Investigation of pharmacological compounds to increase skeletal muscle glucose uptake
in vitro and in vivo [A vázizom glükózfelvételét fokozó farmakológiai vegyületek vizsgálata
in vitro és in vivo]
Background and aims: A healthy metabolism and proper regulation of blood sugar levels
are key factors to maintain the quality of our daily lives. In these, a significant
role can be played by skeletal muscle, which constitutes a substantial portion of
the body. Beside adipose tissue, skeletal muscle also expresses the unique type 4
glucose transporter (GLUT4) responsible for glucose uptake. The GLUT4 translocation
to the plasma membrane, and consequently glucose uptake involves complex regulatory
mechanisms. Initiators of this process include insulin binding to the insulin receptor,
which can regulate Akt substrate of 160 kDa (AS160; also known as TBC1D4) through
the phosphoinositide 3-kinase (PI3K)/ 3-phosphoinositide-dependent protein kinase
1 (PDK1)/ Akt axis. AMP-activated protein kinase (AMPK), which senses cellular energy
status, is also capable of regulating GLUT4 translocation via AS160. However, in case
of insulin resistance and consequently in diabetes the GLUT4 translocation becomes
impaired. As a result, blood glucose levels remain consistently high, giving rise
to numerous long-term complications such as cardiovascular diseases, peripheral neuropathy,
retinopathy, and diabetic nephropathy. Although the dramatically increasing number
of patients makes it increasingly urgent to find a solution, so far, only a few compounds
have been discovered capable of improving GLUT4 translocation and normalizing blood
glucose levels. The possibility has emerged that some less explored pathways in GLUT4
translocation,such as the bone morphogenetic protein (BMP) signaling pathway, might
influence blood glucose regulation. Recently, it has been discovered that BMPs can
sensitize tissues to insulin, increase the amount of GLUT4, reduce blood glucose levels
through the DK1/PI3K/Akt pathway, thus enhancing GLUT4 translocation, and changes
in their serum levels correlate with diabetes. Since oxidative stress is known to
play a role in the development of insulin resistance and diabetes, maintaining redox
balance is of paramount importance. Astaxanthin is an exceptionally potent antioxidant
capable of reducing high glucose- or fatty acid-induced reactive oxygen species (ROS)
formation, improving insulin sensitivity, and enhancing glucose uptake. Moreover,
astaxanthin is also easily available, as it is present in numerous marine organisms
and consequently in our seafoods. Therefore, our aim was to investigate the impact
of a BMP-inducing agent, tilorone, on skeletal muscle glucose uptake in vitro and
in vivo. Additionally, we aimed to explore how 8 astaxanthin, as a potent antioxidant,
can influence the regulation of proteins crucial for GLUT4 translocation. Materials
and methods: The tilorone treatment was conducted at two concentrations (20 and 35
nM) on C2C12 myoblasts for a duration of 40 hours. Additionally, after 5 days of differentiation,
tilorone was applied only at the lower concentration (20 nM) on myotubes to understand
its acute effects at 2 and 5 hours on myotubes. In both of our in vivo experiments,
we used 3-month-old C57BL/6 mice. Two intraperitoneal tilorone injections (25 mg/kg
body weight) were administered with a 3-day interval. For the astaxanthin feeding
model, the astaxanthin-containing preparation dissolved in ethanol was added to the
mice's normal food at a dosage of 4 g/kg for a duration of 4 weeks. We used qRT-PCR
to determine the transcription of BMPs, as well as GLUT1 and GLUT4. Western blot technique
was used to examine Smad1/5/8 activation, the levels of GLUT1 and GLUT4, and the phosphorylation
changes of molecules involved in GLUT4 translocation. Immunofluorescence labeling
and microscopy were also utilized to assess GLUT4 quantities. Using glucose analogue,
18F-fluoro-2-deoxyglucose (18FDG), we investigated cellular glucose uptake. The specific
inhibitor of GLUT1 was used to specify GLUT1-associated 18FDG uptake. Myoblast itochondrial
function was assessed through high-resolution respirometry. Additionally, tissue glucose
uptake was measured in vivo using 18FDG-PET/CT imaging. Key results: Tilorone is capable
of inducing multiple BMPs (BMP2, BMP4, BMP7, and BMP14) in myoblasts and activating
the BMP-mediated Smad1/5/8 and Smad4. As a result of tilorone treatment, GLUT4 levels
increased, and Akt2/AS160 signaling was activated. The uptake of the labeled glucose
also increased, which was not accompanied by an increase in mitochondrial O2 consumption;
in fact, the basal and ATP-linked respiration decreased. AS160 phosphorylation and
glucose uptake were elevated in myotubes as well. Additionally, tilorone was able
to further enhance insulin-stimulated Akt2 phosphorylation and 18FDG uptake. In vivo,
tilorone increased 18FDG uptake in skeletal muscle, adipose tissue, and liver. Furthermore,
astaxanthin feeding elevated the activation of proteins important in glucose uptake
and metabolism in an in vivo mouse model.