the N-terminal dipeptide Ala-Pro. We hypothesize that PCT(3-116) is the result of the hydrolysis of PCT(1-116) by soluble DP IV of the blood plasma or by DP IV expressed on the surface of cells.     

Reactions between dipeptidyl peptidase IV and diacyl hydroxylamines: mechanistic investigations

Kinetics of inactivation of dipeptidyl peptidase IV (DP IV, EC 3.4.14.5) by N-peptidyl-O-(4-nitrobenzoyl) hydroxylamines and their enzyme-catalyzed hydrolysis were followed using independent monitoring methods, all giving similar efficiency ratios of Kcat/Kinact. Different temperature dependences of the DP IV-inactivation and enzyme-catalyzed hydrolysis provide evidence of independent rate determining steps for both reactions. Activation parameters of inactivation are similar to those of spontaneous decomposition of the compounds, suggesting a mechanistic relationship. Investigation of DP IV-inactivation, DP IV-catalyzed hydrolysis of N-Ala-Pro-O-Bz(4-NO2) and the decomposition of the suicide substrate in H2O and D2O gave solvent isotope effects of 4.65, 2.54 and 1.02, respectively. A proton inventory of the inactivation reaction indicates involvement of more than one proton in the formation or breakdown of its transition state. The linear proton inventory found for the hydrolytic reaction is consistent with one proton transition in the rate determining step and resembles the rate limiting deacylation of Ala-Pro-DP IV. The hypothetical reaction model now locates splitting in both reactions prior to formation of a covalent intermediate during the catalytic cycle.     

Targeting dipeptidyl peptidase IV (CD26) suppresses autoimmune encephalomyelitis and up-regulates TGF-beta 1 secretion in vivo

CD26 or dipeptidyl peptidase IV (DP IV) is expressed on various cell types, including T cells. Although T cells can receive activating signals via CD26, the physiological role of CD26/DP IV is largely unknown. We used the reversible DP IV inhibitor Lys[Z(NO(2))]-pyrrolidide (I40) to dissect the role of DP IV in experimental autoimmune encephalomyelitis (EAE) and to explore the therapeutic potential of DP IV inhibition for autoimmunity. I40 administration in vivo decreased and delayed clinical and neuropathological signs of adoptive transfer EAE. I40 blocked DP IV activity in vivo and increased the secretion of the immunosuppressive cytokine TGF-beta1 in spinal cord tissue and plasma during acute EAE. In vitro, while suppressing autoreactive T cell proliferation and TNF-alpha production, I40 consistently up-regulated TGF-beta1 secretion. A neutralizing anti-TGF-beta1 Ab blocked the inhibitory effect of I40 on T cell proliferation to myelin Ag. DP IV inhibition in vivo was not generally immunosuppressive, neither eliminating encephalitogenic T cells nor inhibiting T cell priming. These data suggest that DP IV inhibition represents a novel and specific therapeutic approach protecting from autoimmune disease by a mechanism that includes an active TGF-beta1-mediated antiinflammatory effect at the site of pathology.     

Dipeptidylpeptidase IV--inactivation with N-peptidyl-O-aroyl hydroxylamines

Eleven N-peptidyl-O-aroyl hydroxylamines have been synthesized and their hydrolytic stability, acidity and properties during reaction with dipeptidyl peptidase IV (E.C. 3.4.14.5) investigated. N-peptidyl-O-(4-nitrobenzoyl) hydroxylamines act as irreversible inhibitors of serine proteases. The serine enzyme, dipeptidyl peptidase IV (DP IV), is inactivated by substrate analog derivatives of this class by a suicide inactivation mechanism. During the enzyme reaction of DP IV with the suicide substrates most molecules are hydrolyzed but some irreversibly inactivate the target enzyme. In contrast to porcine pancreatic elastase and thermitase, DP IV exhibits a high ratio for hydrolysis of the compounds versus inhibition during their interaction with the enzyme. Variation of the leaving aroyl residue lowers this ratio. Variation of the substrate analog peptide moieties of the DP IV-inhibitors increases their ability to inhibit the enzyme to a remarkable extent. Possible reaction pathways are discussed.     

