Abstract
The possibility of an insulin-independent blood glucose decreasing activity of sulfonylureas
was re-evaluated. Single dose studies in dogs with different sulfonylureas revealed
a ranking in the ratio of plasma insulin release/blood glucose decrease with glimepiride
exhibiting the lowest and glibenclamide the highest ratio. This ranking suggests that
sulfonylureas have extrapancreatic activity and that this is most pronounced for glimepiride.
Further evidence for this was derived from single dose studies in rabbits, euglycemic
hyperinsulinemic clamp studies in rats and subchronic studies in manifestly diabetic
KK-Ay mice. Extrapancreatic activity of sulfonylureas as deduced from the ranking in vivo between glimepiride and glibenclamide directly on peripheral tissues would imply
a similar ranking between the two drugs in glucose utilizing processes in isolated
muscle and fat cells. Indeed, glimepiride exhibits a higher potency compared to glibenclamide
with respect to stimulation of glucose transport, glucose transporter isoform 4 (GLUT4)
translocation and lipid and glycogen synthesis in normal and insulin-resistant adipocytes
and in muscle cells, as well as of the potential underlying signalling processes examined
at the molecular level. The molecular basis for the sulfonylurea-induced increase
of glucose transport and non-oxidative glucose metabolism may rely on the dephosphorylation
of key metabolic proteins/enzymes, like GLUT4 as demonstrated in isolated rat adipocytes.
Activation of certain serine/threonine-specific protein phosphatases by insulin has
been postulated to be mediated by the mitogen-activated protein kinase (MAPK) pathway
and phosphatidylinositol (PI)-3′-kinase. However, there was no evidence that these
pathways are involved in the regulation of protein phosphatase activity by sulfonylureas.
Binding and photoaffinity studies showed that glimepiride associates in a time- and
concentration-dependent non-saturable manner with detergent-insoluble complexes of
the plasma membrane which may correspond to caveolae. This association seems to be
based on the interaction of glimepiride with glycosyl-phosphatidylinositol (GPI) lipids
and membrane protein anchors. These were found to be enriched in detergent-insoluble
complexes together with a GPI-specific phospholipase (PLC), the caveolae-specific
coast protein, caveolin, and acylated tyrosine kinases of the src family. Sulfonylureas
were found to stimulate the GPI-PLC and tyrosine phosphorylation of caveolin. This
is presumably caused by direct interaction of the sulfonylurea into caveolar glycolipids
and stimulation of a caveolar src tyrosine kinase, respectively. In accordance with
the higher potency of glimepiride in vivo and in glucose transport/metabolism in vitro, the EC50 values for GPI-PLC activation and caveolin phosphorylation were lower for glimepiride
than those for glibenclamide. The stimulation of protein tyrosine phosphorylation
by sulfonylureas via this pathway not involving the insulin signaling cascade may
be coupled to activation of specific protein phosphatases regulating glucose transport
and metabolism. The concentrations required in vitro were higher than the reported therapeutic plasma concentrations. However, provided
that the observed time-dependent accumulation of glimepiride in caveolae of peripheral
cells were of functional relevance for stimulation of glucose transport/metabolism
and would also occur in vivo, due to the longer exposure times even at lower drug
concentrations the insulin-independent blood glucose decreasing activity of sulfonylureas
might become effective in vivo.
Key words
Non-Insulin-Dependent Diabetes Mellitus (NIDDM) - Sulfonylureas - Glibenclamide -
Insulin Signaling - Glucose Transport and Metabolism - Phospholipase C (PLC) - Glycosyl-Phosphatidylinositol
(GPI) - Caveolae
