ATP-insulin conjugates and their use for immunofactor analysis

A method resulting in ATP-insulin conjugates by covalent binding of ATP modified at C(6) amino group of the adenine residue with insulin was developed. The modified ATP was bound to insulin by means of metha-p-toluene sulfonate-N-cyclohezyl Nf [2-morpholinyl(4)ethyl]-carbodiimide. The ATP analogs and ATP-insulin conjugates possess the coenzyme activity in a reaction of luciferin oxidation by luciferase from the fireflies Luciola mingrelica. the catalytic properties of soluble and immobilize on CNBR-activated. Sepharose enzymes in reactions with native ATR, its modified derivatives and ATP--insulin conjugates were compared. The bioluminescence reaction involving ATP--insulin conjugate is inhibited by antibodies against insulin. This effect can form a basis for insulin detection in solution, which is based on competitive binding of free and antibody-labelled ATP--insulin conjugates.     

Photoreactive insulin derivatives for the detection of the doubly labeled insulin receptor

Two different photoinsulins, the radioactive N(epsilonB29)-(4-azidosalicyloyl) insulin and the novel biotinylated N(epsilonB29)-(4-azidotetrafluorobenzoyl-biocytinyl) insulin, were synthesized in order to study the binding stoichiometry of insulin and the insulin receptor in a direct approach. Both derivatives were cross-linked simultaneously to the (alphabeta)(2) receptor. Insulin-receptor conjugates were formed that carry a radioactive label as well as a biotin label. The doubly labeled complexes were isolated by streptavidin-affinity chromatography. Analysis of both markers, the radioactive (125)I marker and the biotin marker, proved the existence of a covalent complex of one receptor molecule and two ligands. Thus, orthogonal photocross-linking is introduced as a method for the isolation and analysis of bivalent receptor complexes.     

Synthesis and evaluation of insulin-human serum albumin conjugates

A series of human insulin maleimido derivatives with short and long linkers was synthesized by exploiting the variations in the pK(a) values and environment of the three amino groups present in the protein. The syntheses were accomplished in organic solvent because of maleimide's instability in basic aqueous media. The derivatives thus obtained were conjugated to the free thiol on Cys34 of human serum albumin (HSA) and purified. A structure-activity relationship based on in vitro receptor binding and activation results for this series of insulin-HSA conjugates showed that the best compounds were attached at the B1 position of insulin with either short or long linkers. Two conjugates were administered subcutaneously to streptozotocin-induced diabetic rats and found to possess blood glucose normalizing activity up to 8 h post-administration. The return to diabetic plasma glucose levels was not observed within the time frame of the experiment (48 h). In comparison, the insulin-treated group's normalization activity lasted 2 h and returned to a diabetic level at 8 h. The onset of the conjugate activities were delayed by 1 h when compared to the activity of human insulin. The study results led to the identification of CJC-1575 as a potent and long lasting human insulin analogue.     

Effects of deoxycorticosterone acetate on glucose metabolism in nondiabetic and streptozotocin-diabetic rats.

A previous study in our laboratory showed that streptozotocin (STZ) induced diabetic, deoxycorticosterone acetate (DOCA) induced hypertensive rats exhibited significantly lower levels of plasma glucose than did normotensive diabetic animals. The present experiments further investigate the effects of DOCA treatment on fasting levels of plasma glucose and insulin and on their changes after oral glucose challenge in nondiabetic and STZ-diabetic rats. It was found that, in nondiabetic rats, DOCA-induced hypertension was associated with normal glucose levels and glucose tolerance but with significantly lower levels of plasma insulin. DOCA-treated diabetic animals showed significantly lower levels of plasma glucose, but their plasma insulin concentrations were not significantly different from those of the DOCA vehicle treated diabetic rats. DOCA-treated diabetic rats also had significantly higher plasma levels of cholesterol and triglycerides. It is suggested that DOCA may have a direct or indirect action on the assimilation, production, or utilization of glucose, perhaps leading to an improvement in insulin sensitivity and subsequently a decrease in insulin secretion.     

