Automated radiosynthesis of [18F]FBEM, a sulfhydryl site specific labeling agent for peptides and proteins.

In the process of developing [18F]FBEM coupled target peptide, we have instituted a robust automated synthesis of [18F]FBEM, a sulfhydryl (-SH) site specific agent for radiolabeling of peptides and proteins. The radiosynthesis generated 1.67-3.89 GBq (45.1-105.1 mCi, 7.5-18.8% non-decay corrected yield) of [18F]FBEM from 22.2 GBq (600 mCi) of starting [18F]fluoride with molar activity of 31.8 ±â€¯5.3 GBq/µmol (0.86 ±â€¯0.14 mCi/nmol) (n = 3) at the end of synthesis. Radiochemical purity was greater than 98%, and total synthesis time was ~90 min.

Novel fatty acid chain modified GLP-1 derivatives with prolonged in vivo glucose-lowering ability and balanced glucoregulatory activity.

Glucagon-like peptide-1 is a potent hypoglycemic hormone with beneficial properties for the treatment of diabetes. However, its half-life is short because the rapid metabolic degradation. This study aims to prolong the half-life of glucagon-like peptide-1 through conjugation with the fatty acid side chain which helps the conjugates to interact with the albumin. Firstly, we chose two optimized polypeptide chains which have tremendous hypoglycemic effect named Cys17-Gly8-GLP-1(7-36)-NH2 and Cys37-Gly8-GLP-1(7-37)-NH2, and various fatty acid chains were modified. All conjugates preserved relatively strong GLP-1R activation and I-6 behaved best in glucose-lowering ability. The prolonged antidiabetic effects of I-6 were further confirmed by hypoglycemic efficacy test in vivo. Meanwhile, once daily injection of I-6 to diabetic mice achieved long-term beneficial effects on glucose tolerance, body weight and blood chemistry. It is concluded that I-6 is a promising agent for further investigation of its potential to treat obese patients with diabetes.

Bioactivity of a modified human Glucagon-like peptide-1.

Diabetes has become the third largest cause of death in humans worldwide. Therefore, effective treatment for this disease remains a critical issue. Glucagon-like peptide-1 (GLP-1) plays an important role in glucose homeostasis, and therefore represents a promising candidate to use for the treatment of diabetes. Native GLP-1, however, is quickly degraded in in the circulatory system; which limits its clinical application. In the present study, a chemically-synthesized, modified analogue of human GLP-1 (mGLP-1) was designed. Our analyses indicated that, relative to native GLP-1, mGLP-1 is more resistant to trypsin and pancreatin degradation. mGLP-1 promotes mouse pancreatic ß-cell proliferation by up-regulating the expression level of cyclin E, CDK2, Bcl-2 and down-regulating Bax, p21, and stimulates insulin secretion. An oral glucose tolerance test indicated that mGLP-1 significantly improved glucose tolerance in mice. Intraperitoneal injections of mGLP-1 into streptozotocin (STZ)-induced type 2 diabetic mice significantly reduced blood sugar levels and stimulated insulin secretion. Oral gavages of mGLP-1 in diabetic mice did not result in significant hypoglycemic activity.

Rational design of α-helix-stabilized exendin-4 analogues.

Exendin-4 (Ex4) is a potent glucagon-like peptide-1 receptor agonist, a drug regulating the plasma glucose level of patients suffering from type 2 diabetes. The molecule's poor solubility and its readiness to form aggregates increase the likelihood of unwanted side effects. Therefore, we designed Ex4 analogues with improved structural characteristics and better water solubility. Rational design was started from the parent 20-amino acid, well-folded Trp cage (TC) miniprotein and involved the step-by-step N-terminal elongation of the TC head, resulting in the 39-amino acid Ex4 analogue, E19. Helical propensity coupled to tertiary structure compactness was monitored and quantitatively analyzed by electronic circular dichroism and nuclear magnetic resonance (NMR) spectroscopy for the 14 peptides of different lengths. Both (15)N relaxation- and diffusion-ordered NMR measurements were established to investigate the inherent mobility and self-association propensity of Ex4 and E19. Our designed E19 molecule has the same tertiary structure as Ex4 but is more helical than Ex4 under all studied conditions; it is less prone to oligomerization and has preserved biological activity. These conditions make E19 a perfect lead compound for further drug discovery. We believe that this structural study improves our understanding of the relationship between local molecular features and global physicochemical properties such as water solubility and could help in the development of more potent Ex4 analogues with improved pharmacokinetic properties.

