Diabetes Mellitus Type I Clinical Trial
Official title:
Metabolic Signalling in Muscle- and Adipose Tissue Following Insulin Withdrawal and Growth Hormone Injection in Type I Diabetes Mellitus, a Clinical Experimental Study.
Diabetes mellitus type I (DM I) is characterized by lack of endogenous insulin and these
patients are 100% dependent on insulin substitution to survive.
Insulin is a potent anabolic hormone with its primary targets in the liver, the skeletal
muscle-tissue and - adipose-tissue.
Severe lack of insulin leads to elevated blood glucose levels, dehydration, electrolyte
derangement, ketosis and thus eventually ketoacidosis.
Insulin signalling pathways are well-known.
Growth hormone (GH) is also a potent anabolic hormone, responsible for human growth and
preservation of protein during fasting. GH (in concert with lack of insulin) induces
lipolysis during fasting. It is not known how GH exerts its lipolytic actions.
The aim is to define insulin and growth hormone (GH) signalling pathways in 3 different
states in patients with DM I.
And to test whether ATGL-related lipolysis in adipose tissue contributes to the development
of ketosis.
1. Good glycemic control
2. Lack of insulin (ketosis/ketoacidosis)
3. Good glycemic control and GH injection
Diabetes mellitus type I (DMI ) is characterized by lack of endogenous insulin and these
patients are 100% dependent on insulin substitution to survive.
Insulin is a potent anabolic hormone with its primary targets in- the liver, -the skeletal
muscle-tissue and - fat-tissue.
In the liver it enhances glycogenesis and inhibits glycogenolysis and gluconeogenesis.
In skeletal muscle-tissue, it enhances glucose transport into the cell, glycogenesis,
glycolysis, glucose oxidation and protein synthesis.
In fat-tissue, it inhibits lipolysis and enhances lipogenesis.
This indicates that a fall in serum insulin levels lead to increased blood glucose and
increased levels of FFA's (free fatty acids) in the blood - eventually leading to ketone
production.
If this condition is not corrected, it will lead to ketoacidosis, which is a potentially
life-threatening condition, that is to be corrected under hospital admission with
fluid-therapy, electrolyte- and insulin-substitution.
Insulin has been studied thoroughly and signalling pathways are well known.
An interesting pathway is suppression of lipolysis. The most important and rate-limiting
lipase in triglyceride hydrolysis is adipose triglyceride lipase (ATGL)(1-5). A connection
between ATGL and G0/G1 switch gene (G0S2) has been shown (6,7). During lipolysis ATGL is
up-regulated and G0S2 is down-regulated and the promoter region for G0S2 has binding-sites
for glucose, insulin dependent transcription factors and peroxisome proliferator-activated
receptors y (PPAR-y)(8).
One former study has shown that fasting reduces G0S2 and increases ATGL in humane
adipose-tissue(7).
The anti-lipolytic effects of insulin, could be thought, to be mediated through increased
transcription of G0S2 which then in turn inhibits ATGL. Conversely, increased lipolysis
during lack of insulin.
Growth hormone and growth hormone dependent synthesis og IGF-1 (Insulin-like growth factor -
1) is crucial for human growth before and during adolescence. As an adult GH and IGF-1 are
still potent growth factors and also they exert essential regulatory properties on human
metabolism(9,10)
GH- signalling pathways go through the GH-receptor, which phosphorylates and thus activates
the receptor associated Janus Kinase 2 (JAK2). The signals from this point have been
examined in numerous studies.
In rodents, the signal has been shown to run three ways (9,10) Studies on human fibroblast
cells have been able to support two of these pathways (MAPK - mitogen-activated protein
kinase and STAT - signal transducer and activator of transcription), but not through the
insulin receptor substrate (IRS) and phosphatidylinositol 3-kinase (PI3-K) pathway.
In human (in vivo) studies, GH stimulation and phosphorylation of STAT5 has been evident,
however an association between GH stimulation and activation of MAPK and PI3-K has not been
shown (11).
The latter is interesting and remarkable, considering the insulin-agonistic and antagonistic
effects of GH.
GH stimulates lipolysis, but exactly how the lipolytic properties of GH are mediated is not
fully understood. However, it is shown that GH has an effect on hormone-sensitive lipase
(12) (HSL).
Other options could be, as found in rodents, interaction via PI3-K signaling pathway or via
G0S2/ATGL interaction, either directly or perhaps mediated through IGF-1.
Humane intracellular signaling-pathways during development of ketosis/ketoacidosis are not
well-known. The investigators believe that understanding these pathways and the exact
mechanisms behind the development of ketoacidosis, is of great importance.
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Allocation: Randomized, Intervention Model: Factorial Assignment, Masking: Single Blind (Subject), Primary Purpose: Basic Science
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