Perturbation of insulin-receptor interactions by intramolecular hormone cross-linking. Analysis of relative movement among residues A1, B1, and B29

We have evaluated, by use of isolated canine hepatocytes, the importance of intramolecular hormone cross-linking (and of concomitant changes in molecular flexibility) to the interaction of insulin with its plasma membrane receptor. Cross-linked hormone analogs were prepared by reacting porcine insulin, N alpha A1-t-butyloxycarbonyl insulin or N alpha A1-t-butyloxycarbonyl [D-LysA1]insulin with various dicarboxylic acid active esters to obtain alpha-GlyA1/epsilon-LysB29-, alpha-PheB1/epsilon-LysB29-, and epsilon-D-LysA1/epsilon-LysB29-cross-linked insulins, respectively. In the aggregate, insulin analogs cross-linked by groups containing 2-12 atoms retained 1.4-35% of the receptor binding potency of native insulin. Analysis of our results suggests that: (a) loss of chemical functionality, steric interference, and restriction of potential intramolecular movement can all play roles in determining the receptor binding potencies of cross-linked insulin analogs; (b) restriction of intramolecular movement between residues A1 and B29 affects negatively the binding of insulin to its receptor (but accounts for only a fraction of the conformational change which insulin must undergo to achieve a high affinity state of ligand-receptor interaction); and (c) introduction of a cross-link between residues B1 and B29 (residues that are in fact in proximity in one crystalline form of the hormone) decreases markedly the receptor binding potencies of the corresponding analogs. The importance of these findings is discussed in relation to the potential structure of insulin when it is bound to its plasma membrane receptor.     

Preparation and properties of alpha- and epsilon-amino-protected porcine relaxin derivatives

The chemical modification of the amino groups of B29 porcine relaxin resulted in pure derivatives of N alpha A1-citraconyl-B29 relaxin, N epsilon A7, N epsilon A16, N epsilon B8-tris [[[(methylsulfonyl)ethyl]oxy]carbonyl]-B29 relaxin (Msc3-relaxin), and N alpha A1, N epsilon A7, N epsilon A16, N epsilon B8-tetrakis [[[(methylsulfonyl)ethyl]oxy]carbonyl]-B29 relaxin (Msc4-relaxin). N alpha A1-Citraconyl-B29 relaxin was obtained after selective deprotection of fully acylated B29 relaxin derivatives. The quantitative reaction of N alpha A1-citraconylrelaxin with [[(methylsulfonyl)ethyl]-oxy]carbonyl succinimide ester followed by deprotection of the citraconyl group resulted in N epsilon A7, N epsilon A16, N epsilon B8-Msc3-B29 relaxin, the starting material for selective chemical modifications at the N terminus of the relaxin A chain. In mouse interpubic ligament assay both Msc3 and Msc4 derivatives of relaxin showed a bioactivity of 30%, while in the case of N alpha A1-citraconyl-B29 relaxin the bioactivity was reduced to 15%. When compared with unmodified relaxin, only the circular dichroic spectrum of N alpha A1-citraconyl-B29 relaxin revealed significant differences. Therefore, the loss in bioactivity of the N alpha A1-citraconyl-B29 relaxin seems to be related to the structural changes caused by the introduction of a negative charge at the N terminus of the A chain.     

N epsilonB29-(+)-biotinylinsulin and its complexes with avidin. Synthesis and biological activity

Insulin was modified with d-biotin-N-hydroxysuccinimide ester in dimethylformamide. Mono-, di-, and triacylated insulins were separated by preparative isoelectric focusing. Monoacylated derivatives (isoelectric point 5.1) were fractionated twice on DEAE-cellulose to yield pure N epsilonB29-biotinylinsulin. The structure of the product was established by amino acid analysis before and after deamination. N epsilonB29-biotinylinsulin had biological activity indistinguishable from insulin on glucose oxidation and lipid synthesis assays using isolated rat epididymal fat cells. Complexes of N epsilonB29-biotinylinsulin with avidin, having essentially all but one binding site filled with biotin, were prepared in order to obtain a 1:1 insulin:avidin ration. The elicited identical maximal biological responses, but showed a potency decreased to 5% of that of insulin. Such complexes conjugated with ferritin will provide a useful tool in the development of electron microscopic stains of insulin receptors.     