The C-terminal extension of exendin-4 provides additional metabolic stability when added to GLP-1, while there is minimal effect of truncating exendin-4 in anaesthetized pigs.

The most striking sequence difference between glucagon-like peptide-1 (GLP-1)(2) and the longer-acting GLP-1 receptor agonist, exendin-4 (Ex-4),(3) is the nine-amino acid COOH-terminal extension of Ex-4. We investigated the contribution of this extension to the survival time of Ex-4. We assessed the overall metabolism of GLP-1, Ex-4, a COOH-terminally extended GLP-1 peptide (GLP-1+Ex(31-39); GLP-Ex),(4) and a COOH-terminally truncated exendin peptide (Ex(1-30)) in anaesthetized, catheterized pigs, with focus on the extraction across the kidneys and a peripheral tissue (a hindleg, representing muscle, adipose- and connective tissue). Peptide analysis was carried out with assays against the mid-region of the peptides, whereby the role of dipeptidyl peptidase-4 (DPP-4)(5) mediated NH(2)-terminal degradation could be disregarded. The half-life of GLP-1 was significantly increased when the COOH-terminal extension of Ex-4 was added (GLP-1 4.8±3.3min; GLP-Ex 19.5±3.3min). In contrast, there was no effect of truncating Ex-4 (Ex-4 32.4±4.1min; Ex(1-30) 28.4±1.7min). Ex-4 and Ex(1-30) were cleared solely by the kidneys at rates corresponding to the glomerular filtration rate (GFR),(6) while GLP-1 and GLP-Ex were cleared by both the kidneys and peripheral tissues. Both extraction rates were, however, significantly reduced with GLP-Ex compared to GLP-1. The renal clearance rate of GLP-1 greatly exceeded GFR, while GLP-Ex was cleared at a rate resembling GFR. In conclusion, the COOH-terminal extension of Ex-4 contributes minimally to the increased survival time of Ex-4, while addition of this sequence to GLP-1 significantly reduces its clearance.

(Val(8))GLP-1-Glu-PAL: a GLP-1 agonist that improves hippocampal neurogenesis, glucose homeostasis, and ß-cell function in high-fat-fed mice.

This study examined the biological properties of a novel GLP-1 peptide, (Val(8))GLP-1-Glu-PAL, engineered with an Ala(8)→Val(8) substitution and additional incorporation of a C(16) fatty acid moiety at Lys(26) via a glutamic acid linker. GLP-1 underwent 75 % degradation by DPP-IV over 8 h, whereas (Val(8))GLP-1 and (Val(8))GLP-1-Glu-PAL remained intact. All GLP-1 peptides significantly stimulated insulin secretion at 5.6 mM (1.3- to 4.9-fold, p<0.01 to p<0.001) and 16.7 mM glucose (1.5- to 2.3-fold, p<0.001). At higher concentrations (Val(8))GLP-1-Glu-PAL was significantly more potent at stimulating insulin secretion (1.2- to 1.3-fold, p<0.05). In high-fat-fed mice, all GLP-1 peptides significantly lowered plasma glucose concentrations (41-66 % decrease, p<0.05 to p<0.001), with (Val(8))GLP-1-Glu-PAL eliciting protracted glucose-lowering actions (32-59 % decrease, p<0.05 to p<0.01) when administered 8 h prior to a glucose load. Twice-daily administration of (Val(8))GLP-1-Glu-PAL in high-fat-fed mice for 21 days had no effect on bodyweight or food intake, but significantly lowered non-fasting plasma glucose (43-46 % decrease, p<0.05). (Val(8))GLP-1-Glu-PAL markedly decreased glycemic excursion following intraperitoneal glucose (32-48 % decrease, p<0.05), enhanced insulin response to glucose (2- to 2.3-fold, p<0.05 to p<0.01), and improved insulin sensitivity (25-38 % decrease in plasma glucose, p<0.05). O(2) consumption, CO(2) production, RER, and energy expenditure were not altered by (Val(8))GLP-1-Glu-PAL therapy. Treatment with (Val(8))GLP-1-Glu-PAL resulted in a significant increase in BrdU-positive cells (1.3-fold, p<0.05) in the granule cell layer of the dentate gyrus. These data demonstrate that (Val(8))GLP-1-Glu-PAL is a long-acting GLP-1 peptide that significantly improves hippocampal neurogenesis, glucose homeostasis, and insulin secretion in high-fat-fed mice.

Optimization of co-agonism at GLP-1 and glucagon receptors to safely maximize weight reduction in DIO-rodents.

