A family of insulinomimetic zinc(II) complexes of amino ligands with Zn(Nn) (n=3 and 4) coordination modes.

Several metal ions and their complexes have been known to mimic the action of insulin in in vitro and in vivo systems. We prepared a family of Zn(II) complexes derived from amino ligands with Zn(Nn) (n=3 and 4) coordination modes, the insulinomimetic activity being estimated by an inhibitory effect of free fatty acid release from isolated rat adipocytes treated with epinephrine. In comparison with the positive controls VOSO(4) and ZnSO(4), Zn(II)-amine complexes with stability constants (log beta) lower than 11.5 exhibited higher insulinomimetic activities. Among them, a bis(2-aminomethyl pyridinato)Zn(II) (Zn(2-ampy)(2)(2+)) complex with the highest insulinomimetic activity and a higher stability constant but lower than 11.5 was selected, and subjected to in vivo evaluation in KK-A(y) mice with a genetically type 2 diabetes mellitus. The high blood glucose level of the mice was lowered by daily intraperitoneal injections of Zn(2-ampy)(2)(2+) at a dose of 2 mg Zn/kg body weight for 14 days. Based on the results, Zn(2-ampy)(2)(2+) with Zn(N(4)) coordination mode was proposed to have both a high in vitro insulinomimetic activity and an in vivo blood glucose lowering effect.

In vitro alpha-glucosidase inhibitory effect of Zn(II) complex with 6-methyl-2-picolinmethylamide.

We found alpha-glucosidase inhibitory effect of Zn(II) complex with 6-methyl-2-picolinmethylamide (6mpa-ma) which showed the highest blood glucose lowering effect in Zn(II) complexes with picolinamide derivatives in KK-A(y) mice. The Zn(II) complex showed strong alpha-glucosidase inhibitory activity greater by about eighty times (substrate: maltose) and forty times (substrate: sucrose) compared with acarbose.

A new insulin-mimetic bis(allixinato)zinc(II) complex: structure-activity relationship of zinc(II) complexes.

During the investigation of the development of insulin-mimetic zinc(II) complexes with a blood glucose-lowering effect in experimental diabetic animals, we found a potent bis(maltolato)zinc(II) complex, Zn(ma)(2), exhibiting significant insulin-mimetic effects in a type 2 diabetic animal model. By using this Zn(ma)(2) as the leading compound, we examined the in vitro and in vivo structure-activity relationships of Zn(ma)(2) and its related complexes. The in vitro insulin-mimetic activity of these complexes was determined by the inhibition of free fatty acid release and the enhancement of glucose uptake in isolated rat adipocytes treated with epinephrine. A new Zn(II) complex with allixin isolated from garlic, Zn(alx)(2), exhibited the highest insulin-mimetic activity among the complexes analyzed. The insulin-mimetic activity of the Zn(II) complexes examined strongly correlated (correlation coefficient=0.96) with the partition coefficient (log P) of the ligand, indicating that the activity of Zn(ma)(2)-related complexes depends on the lipophilicity of the ligand. The blood glucose-lowering effects of Zn(alx)(2) and Zn(ma)(2) were then compared, and both complexes were found to normalize hyperglycemia in KK- A(y) mice after a 14-day course of daily intraperitoneal injections. However, Zn(alx)(2) improved glucose tolerance in KK- A(y) mice much more than did Zn(ma)(2), indicating that Zn(alx)(2) possesses greater in vivo anti-diabetic activity than Zn(ma)(2). In addition, Zn(alx)(2) improved leptin resistance and suppressed the progress of obesity in type 2 diabetic KK- A(y) mice. On the basis of these observations, we conclude that the Zn(alx)(2) complex is a novel potent candidate for the treatment of type 2 diabetes mellitus.

The action mechanism of zinc(II) complexes with insulinomimetic activity in rat adipocytes.

