Novel peptidic dual GLP-1/glucagon receptor agonist alleviates diabetes and diabetic complications in combination with low-intensity ultrasound.

OBJECTIVE: To design and evaluate a novel oxyntomodulin (OXM) derivative with albumin-binding helix domain and dual GLP-1 receptor (GLP-1R) and glucagon receptor (GcgR) activation activity to achieve metabolize improvement on the diabetes-related complication. MATERIALS AND METHODS: Mutation (D-Ser2) on OXM was performed and then different helix albumin-binding domains were fused to the mutated OXM via a thrombin-cleavable linker to generate seven fusion peptides, named LM01-LM07. Seven LM peptides were synthesized and screened via in vitro receptor activation test, albumin binding measurement and protease cleavage assay to select potent candidate peptide for further in vivo study. Moreover, acute and chronic efficacy studies were conducted to evaluate the efficacy of selected candidate using db/db mice. RESULTS: LM06, as selected OXM derivative, exhibited higher albumin-binding affinity, sustained-release efficiency and balanced activation activities on both GLP-1R and GcgR compared with other ones. Moreover, LM06 was demonstrated with improved hypoglycemic and insulinotropic abilities in receptor-deficient mice via activating GLP-1R. In addition, prolonged anti-diabetic efficacies of LM06 were demonstrated via hypoglycemic duration assay and OGTT in db/db mice. Further pharmacokinetic test of LM06 in both rats and monkeys identified improved half-life and other metabolic characteristics. Nevertheless, 8-week subcutaneously dosed LM06 in db/db mice achieved prominent efficacies on glucostasis, weight-lowering, pancreatic function and adipogenesis via activating GLP-1R and GcgR. Moreover, LM06 also could accelerate diabetic skin wound closure in combination with low-intensity ultrasound. CONCLUSIONS: LM06, as a long-acting dual GLP-1R/GcgR agonist, exerts potential as a once-weekly therapeutic candidate against diabetes-related complication in combination with low-intensity ultrasound.

Design, screening and biological evaluation of novel fatty acid chain-modified oxyntomodulin-based derivatives with prolonged glucose-lowering ability and potent anti-obesity effects.

Recently, oxyntomodulin (OXM) has emerged as a treatment option for type 2 diabetes mellitus and obesity. In order to develop more promising novel OXM derivatives combining glycemic effects of glucagon-like peptide-1 (GLP-1) and lipolytic properties of glucagon, six 12-mer GLP-1 receptor agonists (PP01-PP06) were screened using a phage display method and then fused to OXM (3-37) to generate hybrid OXM derivatives (PP07-PP12). PP11, as a selected starting point, was further site-specifically modified with three lengths of fatty acid chains to provide long-acting conjugates PP13-PP24, among which PP18 was found not only to retain almost the entire balanced activation potency of PP11 in GLP-1/glucagon receptors but also to enhance plasma stability and prolong hypoglycemic activity. PP18 was further confirmed as an insulin secretagogue and glycemic agent in gene knockout mice. The protracted antidiabetic effects and in vivo half-life of PP18 were further proved by hypoglycemic efficacies in diet-induced obesity (DIO) mice and pharmacokinetics tests in Sprague Dawley (SD) rats, respectively. Nevertheless, administration of PP18 once per day normalized food intake, body weight, blood biochemical indexes, insulin resistance and islet function of DIO mice. These preclinical results suggested that PP18, as a novel OXM-based dual GLP-1 and glucagon receptor agonist, may serve as a novel therapeutic approach to treat T2DM and obesity.

Chemical polysialylation: design of conjugated human oxyntomodulin with a prolonged anorexic effect in vivo.

Recombinant gut hormone oxyntomodulin (OXM) is known to act as a satiety signal in human subjects and has therapeutic potential as an appetite controlling agent. The only form of this hormone that has a prospective use is a modified one, because native OXM has a very short half-life in vivo. Conjugation of OXM and the natural hydrophilic polymer polysialic acid (PSA) may significantly improve its half-life. Chemical polysialylation in vitro was used to create a long-acting form of OXM, the polysialic acid-oxyntomodulin (PSA-OXM) conjugate. The conjugation site was identified using mass shift comparative analysis of Asp-N proteolytic digests. The anorexic effect of the conjugate was tested on the lean, fasted mouse model. A two-stage purification technique was developed to obtain a homogeneous PSA-OXM conjugate, suitable for in vivo testing. The N-terminal backbone primary amino group was found to be the only point of conjugation. The conjugate obtained was resistant to the DPP-IV protease. A single injection of PSA-OXM at 15 µmol/kg dose was sufficient to maintain a steady decrease in food consumption for 8 h (P < 0.05). The length of the anorexic effect achieved is comparable to other long-acting derivatives of OXM but it requires a much higher dose for administration. It is expected that site-directed attachment of the PSA chain to the inner residues of OXM, away from the site of interaction with receptors, would produce a compound with a higher specific activity but comparable stability in the bloodstream. The conjugation technique used may be used to create OXM derivatives and other related hormones to obtain long-lasting variants, with improved suitability for clinical use.

Crystallization and preliminary x-ray analysis of anti-obesity peptide hormone oxyntomodulin.

Oxyntomodulin is a proglucagon-derived gut hormone that reduces food intake and body weight, thus represents a potential therapy for obesity. We synthesized and crystallized oxyntomodulin. The crystal diffracts x-ray to 2.4 A resolution and belongs to space group P2(1)3 with unit-cell parameters a=b=c= 48.44 A, alpha=beta=gamma=90 degrees . Preliminary analysis indicates a trimer packing in one asymmetric unit.