The ratio of GLP-1/glucagon receptor (GLP1R/GCGR) co-agonism that achieves maximal weight loss without evidence of hyperglycemia was determined in diet-induced obese (DIO) mice chronically treated with GLP1R/GCGR co-agonist peptides differing in their relative receptor agonism. Using glucagon-based peptides, a spectrum of receptor selectivity was achieved by a combination of selective incorporation of GLP-1 sequences, C-terminal modification, backbone lactam stapling to stabilize helical structure, and unnatural amino acid substitutions at the N-terminal dipeptide. In addition to α-amino-isobutyric acid (Aib) substitution at position two, we show that α,α'-dimethyl imidazole acetic acid (Dmia) can serve as a potent replacement for the highly conserved histidine at position one. Selective site-specific pegylation was used to further minimize enzymatic degradation and provide uniform, extended in vivo duration of action. Maximal weight loss devoid of any sign of hyperglycemia was achieved with a co-agonist comparably balanced for in vitro potency at murine GLP1R and GCGR. This peptide exhibited superior weight loss and glucose lowering compared to a structurally matched pure GLP1R agonist, and to co-agonists of relatively reduced GCGR tone. Any further enhancement of the relative GCGR agonist potency yielded increased weight loss but at the expense of elevated blood glucose. We conclude that GCGR agonism concomitant with GLP1R agonism constitutes a promising approach to treatment of the metabolic syndrome. However, the relative ratio of GLP1R/GCGR co-agonism needs to be carefully chosen for each species to maximize weight loss efficacy and minimize hyperglycemia.

A novel GLP-1 analog exhibits potent utility in the treatment of type 2 diabetes with an extended half-life and efficient glucose clearance in vivo.

The multiple physiological characterizations of glucagon-like peptide-1 (GLP-1) make it a promising drug candidate for the therapy of type 2 diabetes. However, the half-life of GLP-1 is short in vivo due to degradation by dipeptidyl peptidase-IV (DPP-IV) and renal clearance. Therefore, the stabilization of GLP-1 is critical for its utility in drug development. Based on our previous research, a GLP-1 analog that contained an intra-disulfide bond exhibited a prolonged biological half-life. In this study, we improved upon previous analogs with a novel GLP-1 analog that contained a tryptophan cage-like sequence for an improved binding affinity to the GLP-1 receptor. The binding capacities and the stabilities of GLP715a were investigated, and the physiological functions of the GLP715a were compared to those of the wild-type GLP-1 in animals. The results demonstrated that the new GLP-1 analog (GLP715a) increased its biological half-life to approximately 48h in vivo; GLP715a also exhibited a higher binding affinity to the GLP-1 receptor than the wild-type GLP-1. The increased binding capacity of GLP715a to its receptor resulted in a quick response to glucose administration. The long-acting anti-diabetic property of GLP715a was revealed by its increased glucose tolerance, higher HbA(1c) reduction, more efficient glucose clearance and quicker insulin stimulation upon glucose administration compared to the wild-type GLP-1 in rodents. The improved physiological characterizations of GLP715a make it a possible potent anti-diabetic drug in the treatment of type 2 diabetes mellitus.

Disulfide bond prolongs the half-life of therapeutic peptide-GLP-1.

The multiple physiological characterization of glucagon-like peptide-1 (GLP-1) makes it a promising drug candidate for the therapy of type 2 diabetes. However, the half-life of GLP-1 is short in vivo due to rapid degradation by dipeptidyl peptidase-IV (DPP-IV) and renal clearance. This indicates that the stabilization of GLP-1 is critical for its utility in drug development. In this study, we developed a cluster of GLP-1 homodimeric analogs, which fused the mutated GLP-1 monomer by an intra-disulfide bridge. The stabilities of the GLP-1 homodimeric analogs were investigated and the physiological functions of the analogs were compared with those of wild-type GLP-1 in rats and human serum. Single dose glucose tolerance test was performed to investigate the administration frequency which satisfied the efficient glucose regulatory in rats. Multiple dose glucose tolerance tests were employed also to study the long-acting anti-diabetic activity of GLP-1 homodimeric analog. The results indicated that the GLP-1 homodimeric analog (hdGLP1G10C) remarkably raised the biological half-life of GLP-1; also HDGLP1G10C showed better glucose tolerance and higher HbA(1c) reduction than GLP-1 in rodents. Based upon the results in this study, it was suggested that hdGLP1G10C prolonged the stability of GLP-1 and retained the biological activity of GLP-1. The improved physiological characterization of hdGLP1G10C makes it as possible potent anti-diabetic drug in the treatment of type 2 diabetes mellitus.

GLP-1 analogs containing disulfide bond exhibited prolonged half-life in vivo than GLP-1.

