A glucose-responsive insulin therapy protects animals against hypoglycemia
Ruojing Yang, Margaret Wu, Songnian Lin, Ravi P. Nargund, Xinghai Li, Theresa Kelly, Lin Yan, Ge Dai, Ying Qian, Qing Dallas-yang, Paul A. Fischer, Yan Cui, Xiaolan Shen, Pei Huo, Danqing Dennis Feng, Mark D. Erion, David E. Kelley, James Mu
Ruojing Yang, Margaret Wu, Songnian Lin, Ravi P. Nargund, Xinghai Li, Theresa Kelly, Lin Yan, Ge Dai, Ying Qian, Qing Dallas-yang, Paul A. Fischer, Yan Cui, Xiaolan Shen, Pei Huo, Danqing Dennis Feng, Mark D. Erion, David E. Kelley, James Mu
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Research Article Endocrinology Metabolism

A glucose-responsive insulin therapy protects animals against hypoglycemia

Abstract

Hypoglycemia is commonly associated with insulin therapy, limiting both its safety and efficacy. The concept of modifying insulin to render its glucose-responsive release from an injection depot (of an insulin complexed exogenously with a recombinant lectin) was proposed approximately 4 decades ago but has been challenging to achieve. Data presented here demonstrate that mannosylated insulin analogs can undergo an additional route of clearance as result of their interaction with endogenous mannose receptor (MR), and this can occur in a glucose-dependent fashion, with increased binding to MR at low glucose. Yet, these analogs retain capacity for binding to the insulin receptor (IR). When the blood glucose level is elevated, as in individuals with diabetes mellitus, MR binding diminishes due to glucose competition, leading to reduced MR-mediated clearance and increased partitioning for IR binding and consequent glucose lowering. These studies demonstrate that a glucose-dependent locus of insulin clearance and, hence, insulin action can be achieved by targeting MR and IR concurrently.

Authors

Ruojing Yang, Margaret Wu, Songnian Lin, Ravi P. Nargund, Xinghai Li, Theresa Kelly, Lin Yan, Ge Dai, Ying Qian, Qing Dallas-yang, Paul A. Fischer, Yan Cui, Xiaolan Shen, Pei Huo, Danqing Dennis Feng, Mark D. Erion, David E. Kelley, James Mu

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Figure 4

Cellular MR levels correlate with GRI clearance.

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Cellular MR levels correlate with GRI clearance. (A) Glucose lowering by...
(A) Glucose lowering by GRI1 in C57BL/6 mice was assessed in the absence or presence of α-MM coinjection, and corresponding GRI1 plasma levels are shown in B. n = 8 per group. **P < 0.01, ***P < 0.001 vs. GRI1 alone group by 1-way ANOVA with Tukey’s test. (C) High-content imaging analysis of cellular uptake of Alexa488-labeled GRI1 and GRI2 in the presence or absence of 10 mg/ml mannan in cultured rat macrophage NR8383 cells. n = 2–5 per group. **P < 0.01 corresponding GRI vs. GRI + mannan by Student’s t test. (D) Cellular uptake of GRI2 and lysosome staining by LysoTracker are measured in cultured rat macrophage NR8383 cells. Original magnification, ×40. (E) siRNA-mediated knockdown of MR and corresponding GRI uptake in NR8383 cells. n = 3 per group. *P < 0.05 vs. scrambled siRNA group by Student’s t test. A 57% reduction of GRI2 uptake corresponded to a 65% reduction of MR protein. Western blot detection of MR protein is shown in E. (F) Overexpression of human MR in HEK293 cells and corresponding GRI1 and GRI2 uptake are shown in the presence or absence of 10 mg/ml mannan. n = 2–3 per group. **P < 0.01 vs. corresponding GRI uptake in parental HEK cells by Student’s t test. (G) Representative FACS analysis of GRI2 and OVA uptake in primary human liver cell mixture is shown. The x axis represents medium fluorescence intensity of Alexa488-labeled GRI2/OVA in each cell. The y axis represents medium fluorescence intensity of APC-labeled MR/IgG antibodies only detecting membrane-expressing MR in each cell. Results are shown as mean ± SEM (A and B) or mean ± SD (C, E, and F). Results represent 2 (F) or 3 independent experiments (A, B, C, E, and G).