Preparation and characterization of two LysB29 specifically labelled fluorescent derivatives of human insulin.

The preparation and characterization of two novel LysB29 selectively labelled fluorescent derivatives of human insulin are described. Two probes were chosen: 4-chloro-7-nitrobenz-2-oxa-1,3-diazole (NBD) and 7-methoxycoumarin-4-acetic acid (MCA), which have a relatively small, compact structure and are able to react with amino groups to form highly fluorescent derivatives. The combination of solid phase peptide synthesis and enzymatic semisynthesis was chosen for preparation of these fluorescent derivatives. Using two different protocols of solid-phase peptide synthesis, two fluorescent octapeptides were prepared corresponding to the position B23-B30 of human insulin, each with a different fluorescent label, NBD or MCA, on the epsilon-amino group of lysine. Then, the fluorescent octapeptides were coupled to desoctapeptide-(B23-B30)-insulin by a trypsin catalysed reaction. The receptor binding affinities of two novel fluorescent derivatives of human insulin with NBD and MCA (HI-NBD and HI-MCA) were determined on rat adipose tissue plasma membranes. Both fluorescent insulins, HI-NBD and HI-MCA, had only slightly reduced binding affinity and will be used for studying the interaction of insulin with its receptor.     

Synthesis and characterization of poly(ethylene glycol)-insulin conjugates

Human insulin was modified by covalent attachment of short-chain (750 and 2000 Da) methoxypoly (ethylene glycol) (mPEG) to the amino groups of either residue PheB1 or LysB29, resulting in four distinct conjugates: mPEG(750)-PheB1-insulin, mPEG(2000)-PheB1-insulin, mPEG(750)-LysB29-insulin, and mPEG(2000)-LysB29-insulin. Characterization of the conjugates by MALDI-TOF mass spectrometry and N-terminal protein sequence analyses verified that only a single polymer chain (750 or 2000 Da) was attached to the selected residue of interest (PheB1 or LysB29). Equilibrium sedimentation experiments were performed using analytical ultracentrifugation to quantitatively determine the association state(s) of insulin derivatives. In the concentration range studied, all four of the conjugates and Zn-free insulin exist as stable dimers while Zn(2+)-insulin was exclusively hexameric and Lispro was monomeric. In addition, insulin (conjugate) self-association was evaluated by circular dichroism in the near-ultraviolet wavelength range (320-250 nm). This independent method qualitatively suggests that mPEG-insulin conjugates behave similarly to Zn-free insulin in the concentration range studied and complements results from ultracentrifugation studies. The physical stability/resistance to fibrillation of mPEG-insulin conjugates in aqueous solution were assessed. The data proves that mPEG(750 and 2000)-PheB1-insulin conjugates are substantially more stable than controls but the mPEG(750 and 2000)-LysB29-insulin conjugates were only slightly more stable than commercially available preparations. Circular dichroism studies done in the far ultraviolet region confirm insulin's tertiary structure in aqueous solution is essentially conserved after mPEG conjugation. In vivo pharmacodynamic assays reveal that there is no loss in biological activity after conjugation of mPEG(750) to either position on the insulin B-chain. However, attachment of mPEG(2000) decreased the bioactivity of the conjugates to about 85% of Lilly's HumulinR formulation. The characterization presented in this paper provides strong testimony to the fact that attachment of mPEG to specific amino acid residues of insulin's B-chain improves the conjugates' physical stability without appreciable perturbations to its tertiary structure, self-association behavior, or in vivo biological activity.     

