Gerhard Seipke scite author profile

BackgroundInsulin glargine (Lantus®) is a long-acting basal insulin analog that demonstrates effective day-long glycemic control and a lower incidence of hypoglycemia than NPH insulin. After subcutaneous injection insulin glargine is partly converted into the two main metabolites M1 ([GlyA21]insulin) and M2 ([GlyA21,des-ThrB30]insulin). The aim of this study was to characterize the glargine metabolites in vitro with regard to their insulin receptor (IR) and IGF-1 receptor (IGF1R) binding and signaling properties as well as their metabolic and mitogenic activities.MethodsThe affinity of human insulin, insulin glargine and its metabolites to the IR isoforms A and B or IGF1R was analyzed in a competitive binding assay using SPA technology. Receptor autophosphorylation activities were studied via In-Cell Western in CHO and MEF cells overexpressing human IR-A and IR-B or IGF1R, respectively. The metabolic response of the insulins was studied as stimulation of lipid synthesis using primary rat adipocytes. Thymidine incorporation in Saos-2 cells was used to characterize the mitogenic activity.ConclusionsThe binding of insulin glargine and its metabolites M1 and M2 to the IR were similar and correlated well with their corresponding autophosphorylation and metabolic activities in vitro. No differences were found towards the two IR isoforms A or B. Insulin glargine showed a higher affinity for IGF1R than insulin, resulting in a lower EC50 value for autophosphorylation of the receptor and a more potent stimulation of thymidine incorporation in Saos-2 cells. In contrast, the metabolites M1 and M2 were significantly less active in binding to and activation of the IGF1R and their mitogenicity in Saos-2 cells was equal to human insulin. These findings strongly support the idea that insulin glargine metabolites contribute with the same potency as insulin glargine to blood glucose control but lead to significantly reduced growth-promoting activity.

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The Evolution of Insulin Glargine and its Continuing Contribution to Diabetes Care

Hilgenfeld

Seipke

Berchtold

et al. 2014

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The epoch-making discovery of insulin heralded a new dawn in the management of diabetes. However, the earliest, unmodified soluble insulin preparations were limited by their short duration of action, necessitating multiple daily injections. Initial attempts to protract the duration of action of insulin involved the use of various additives, including vasoconstrictor substances, which met with limited success. The subsequent elucidation of the chemical and three-dimensional structure of insulin and its chemical synthesis and biosynthesis allowed modification of the insulin molecule itself, resulting in insulin analogs that are designed to mimic normal endogenous insulin secretion during both fasting and prandial conditions. Insulin glargine was the first once-daily, long-acting insulin analog to be introduced into clinical practice more than 10 years ago and is specifically designed to provide basal insulin requirements. It has a prolonged duration of action and no distinct insulin peak, making it suitable for once-daily administration and reducing the risk of nocturnal hypoglycemia that is seen with intermediate-acting insulins. Insulin glargine can be used in combination with prandial insulin preparations and non-insulin anti-diabetic agents according to individual requirements.Electronic supplementary materialThe online version of this article (doi:10.1007/s40265-014-0226-4) contains supplementary material, which is available to authorized users.

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The Long Acting Human Insulin Analog HOE 901: Characteristics of Insulin Signalling in Comparison to Asp(B10) and Regular Insulin

et al. 1998

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HOE 901 is a new biosynthetic long-acting human insulin analog (GLY[A21]ARG[B31]ARG[B32]). We compared HOE 901 with normal human insulin and the insulin analog Asp(B10), which is known to have increased mitogenic activity at least partially mediated through the insulin receptor. We have analyzed receptor binding, insulin-induced receptor autophosphorylation and phosphorylation of receptor substrates in rat-1 fibroblasts overexpressing human insulin receptor isoform A (HIR A) or B (HIR B). In HIR A expressing cells, insulin and its analogs showed no significant differences in receptor association while clearly different dissociation kinetics were observed. In HIR B expressing cells, no significant differences in association and dissociation kinetics were observed. All insulins induced rapid autophosphorylation of the insulin receptor reaching a maximum after 10 min of stimulation. Asp(B10)insulin induced a prolonged phosphorylation state (over 60 minutes) of the 95 kDa receptor beta-subunit and of the substrates IRS-1/IRS-2 and Shc in contrast to normal human insulin and to HOE 901. In addition, we observed an increased and prolonged tyrosine phosphorylation of an unidentified protein with Asp(B10)insulin at about 60 kDa. Insulin-dependent dephosphorylation of the focal adhesion kinase (p125FAK) was equally induced by all these ligands. With respect to [3H]thymidine incorporation into DNA, HOE 901 had similar effects as normal human insulin, while Asp(B10)insulin showed increased [3H]thymidine incorporation. In summary, the data show that the increased mitogenic activity of Asp(B10)insulin may be explained with a prolonged kinetics of tyrosine phosphorylation of the insulin receptor and of insulin signalling elements together with the preferential phosphorylation of an yet unidentified 60 kDa protein. HOE 901 behaves with respect to insulin receptor binding, receptor autophosphorylation, phosphorylation of signalling elements and promotion of mitogenesis like regular human insulin.

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Growth promoting and metabolic activity of the human insulin analogue [GlyA21,ArgB31,ArgB32]insulin (HOE 901) in muscle cells

Bahr

Kolter

Seipke

et al. 1997

European Journal of Pharmacology

106

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Effects of the Long-Acting Insulin Analog Insulin Glargine on Cultured Human Skeletal Muscle Cells: Comparisons to Insulin and IGF-I

Ciaraldi

Carter

Seipke

et al. 2001

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The aim of this study was to determine whether the long-acting insulin analog, insulin glargine, behaves like human insulin for metabolic and mitogenic responses in differentiated cultured human skeletal muscle cells from nondiabetic and diabetic subjects. Human insulin and insulin glargine were equipotent in their ability to compete for [(125)I]insulin binding. Insulin glargine displaced [(125)I]IGF-I from the IGF-I-binding site with approximately 0.5% the potency of IGF-I. In nondiabetic muscle cells, all three ligands stimulated glucose uptake similarly, whereas the sensitivity of glucose uptake was greatest in response to IGF-I and lower and equal for human insulin and insulin glargine. In diabetic muscle cells, the final responsiveness of glucose uptake was greatest for IGF-I and equivalent for human insulin and insulin glargine; sensitivities were the same as those for nondiabetic cells. Thymidine uptake into DNA was stimulated foremost by IGF-I, whereas human insulin and insulin glargine showed equivalent, but greatly reduced, sensitivities and potencies (<1% IGF-I). Stimulation of Akt phosphorylation was slightly more responsive to IGF-I compared with human insulin and insulin glargine, with sensitivities similar to glucose uptake stimulation. We conclude that in human skeletal muscle cells, insulin glargine is equivalent to human insulin for metabolic responses and does not display augmented mitogenic effects.

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Gerhard Seipke

In Vitro Metabolic and Mitogenic Signaling of Insulin Glargine and Its Metabolites

The Evolution of Insulin Glargine and its Continuing Contribution to Diabetes Care

The Long Acting Human Insulin Analog HOE 901: Characteristics of Insulin Signalling in Comparison to Asp(B10) and Regular Insulin

Growth promoting and metabolic activity of the human insulin analogue [GlyA21,ArgB31,ArgB32]insulin (HOE 901) in muscle cells

Effects of the Long-Acting Insulin Analog Insulin Glargine on Cultured Human Skeletal Muscle Cells: Comparisons to Insulin and IGF-I

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