Zinc (Zn), an essential trace element, and its complexes have recently been known to exhibit insulinomimetic activities. However, the action mechanism of Zn(II) has yet been obscure. The purpose of the present study was to estimate the action mechanism of the Zn(II) complexes. We found first that Zn given in the chemical forms such as Zn(maltolate)2 and Zn(threoninate)2 complexes is highly uptaken in the isolated rat adipocytes compared with that of Zn(picolinate)2. Then, the action mechanism for the insulinomimetic activities was examined in terms of free fatty acid release from the adipocytes. Four Zn(II) compounds, ZnSO4, Zn(picolinate)2, Zn(maltolate)2, and Zn(threoninate)2, inhibited the free fatty acid release from the adipocytes treated with epinephrine (adrenaline). By using several inhibitors for fatty acids and glucose metabolisms in the adipocytes, the following results were obtained. (1) Zn(picolinic acid)2 complex acts on the insulin receptor and PI3-k, which relate to the glucose uptake, as indicated by the experiments using hydroxy-2-naphthalenylmethyl phosphonic acid tris acetoxy methyl ester (HNMPA-(AM)3) and wortmannin, respectively. (2) ZnSO4, and Zn(maltolate)2 and Zn(threoninate)2 complexes affect a glucose transporter 4 (GLUT 4), which is involved in the glucose uptake as indicated by the results using cytochalasin B. (3) Four Zn(II) compounds affect the activation of the phosphodiesterase as indicated by the experiments using cilostamide. These results indicate that the Zn(II) compounds promote the glucose uptake into the adipocytes by affecting at least three sites in the adipocytes, which in turn normalize the blood glucose levels in the experimental diabetic animals.

Synthesis, structure analysis, solution chemistry, and in vitro insulinomimetic activity of novel oxovanadium(IV) complexes with tripodal ligands containing an imidazole group derived from amino acids.

Structures, chemical properties, and in vitro insulinomimetic activities of new vanadyl [oxovanadium(IV), VO(2+)] complexes with five tripodal ligands containing an imidazole functionality were examined. The ligands, N-(carboxymethyl)- N-(4-imidazolylmethyl)amino acids, contain glycine, ( S)- and ( R)-alanine, and ( S)- and ( R)-leucine residues. The molecular structures of the latter four alanine- and leucine-containing complexes were determined by X-ray analysis. The coordination geometry around each vanadium center was octahedral, where an imino nitrogen occupied the apical site and two carboxylate oxygens, an imidazole nitrogen, and a water molecule coordinated in the equatorial plane. The spectroscopic properties of the complexes were characterized by means of IR, electronic absorption, and CD spectra. Acid dissociation constants (p K(a)) and protonation sites of the ligands were determined by a combination of potentiometric titrations and (1)H NMR spectra. The potentiometric study demonstrated that stability constants (log beta) were not so different among the present complexes (14.0-14.9) and a species of molecular complex with a 1:1 metal:ligand ratio existed predominantly at physiological pH 7.4. EPR parameters indicated that the species at pH 7.4 had an octahedral structure similar to the complex in the solid state. On the other hand, an EPR study in phosphate buffer (pH 7.4) suggested that inorganic phosphate coordinated to the vanadium center instead of the imidazole group in the presence of excess phosphate ion. Cyclic voltammograms in the phosphate buffer showed chemically reversible oxidation waves, whereas irreversible oxidation waves were observed in non-coordinating HEPES buffer. Moreover, the oxidation potential of each complex in phosphate buffer was more positive than that in HEPES buffer. Partition coefficients of the present complexes in a n-octanol/saline system were very low, probably due to hydrophilicity of the imidazole group. The in vitro insulinomimetic activities were estimated on the basis of the ability of the complexes to inhibit epinephrine-stimulated free fatty acid release from isolated rat adipocytes. The achiral glycine-derivative complex exhibited the highest insulinomimetic activity, which was higher than that of VOSO(4) as a positive control. Putting our previous observations together, it was found that the vanadyl complexes with tetradentate amino acid derivatives having no alkyl side chain tend to have high in vitro insulinomimetic activity.