Immunoenzyme method of sequential saturation for determining antigens using the model of insulin

The method for the determination of insulin by means of the enzyme immunoassay, based on the use of insulin-peroxidase conjugates, has been developed. In this assay the scheme of the successive saturation of the active sites of antibodies is used. The antigenic properties of two conjugates differing in the method of their preparation are compared. The conjugates were obtained by the covalent binding of peroxidase, oxidized in its carbohydrate component, with insulin (conjugate 1) or hexamethylene-diamine-modified insulin (conjugate 2). The conjugates represented a mixture of oligomers differing in their molecular weight. Conjugate 1 possessed higher affinity to antibodies and higher enzymatic activity than conjugate 2. The method for evaluating the quality of antisera to insulin used in the assay has been proposed. The time of the insulin assay is 5-16 hours, the limit of insulin detection is 5 microU/ml, the variation factor is 3-12%.     

Insulin analogues with modifications at position B26. Divergence of binding affinity and biological activity

In this study, we prepared several shortened and full-length insulin analogues with substitutions at position B26. We compared the binding affinities of the analogues for rat adipose membranes with their ability to lower the plasma glucose level in nondiabetic Wistar rats in vivo after subcutaneous administration, and also with their ability to stimulate lipogenesis in vitro. We found that [NMeHisB26]-DTI-NH 2 and [NMeAlaB26]-DTI-NH 2 were very potent insulin analogues with respect to their binding affinities (214 and 465%, respectively, compared to that of human insulin), but they were significantly less potent than human insulin in vivo. Their full-length counterparts, [NMeHisB26]-insulin and [NMeAlaB26]-insulin, were less effective than human insulin with respect to binding affinity (10 and 21%, respectively) and in vivo activity, while [HisB26]-insulin exhibited properties similar to those of human insulin in all of the tests we carried out. The ability of selected analogues to stimulate lipogenesis in adipocytes was correlated with their biological potency in vivo. Taken together, our data suggest that the B26 residue and residues B26-B30 have ambiguous roles in binding affinity and in vivo activity. We hypothesize that our shortened analogues, [NMeHisB26]-DTI-NH 2 and [NMeAlaB26]-DTI-NH 2, have different modes of interaction with the insulin receptor compared with natural insulin and that these different modes of interaction result in a less effective metabolic response of the insulin receptor, despite the high binding potency of these analogues.     

Four new monomeric insulins obtained by alanine scanning the dimer-forming surface of the insulin molecule

The residues A21Asn, B12Val, B16Tyr, B24Phe, B25Phe, B26Tyr and B27Thr, buried in the dimer of insulin, were identified by means of alanine-scanning mutagenesis. The receptor binding activity, in vivo biological potency and self-association properties of the seven single alanine human insulin mutants were determined. Four of the seven single alanine mutants, [B12Ala]human insulin, [B16Ala]human insulin, [B24Ala]human insulin and [B26Ala]human insulin, are monomeric insulin, which indicates that B12Val, B16Tyr, B24Phe and B26Tyr are crucial for the formation of insulin dimer. The monomeric [B16Ala]human insulin and [B26Ala]human insulin retain 27 and 54% receptor binding activity, respectively, and nearly the same in vivo biological potency compared with native insulin, so they could be developed as the fast-acting insulin.     

Biological action and fate of photoaffinity-labelled insulin-receptor complexes

Covalent linking of two photoactivatable insulin derivatives, B2-(2-nitro,4-azidophenylacetyl)-des-PheB1-insulin and B29-(2-nitro,4-azidophenylacetyl)-insulin to viable rat adipocytes gives a system, which contains a fixed stoichiometry between hormone and receptor. The biological signal of prolonged lipogenesis has been used to study several aspects of insulin binding and action: the role of the site of the crosslink between insulin and receptor, recognition of bound photoinsulin by anti-insulin antibodies, the half-life of the biologically active complex, the pH-dependence of the biological signal, and the possible role of internalization. Furthermore, the effect of trypsin on the insulin receptor, as well as the insulin-receptor complex, has been investigated and a refined model of the receptor is presented.     

