OBJECTIVES: Our aim was to improve the in vivo pharmacokinetics and pharmacodynamics of exendin-4 by using site-specific PEGylation. METHODS: We designed the PEGylated peptide based on its structure and activity relationship and prepared the conjugate by two steps of chromatographic purification. After obtained the conjugate we confirmed its glucose-lowering activity in normal mice and determined its half-life in SD rats. Then we evaluated its anti-diabetic activity in a multiple low-dose Streptozocin (STZ)-induced diabetic mice model. KEY FINDINGS: With the process established in this study the product conjugate was obtained with a yield of over 60% and purity of above 99%. The conjugate maintained its original conformation after modification. In SD rats its half-life was prolonged to 27.12 ± 5.75 h which was 17.61-fold longer than that of the natural exendin-4 for which the half-life was only 1.54 ± 0.47 h. Its anti-diabetic activity was significantly improved in the diabetic mice. CONCLUSIONS: Compare with native exendin-4, the C-terminal site-specific PEGylated analog of exendin-4 obtained in this study has an improved pharmacokinetics and pharmacodynamics in vivo and could be regarded as a potential candidate for the future development of anti-diabetic drugs.
OBJECTIVES: Our aim was to improve the in vivo pharmacokinetics and pharmacodynamics of exendin-4 by using site-specific PEGylation. METHODS: We designed the PEGylated peptide based on its structure and activity relationship and prepared the conjugate by two steps of chromatographic purification. After obtained the conjugate we confirmed its glucose-lowering activity in normal mice and determined its half-life in SD rats. Then we evaluated its anti-diabetic activity in a multiple low-dose Streptozocin (STZ)-induced diabeticmice model. KEY FINDINGS: With the process established in this study the product conjugate was obtained with a yield of over 60% and purity of above 99%. The conjugate maintained its original conformation after modification. In SD rats its half-life was prolonged to 27.12 ± 5.75 h which was 17.61-fold longer than that of the natural exendin-4 for which the half-life was only 1.54 ± 0.47 h. Its anti-diabetic activity was significantly improved in the diabeticmice. CONCLUSIONS: Compare with native exendin-4, the C-terminal site-specific PEGylated analog of exendin-4 obtained in this study has an improved pharmacokinetics and pharmacodynamics in vivo and could be regarded as a potential candidate for the future development of anti-diabetic drugs.