Metformin effects on dipeptidylpeptidase IV degradation of glucagon-like peptide-1

There is current interest in the use of inhibitors of dipeptidyl peptidase IV (DP IV) as therapeutic agents to normalize glycemic excursions in type 2 diabetic patients. Data indicating that metformin increases the circulating amount of active glucagon-like peptide-1 (GLP-1) in obese nondiabetic subjects have recently been presented, and it was proposed that metformin might act as a DP IV inhibitor. This possibility has been investigated directly using a number of in vitro methods. Studies were performed on DP IV enzyme from three sources: 20% human serum, purified porcine kidney DP IV, and recombinant human DP IV. Inhibition of DP IV hydrolysis of the substrate Gly-Pro-pNA by metformin was examined spectrophotometrically. Effects of metformin on GLP-1([7-36NH2]) degradation were assessed by mass spectrometry. In addition, surface plasmon resonance was used to establish whether or not metformin had any effect on GLP-1([7-36NH2]) or GLP-1([9-36NH2]) interaction with immobilized porcine or human DP IV. Metformin failed to alter the kinetics of Gly-Pro-pNA hydrolysis or GLP-1 degradation tested according to established methods. Surface plasmon resonance recordings indicated that both GLP-1([7-36NH2]) and GLP-1([9-36NH2]) show micromolar affinity (K(D)) for DP IV, but neither interaction was influenced by metformin. The results conclusively indicate that metformin does not act directly on DP IV, therefore alternative explanations for the purported effect of metformin on circulating active GLP-1 concentrations must be considered.     

Inhibition of the activation and catalytic activity of insulin receptor kinase by zinc and other divalent metal ions

The autophosphorylation reaction responsible for conversion of insulin receptor (from human placenta) to an active tyrosyl-protein kinase was shown to be inhibited by Zn2+ and other divalent metal ions. The order of inhibitory potency was found to be Cu2+ greater than Zn2+, Cd2+ greater than Co2+, Ni2+. Autophosphorylation of insulin receptor was almost completely blocked by 10 microM Zn2+. Zn2+, however, did not appear to affect the binding of insulin to its receptor. Histidine, a chelator of Zn2+, protected against the inhibitory effects of Zn2+. The failure of histidine to regenerate the competence of the Zn2+-inhibited receptor to undergo autophosphorylation suggested that the inhibition by Zn2+ was irreversible. In addition to inhibiting autophosphorylation, Zn2+ inhibited the tyrosyl-protein kinase activity of highly purified phosphorylated receptor. Zn2+ was also observed to inhibit phosphotyrosyl-protein phosphatase activity present in preparations of partially purified insulin receptor. These inhibitory effects of Zn2+ should be considered in the design of protocols for the isolation and handling of insulin receptor and possibly other tyrosine kinases. Additionally, the possible physiological significance of the inhibition of insulin receptor kinase by Zn2+ is discussed in light of the fact that Zn2+ is accumulated in and secreted from pancreatic islet cells together with insulin.     

Metabolism of glucagon by dipeptidyl peptidase IV (CD26)

Glucagon is a 29-amino acid polypeptide released from pancreatic islet alpha-cells that acts to maintain euglycemia by stimulating hepatic glycogenolysis and gluconeogenesis. Despite its importance, there remains controversy about the mechanisms responsible for glucagon clearance in the body. In the current study, enzymatic metabolism of glucagon was assessed using sensitive mass spectrometric techniques to identify the molecular products. Incubation of glucagon with purified porcine dipeptidyl peptidase IV (DP IV) yielded sequential production of glucagon(3-29) and glucagon(5-29). In human serum, degradation to glucagon(3-29) was rapidly followed by N-terminal cyclization of glucagon, preventing further DP IV-mediated hydrolysis. Bioassay of glucagon, following incubation with purified DP IV or normal rat serum demonstrated a significant loss of hyperglycemic activity, while a similar incubation in DP IV-deficient rat serum did not show any loss of glucagon bioactivity. Degradation, monitored by mass spectrometry and bioassay, was blocked by the specific DP IV inhibitor, isoleucyl thiazolidine. These results identify DP IV as a primary enzyme involved in the degradation and inactivation of glucagon. These findings have important implications for the determination of glucagon levels in human plasma.     