The relationship between the connecting peptide of recombined single chain insulin and its biological function

To investigate the relationship between the biological activity of recombined single chain insulin and the length of the connecting peptide, we designed and prepared three single chain insulin molecules, namely, PIP, [A]5PIP and [A]10PIP, by site-directed mutagenesis, in which B30 and A1 were linked through dipeptide A-K, heptapeptide A-A-A-A-A-A-K, and dodecapeptide A-A-A-A-A-A-A-A-A-A-A-K, respectively. Their receptor binding capacities were 0.14%, 14.3% and 11.1% of that of insulin respectively and their in vivo biological activities were in consistence with their receptor binding capacity; whereas their growth promoting activities were 17%, 116.3% and 38% of that of insulin. These results suggested the following conclusions. (i) The recombined single chain insulin could also possess the same metabolic and mitogenic function as insulin. (ii) The receptor binding capacity of recombined single chain insulin to insulin receptor was closely related to the length and amino acid composition of the connectin     

Self-organized pullulan/deoxycholic acid nanogels: Physicochemical characterization and anti-cancer drug-releasing behavior

The objective of this study was to develop new self-organized nanogels as a means of drug delivery in patients with cancer. Pullulan (PUL) and deoxycholic acid (DOCA) were conjugated through an ester linkage between the hydroxyl group in PUL and the carboxyl group in DOCA. Three types of PUL/DOCA conjugates were obtained, differing in the number of DOCA substitutions (DS; 5, 8, or 11) per 100 PUL anhydroglucose units. The physicochemical properties of the resulting nanogels were characterized by dynamic light scattering, transmission electron microscopy, and fluorescence spectroscopy. The mean diameter of DS 11 was the smallest (approx. 100 nm), and the size distribution was unimodal. To determine the organizing behavior of these conjugates, we calculated their critical aggregation concentrations (CACs) in a 0.01-M phosphate buffered saline solution. They were 10.5×10⁻⁴ mg/mL, 7.2×10⁻⁴ mg/mL, and 5.6×10⁻⁴ mg/mL for DS 5, 8, and 11, respectively. This indicates that DOCA can serve as a hydrophobic moiety to create self-organized nanogels. To monitor the drug-releasing behavior of these nanogels, we loaded doxorubicin (DOX) onto the conjugates. The DOX-loading efficiency increased with the degree of DOCA substitution. The release rates of DOX from PUL/DOCA nanogels varied inversely with the DS. We concluded that the PUL/DOCA nanogel has some potential for use as an anticancer drug carrier because of its low CAC and satisfactory drug-loading capacity.     

The use of Fmoc-Lys(Pac)-OH and penicillin G acylase in the preparation of novel semisynthetic insulin analogs.

In this paper, we present the detailed synthetic protocol and characterization of Fmoc-Lys(Pac)-OH, its use for the preparation of octapeptides H-Gly-Phe-Tyr-N-MePhe-Thr-Lys(Pac)-Pro-Thr-OH and H-Gly-Phe-Phe-His-Thr-Pro-Lys(Pac)-Thr-OH by solid-phase synthesis, trypsin-catalyzed condensation of these octapeptides with desoctapeptide(B23-B30)-insulin, and penicillin G acylase catalyzed cleavage of phenylacetyl (Pac) group from Nepsilon-amino group of lysine to give novel insulin analogs [TyrB25, N-MePheB26,LysB28,ProB29]-insulin and [HisB26]-insulin. These new analogs display 4 and 78% binding affinity respectively to insulin receptor in rat adipose membranes.     

Insulin receptors are bivalent as demonstrated by photoaffinity labeling.

Insulin receptors in human placental membranes were photoaffinity-labeled with a radioactive human insulin-like growth factor I (hIGF-I) photoprobe N epsilon B28-monoazidobenzoyl 125I-hIGF-I either alone or together with a non-radioactive insulin photoprobe N epsilon B29-monoazidobenzoyl insulin. Precipitation of the solubilized receptors with anti-insulin antibody showed that receptors labeled with the radioactive hIGF-I photoprobe were detected in the immunoprecipitate only when photolabeling was carried out in the presence of the non-radioactive insulin photoprobe. Comparable results were obtained in converse experiments using a radioactive insulin photoprobe N epsilon B29-monoazidobenzoyl 125I-insulin, a non-radioactive hIGF-I photoprobe N epsilon B28-monoazidobenzoyl hIGF-I, and an antibody to hIGF-I. The amount of radioactive receptors precipitated by either the anti-insulin antibody or the anti-hIGHF-I antibody was close to the expected amount. These observations demonstrate that the insulin receptor is bivalent being capable of binding two molecules of ligand.     

