Role of Highâ€Density Lipoproteins in Cholesterol Homeostasis and Glycemic Control | Journal of the American Heart Association
Emerging evidence (summarized in Table) indicates that HDL†and apoAâ€I–targeted therapies are a potential option for conserving residual βâ€cell function and improving insulin sensitivity in patients who are progressing toward, or have already developed, T1DM and T2DM. The recent failures of HDLâ€raising agents in cardiovascular clinical outcome trials highlight the need to develop novel and innovative HDLâ€targeted approaches to achieve these goals. Elucidating the mechanism(s) underlying the antidiabetic functions of HDLs and apoAâ€I will also provide opportunities to identify and develop new HDLâ€targeted therapies for diabetes mellitus. Achievement of these goals could be particularly advantageous for patients with T1DM for whom treatment options are currently limited to insulin replacement therapy, and for patients with T2DM that are refractory to currently available therapies.
Table 1.Role of HDL and apoAâ€I in Glycemic Control, Insulin Sensitivity and βâ€Cell Function
Topic Outcome Reference
Association of HDLâ€C and apoAâ€I levels with glycemic control
Subjects with T2DM Serum HDLâ€C, apoAâ€I, and HDLâ€C/apoAâ€I levels are inversely associated with insulin resistance by HOMAâ€IR 9
Subjects with impaired glucose tolerance ApoAâ€I level is an independent risk factor for glucose tolerance 10
HDL and apoAâ€I in glucose disposal/insulin sensitivity
Primary human skeletal muscle cells ApoAâ€I improves insulinâ€dependent and â€independent glucose uptake 27
C2C12 skeletal muscle cells ApoAâ€I increases glucose uptake by phosphorylation of AMPK 35
Highâ€fat–fed C57BL/6 mice ApoAâ€I improves insulin sensitivity by reducing systemic and hepatic inflammation 40
db/db mice Longâ€term HDL infusion improves glucose tolerance by activating GSKâ€3 and AMPK in skeletal muscle 37
Pregnant female Wistar rats ApoAâ€I infusions increase insulin sensitivity, reduces systemic inflammation and protects against pregnancyâ€induced insulin resistance 45
Subjects with T2DM A single rHDL infusion reduces plasma glucose levels by increasing insulin secretion and promoting glucose uptake in skeletal muscle 2
HDL and apoAâ€I in βâ€cell function
Min6 insulinoma cells HDLs isolated from normal human plasma, rHDLs, and apoAâ€I increase Ins1 and Ins2 gene transcription and GSIS 58
Insâ€1E insulinoma cells ApoAâ€I increases Pdx1 gene transcription and GSIS 57
βTC3 insulinoma cells Incubation with HDL protects βTC3 cells against LDLâ€induced apoptosis 70
C57BL/6 mice ApoAâ€I infusions increase insulin secretion and improve glucose tolerance 52
Highâ€fat–fed C57BL/6 mice Shortâ€term apoAâ€I treatment increases GSIS and improves glucose clearance independent of insulin secretion 53
Mice with conditional deletion of ABCA1 and ABCG1 in β cells ApoAâ€I infusions increase GSIS in islets isolated from mice with elevated islet cholesterol levels 54
Healthy subjects and Min6 cells CETP inhibition increases plasma HDLâ€C, apoAâ€I, and insulin levels in normal human subjects. Plasma from these subjects also increases GSIS in Min6 cells pretreated with oxidized LDLs 60
Isolated human islets HDL protects human islets against oxidized LDLâ€induced apoptosis 71
Isolated human and mouse islets HDL protects human and mouse islets from interleukinâ€1β– and glucoseâ€induced apoptosis 72
AMPK indicates adenosine monophosphateâ€activated protein kinase; apoAâ€I, apolipoprotein Aâ€I; CETP, cholesteryl ester transfer protein; GSIS, glucoseâ€stimulated insulin secretion; GSK, glycogen synthase kinaseâ€3; HDL, highâ€density lipoprotein; HDLâ€C, highâ€density lipoprotein cholesterol; HOMAâ€IR, Homeostatic model assessment of insulin resistance; LDL, lowâ€density lipoprotein; rHDL, reconstituted HDL.