The multiple physiological characterizations of glucagon-like peptide-1 (GLP-1) make it a promising drug candidate for the therapy of type 2 diabetes. However, the half-life of GLP-1 is short in vivo due to degradation by dipeptidyl peptidase-IV (DPP-IV) and renal clearance. This indicates that the stabilization of GLP-1 is critical for its utility in drug development. In this study, we developed a cluster of GLP-1 mutants containing an inter-disulfide bond that is predicted to increase the half-life of GLP-1 in vivo. Exendin-4 was also mutated with a disulfide bond similar to the GLP-1 analogs. In this study, the binding capacities of the mutants were determined, the stabilities of the mutants were investigated and the physiological functions of the mutants were compared with those of wild-type GLP-1 and exendin-4 in animals. The results indicated that the mutants remarkably raised the half-life in vivo; they also showed better glucose tolerance and higher HbA(1c) reduction than GLP-1 and exendin-4 in rodents. These results suggest that GLP-1 and exendin-4 mutants containing disulfide bonds might be utilized as possible potent anti-diabetic drugs in the treatment of type 2 diabetes mellitus.

Development of potent glucagon-like peptide-1 agonists with high enzyme stability via introduction of multiple lactam bridges.

Glucagon-like peptide-1 (GLP-1) has the ability to lower the blood glucose level, and its regulatory functions make it an attractive therapeutic agent for the treatment of type 2 diabetes. However, its rapid degradation by enzymes like dipeptidyl peptidase-IV (DPP-IV) and neutral endopeptidase (NEP) 24.11 severely compromises its effective clinical use. Whereas specific DPP-IV inhibitors have been developed, NEP 24.11 targets multiple sites in the GLP-1 sequence, which makes it difficult to block. To address this drawback, we have designed and synthesized conformationally constrained GLP-1 analogues by introducing multiple lactam bridges that stabilized both alpha-helices in the N- and C-terminal regions simultaneously. In addition to improving the receptor activation capability (up to 5-fold) by fixing the alpha-helical conformations required for optimal receptor interaction, the introduced lactam bridges provided outstanding shielding over NEP 24.11 (half-life of >96 h). These highly constrained peptides are the first examples of NEP 24.11-resistant GLP-1 analogues.

Design, synthesis and in vitro characterization of Glucagon-Like Peptide-1 derivatives for pancreatic beta cell imaging by SPECT.

Novel Glucagon-Like Peptide-1 (GLP-1) derivatives containing the metal chelator DOTA (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid) and naturally occurring Indium ((113/115)In) were prepared using solid-phase Fmoc methods. All synthesized peptides contained d-Ala-8, a modification known to improve resistance towards degradation by dipeptidyl peptidase-IV. The effect of increased distance between DOTA and the peptide chain was investigated using an (aminoethyl) ethoxy acetyl linker, in order to reduce steric effects imposed by DOTA. Placement of linker and DOTA moieties were also varied within the GLP-1 sequence to test for optimal metal-complex location. The binding affinity of the peptide derivatives was determined in vitro with Chinese hamster ovary cells stably transfected with a human GLP-1 receptor (CHO/GLP-1R) cell line and was shown to be in the nM range. Gamma camera imaging of an insulinoma cell line was carried out using (111)In-labeled peptides. Our results suggest that the prepared GLP-1 derivatives are suitable imaging probes for studying pancreatic islet function in vivo.

Microwave-assisted solid phase synthesis, PEGylation, and biological activity studies of glucagon-like peptide-1(7-36) amide.

The insulinotropic hormone glucagon-like peptide-1 (GLP-1) is rapidly inactivated in the body. In order to improve its stability, we replaced the enzymatic hydrolyzation position Ala(8)with Gly and replaced Ala(30) with Cys firstly. Then the modified peptide was further PEGylated at thiol group of Cys(30). Biological activity studies showed that the resulting mPEG-MAL-Gly(8)-Cys(30)-GLP-1(7-36)-NH(2) exhibited long-lasting effect while maintaining moderate glucose-lowering activity.

Structure-activity and protraction relationship of long-acting glucagon-like peptide-1 derivatives: importance of fatty acid length, polarity, and bulkiness.

We here report a series of derivatives describing the structure-activity relationship around liraglutide, a once-daily human glucagon-like peptide-1 fatty acid derivative, with respect to potency as well as protraction in vivo. The spacer region between the fatty acid and the peptide is mostly important for potency, whereas the fatty acid or fatty acid mimetic is important for both potency and protraction. The length of the fatty acid is the most important parameter for protraction.