Enzyme inhibition,radical scavenging,and spectroscopic studies of vanadium(IV)–hydrazide complexes

Spectroscopic, enzyme-inhibition, and free-radical scavenging properties of a series of hydrazide ligands and their vanadium(IV) complexes have been investigated. Analytical and spectral data indicate the presence of a dimeric unit with two oxovanadium(IV) ions (VO²⁺) coordinated with two hydrazide ligands along with two water molecules. All complexes are stable in the solid state, but exhibit varying degrees of stability in solution. Binding of the coordinating solvent such as DMSO is indicated at the 6th position of vanadium in the dimeric unit followed by conversion to a monomeric intermediate species, [VOL(DMSO)3]1+ (L = hydrazide ligand). The free hydrazide ligands are inactive against snake venom phosphodiesterase I (SVPD), whereas oxovanadium(IV) complexes of these ligands show varying degrees of inhibition and are found to be non-competitive inhibitors. The superoxide and nitric oxide radical scavenging properties have been determined. Hydrazide ligands are inactive against these free radicals, whereas their V(IV) complexes show varying degrees of inhibition. Structure–activity relationship studies indicate that the electronic and/or steric factors that change the geometry of the complexes play an important role in their inhibitory potential against SVPD and free radicals.     

Determination of the Solution Conformation of HIV-1 Tat(1–9) Peptides by Means of Molecular Dynamics Simulations Considering NMR Data and Docking Studies into an Active Site Model of DP IV

The human immunodeficiency virus 1 Tat protein suppresses antigen-, anti-CD3-and mitogen-induced activation of human T cells when added to T cell cultures. This activity is important for the development of AIDS because lymphocytes from HIV-infected individuals exhibit a similar antigen-specific dysfunction. Moreover, Tat was found to interact with dipeptidyl peptidase IV (DP IV). To find out the amino acid sequence important for the inhibition of the DP IV enzymatic activity we investigated N-terminal Tat(1–9) peptide analogues with amino acid substitutions in different positions. Interestingly, the exchange of Pro⁶ with Leu and Asp⁵ with Ile strongly diminished the DP IV inhibition by Tat(1–9). Based on data derived from one-and two-dimensional ¹H NMR investigations the solution conformations of the three nonapeptides in water were determined by means of molecular dynamics simulations. These conformations were used for studies of the docking behavior of the peptides into a model of the active site of DP IV. The results suggest that several attractive interactions between the native Tat(1–9) and DP IV lead to a stable complex and that the reduced affinity of both L⁶-Tat(1–9) and I⁵-Tat(1–9) derivatives might be caused by conformational alterations in comparison to the parent peptide.Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s0089480040200     

New Antidiabetic Targets of α-Glucosidase Inhibitory Peptides,SVPA, SEPA,STYV and STY: Inhibitory Effects on Dipeptidyl Peptidase-IV and Lipid Accumulation in 3T3-L1 Differentiated Adipocytes with Scavenging Activities Against Methylglyoxal and Reactive Oxygen Species

Type 2 diabetes mellitus (T2DM) is a multifactorial disease that requires multiple therapeutic strategies for its management. Bioactive peptides with multiple anti-diabetic targets are attractive therapeutic molecules. The present study was conducted to identify additional anti-diabetic targets of α-glucosidase inhibitory peptides, SVPA, SEPA, STYV, and STY. The α-glucosidase inhibitory activity of the peptides was in the order STYV?>?STY?>?SEPA?>?SVPA while molecular docking against human dipeptidyl peptidase IV (DPP-IV) showed that SVPA had the best binding affinity. In contrast, in vitro studies indicated that SEPA had a significantly higher (P?<?0.05) DPP-IV inhibitory activity (IC₅₀?=?5.78?±?0.19 mM) than other peptides. SVPA and SEPA showed mixed inhibition pattern while STYV and STY were uncompetitive inhibitors of the enzyme. IPI (diprotin A), STYV and STY were not cytotoxic while SEPA displayed some cytotoxicity. In differentiated 3T3-L1 adipocytes, SVPA and STYV were found to induce a significant (P?<?0.05) decrease in intracytoplasmic lipid accumulation when added during the differentiation process while STY, GSH and IPI caused significant reduction (P?<?0.05) in the lipid accumulation when added after the differentiation. The SVPA, SEPA and STYV were better scavengers of methylglyoxal than STY but STYV had the best scavenging activities toward reactive oxygen species and nitric oxide. It was concluded that the four α-glucosidase inhibitory peptides including IPI have multiple targets against type T2DM but, overall, of the four peptides evaluated, STYV tends to have better potential for application as a multifunctional anti-diabetic peptide.