Insulinomimetic zinc(II) complexes with natural products: in vitro evaluation and blood glucose lowering effect in KK-Ay mice with type 2 diabetes mellitus.

In vitro insulinomimetic activities of Zn(II) complexes with three natural products, betaine, L-lactic acid, and D-(-)-quinic acid (qui), were found in rat adipocytes treated with epinephrine in terms of the inhibition of free fatty acid release. Based on the results, the blood glucose lowering effect in KK-A(y) mice with type 2 diabetes mellitus was observed by daily i.p. injections of a monomeric zinc(II) complex, Zn(qui)(2), for 13 d.

Anti-diabetes effect of Zn(II)/carnitine complex by oral administration.

A novel bis(L-carnitinato)Zn(II) complex, Zn(car)(2)Cl(2), was prepared, and its insulinomimetic and antidiabetic activities were examined. The complex showed a tendency to lower the high blood glucose levels of KK-A(y) mice with type 2 diabetes mellitus when given by oral administration at a dose of 20 mg Zn/kg body weight for 16 d. In addition, the complex improved glucose tolerance ability when examined by the oral glucose tolerance test (1 g glucose/kg body weight).

Potential insulinominetic agents of zinc(II) complexes with picolinamide derivatives: preparations of complexes, in vitro and in vivo studies.

Following the finding of in vitro insulinominetic activities of new prepared Zn(II) complexes with amide ligands (2-picolinamide (pa-a) and 6-methyl-2-picolinmethylamide (6mpa-ma)) in isolated rat adipocytes treated with epinephrine in terms of inhibition of free fatty acid release, their blood glucose normalizing effects were observed on daily intraperitoneal injections for 14 d in a type 2 diabetes mellitus model animal, KK-Ay mice. The blood glucose levels of KK-Ay mice were maintained in a normal range during the administration of both complexes. After the administration of each complex for 14 d, the improvement of glucose metabolism was confirmed as judged by the glucose tolerance test.

Development of new insulinomimetic zinc(II) picolinate complexes with a Zn(N2O2) coordination mode: structure characterization, in vitro, and in vivo studies.

Three zinc(II) complexes of picolinic acid and its derivatives with a Zn(N2O2) coordination mode were prepared and evaluated for their insulinomimetic activities by in vitro and in vivo studies. By introducing an electron-donating methyl group into the picolinate ligand (pic), bis(6- or 3-methylpicolinato)zinc(II) complexes [Zn(6-mpa)2 or Zn(3-mpa)2, respectively] were prepared. The Zn(6-mpa)(2) complex was crystallized as a water adduct [Zn(6-mpa)2(H2O)].H2O, in which two carboxylate oxygens and two pyridine nitrogens of 6-mpa and a water oxygen coordinate to a zinc(II) with a trigonal bipyramidal geometry. By in vitro evaluation of the inhibition of free fatty acid (FFA) release from isolated rat adipocytes in the presence of epinephrine, the insulinomimetic activities of Zn(pic)2, Zn(6-mpa)2, and Zn(3-mpa)2 (IC50=0.64 +/- 0.13, 0.31 +/- 0.05, and 0.40 +/- 0.07 mM, respectively) were found to be higher than those of VOSO(4) (IC50=1.00 mM) and ZnSO(4) (IC50=1.58 +/- 0.05 mM) in terms of IC50 value, the 50% inhibition concentrations for the FFA release from the adipocytes. Then, Zn(6-mpa)2, which exhibited the highest in vitro insulinomimetic activity among three complexes examined, was given at a dose of 3.0 mg (45.9 micromol) Zn/kg body weight to KK-A(y) mice with type 2 diabetes mellitus by daily intraperitoneal injections for 14 days and it was found that the hereditary high blood glucose levels were lowered during the administration of the complex. The improvement of diabetes mellitus was confirmed with the oral glucose tolerance test.

Blood glucose lowering and toxicological effects of zinc (II) complexes with maltol, threonine, and picolinic acid.