一种重组抗胰蛋白酶单体人胰岛素突变体的设计、制备和鉴定

用缺口双链DNA的定向突变方法分别将胰岛素前体中B链第 2 2、2 8、2 9和 3 0位改变为Asp、Lys、Pro和Lys,酵母分泌表达的前体经胰蛋白酶直接酶切 ,得到重组 [B2 2Asp、B2 8Lys、B2 9Pro、B3 0Lys]人胰岛素。它与受体的结合能力约为猪胰岛素的 6% ,而体内生物活力保留 5 0 %。通过FPLC分子筛测定其自身结合能力 ,在生理条件下浓度达 10 -4mol/L时它以单体形式存在。作为可抗胰蛋白酶酶解的单体胰岛素类似物 ,它可能具有一定的应用前景     

Multivalent carbocyanine molecular probes: synthesis and applications

Synergistic multivalent interactions can amplify desired chemical or biological molecular recognitions. We report a new class of multicarboxylate-containing carbocyanine dye constructs for use as optical scaffolds that not only serve as fluorescent antennas but also participate in structural assembly of the multivalent molecular construct. Three generations of carboxylate-terminating multivalent near-infrared carbocyanine probes from a dicarboxylic acid precursor dye (cypate) were prepared via its imino diacetic acid derivatives. Conjugation of the probes with D-(+)-glucosamine afforded dendritic arrays of the carbohydrates on an inner NIR chromophore core. All the multicarboxylate probes and their glucosamine conjugates have similar NIR spectral properties because conjugation occurred at distal positions to the inner chromophore core, thereby providing consistent and predictable spectral properties for their biological applications. Although light-induced photodamage equally affected the precursor dye, multicarboxylate probes, and their glucosamine derivatives, we observed that octacarboxylcypate (multivalent probe) was remarkably stable in different mediums at physiologically relevant temperatures relative to cypate, especially in basic mediums. Biodistribution studies in tumor-bearing nude mice show that all the glucosamine conjugates localized in the tumor but cypate was almost exclusively retained in the liver at 24 h postinjection. The tumor uptake does not correlate with the number of glucosamine tether on the multicarboxylate probe. Overall, the triglucosamine derivative appears to offer the best balance between high tumor uptake and low retention in nontarget tissues. These results suggest that multivalent molecular beacons are useful for assessing the beneficial effects of multivalency and for optimizing the biological and chemical properties of tissue-specific molecular probes.     

Possible involvement of the A20-A21 peptide bond in the expression of the biological activity of insulin. 2. [21-Asparagine diethylamide-A]insulin

We have synthesized [21-asparagine diethylamide-A]insulin, which differs from the parent molecule in that the free carboxyl group of the C-terminal amino acid residue, asparagine, of the A chain moiety has been converted to a diethylamide group. The analogue displays equivalent potency in receptor binding and biological activity, 48% and 56%, respectively, relative to bovine insulin. In contrast, we have reported previously [Burke, G. T., Chanley, J. D., Okada, Y., Cosmatos, A., Ferderigos, N., & Katsoyannis, P. G. (1980) Biochemistry 19, 4547-4556] that [21-asparaginamide-A]insulin exhibits a divergence in these properties, ca. 60% in receptor binding and ca. 13% in biological activity. The disparity in the biological behavior of these analogues is discussed, and we ascribe the modulation of biological activity independent of receptor binding activity observed between these analogues to the difference in the negativity of the carbonyl oxygen of the A chain moiety C-terminal amino acid residue.