The blood glucose lowering effects in KK-Ay mice with type 2 diabetes mellitus (DM) receiving daily an intraperitoneal (i.p.) administration of Zn(II) complexes with maltol, L-threonine, and picolinic acid for 14 days were estimated under the same conditions, and dose-dependent blood glucose lowering effects in the dose range of 0.2-3.0 mg Zn/kg body weight were found. Among them, the bis(maltolato)Zn(II) complex exhibited the highest blood sugar lowering effect at the dose of 3.0 mg Zn/kg. The improvement of DM was confirmed with oral glucose tolerance tests as well as blood HbA1c levels after the administration of the three Zn(II) complexes at the dose of 3.0 mg Zn/kg. For the purpose of the clinical trial of the complexes in the future, we examined the toxic effects of these three Zn(II) complexes in regard of the LD50 values and hepatic cytochrome P450 levels. The LD50 values of the three Zn(II) complexes exhibited high values compared with that of ZnCl2. No changes of both CYP1A1 and CYP2E1 levels in the liver of KK-Ay mice treated with the three Zn(II) complexes were observed. The obtained results will be important when the complexes are tried for clinical use.

Metallokinetic study of zinc in the blood of normal rats given insulinomimetic zinc(II) complexes and improvement of diabetes mellitus in type 2 diabetic GK rats by their oral administration.

In order to understand the insulinomimetic activity of zinc(II) complexes, we studied the metallokinetic features of zinc in the blood of normal rats given the zinc complexes, bis(maltolato)zinc(II) (Zn(mal)(2)) and bis(6-methylpicolinato)zinc(II) (Zn(6mpa)(2)) by comparing each of them with an ionic form of zinc chloride (ZnCl(2)). The bioavailability of the zinc(II) complexes following oral administration was enhanced to 1.4-1.5-fold that of ZnCl(2) with respect to zinc level. Based on the results of a metallokinetic analysis and administration method in normal rats, we examined the antidiabetic ability of the zinc(II) complexes in GK rats, a model animal of type 2 diabetes mellitus. High blood glucose levels of GK rats were normalized following intraperitoneal injections and oral administration of the zinc(II) complexes, in which the Zn(6mpa)(2) complex was found to be more effective than Zn(mal)(2). The present results are noteworthy, not only due to their potential relevance for clinical application, but also for the development of new zinc(II) complexes.

Bis(6-ethylpicolinato)oxovanadium(IV) complex with normoglycemic activity in KK-A(y) mice.

A novel bis(6-ethylpicolinato)(H(2)O)oxovanadium(IV) complex (VO(6epa)(2) x (H(2)O)) was prepared and its structure was revealed by X-ray analysis (space group Pc(#7), a=10.838(2), b=11.148(5), c=16.642(3) A, and Z=2). Because VO(6epa)(2) x (H(2)O) exhibited higher in vitro insulinomimetic activity compared to that of vanadyl sulfate in terms of inhibition of free fatty acid (FFA) release from isolated rat adipocytes in the presence of epinephrine, its in vivo effect on whether the complex has a blood glucose normalizing effect was examined in KK-A(y) mice, a model animal of type 2 diabetes mellitus. VO(6epa)(2) x (H(2)O) was found to normalize the high blood glucose levels of KK-A(y) mice when given intraperitoneally at doses of 49 micromol/kg body weight for the first 4 days and then 39 micromol/kg body weight for 10 days. In addition, VO(6epa)(2) x (H(2)O) improved glucose tolerance ability as examined by the oral glucose test and seemed to have little toxicity in terms of serum parameters. VO(6epa)(2) x (H(2)O) showed higher normoglycemic activity than bis(6-methylpicolinato)oxovanadium(IV) (VO(6mpa)(2)) at the same dose. These results indicated that greater enhancement of the blood glucose normalizing effect in KK-A(y) mice by ethyl substitution compared to methyl substitution may be due to its being more strongly lipophilic.