Carbohydrate metabolism

Summary

Carbohydrate metabolism is the whole of the biochemical processes responsible for the metabolic formation, breakdown, and interconversion of carbohydrates in living organisms. Carbohydrates are central to many essential metabolic pathways. Plants synthesize carbohydrates from carbon dioxide and water through photosynthesis, allowing them to store energy absorbed from sunlight internally. When animals and fungi consume plants, they use cellular respiration to break down these stored carbohydrates to make energy available to cells. Both animals and plants temporarily store the released energy in the form of high-energy molecules, such as adenosine triphosphate (ATP), for use in various cellular processes. Humans can consume a variety of carbohydrates, digestion breaks down complex carbohydrates into simple monomers (monosaccharides): glucose, fructose, mannose and galactose. After resorption in the gut, the monosaccharides are transported, through the portal vein, to t

Official source

https://en.wikipedia.org/wiki/Carbohydrate_metabolism

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Investigation of physiological roles of AMPK-activated protein kinase y3

Philipp Jurijvic Rhein

Clinical trials have shown that direct activators of an evolutionary-conserved metabolic sensor, AMP-activated protein kinase (AMPK), are beneficial in preventing/treating a range of metabolic disorders, including type 2 diabetes. These activators, including 991/MK-8722, bind at regulatory site, termed the allosteric drug and metabolite (ADaM-site) at the interface between the catalytic alpha subunit and regulatory beta subunit. In addition, another approach for direct activation of AMPK is through mimicking its natural ligands, AMP/ADP, by binding to the nucleotide site in the y3 subunit, e.g. 5-aminoimidazole-4-carboxamide ribonucleotide (AICAR). Interestingly, their ability to influence glucose homeostasis is reported to be through activation of AMPK complexes found within the skeletal muscle. The AMPKy3 is unique as an AMPK subunit isoform since it is selectively expressed in glycolytic skeletal muscle fibres. To gain more insight into the y3 isoform-specific regulation of glucose metabolism, we used a y3 knock-out (y3-/-) mouse model to investigate the effects of the AICAR and 991/MK-8722. We confirm that y3 isoform expression and activity is high glycolytic muscles, including extensor digitorum longus (EDL), whereas there is very little detected in oxidative soleus (SOL) muscle. We show that AICAR and 991/MK-8722 stimulated glucose uptake in both EDL and SOL muscles. Interestingly, only the ability of AICAR to induce glucose uptake was blunted in EDL muscle taken from y3-/- mice. Consistent with this, whole-body glucose clearance was also impaired in y3-/- mice in response to an AICAR, whilst MK-8722 lowered blood glucose similarly between WT and y3-/- mice. Despite the presence of y1-containing complexes, which are the most predominant complexes in both EDL and SOL muscles, this suggests that different AMPKy isoforms play different roles in glucose homeostasis in response to AICAR. We further looked at de novo glycogen synthesis and glucose utilisation in skeletal muscle. Despite similar basal glucose uptake between muscles from WT and y3-/-, y3-deficiency results in lower basal glycogen content only in glycolytic muscles. We show that this is not due to an inability to synthesise glycogen de novo, since MK-8722 was able to increase glycogen levels in EDL. Instead, we show that the decrease in basal glycogen in y3-/- EDL, may be linked lower expression of UDP-glucose pyrophosphorylase 2 (UGP2). This suggests that AMPKy3 may play a role in steering the molecular fate of glucose inside the cell. Taken together, whilst we show that AMPKy3 is dispensable for ex vivo glucose transport and in vivo glucose homeostasis in response to ADaM-site AMPK activators, nucleotide-mediated activation of y3 by AICAR is impaired. Further research is required to understand the nucleotide regulation of different y-containing AMPK complexes. This differential activation mechanism could be exploited to specifically target AMPKy3 complexes in the muscle, and potentially avoid deleterious effects of activation of AMPK complexes in other tissues.

EPFL2021

While altered metabolism is a well-established tumor cell trait, the specifics of metabolic rewiring during cancer development and progression are yet to be fully understood. The Warburg effect, or aerobic glycolysis, has been described in a wide array of malignancies and has long been considered as an inefficient mean to fill energetic requirements. Emerging evidence however supports a role that extends beyond that, with glycolytic intermediates diverting to anabolic pathways to allow growth and proliferation. Importantly, the first and most critical rate-limiting step in glycolysis is glucose uptake. Fittingly, high affinity, high capacity glucose transporters such as GLUT1 and to a lesser extent GLUT3, are upregulated in cancer. Given the centrality of glycolysis in tumor biology and reported clinical observations relating to glucose transporter expression patterns, the present work focuses on characterizing the role of GLUT1 and GLUT3 in the context of non-small cell lung cancer (NSCLC), the most prevalent histological subtype of lung cancer. Linking glucose metabolism and a program involved in early steps of metastasis, part of the findings uncovers an aberrant expression of GLUT3 as integral to the epithelial-mesenchymal transition (EMT) in NSCLC. Indeed, a unique association between GLUT3 and a mesenchymal status is observed in a panel of human NSCLC cell lines. Furthermore, GLUT3 expression is increased during EMT by a mechanism that involves direct binding of EMT mediating transcription factor ZEB1 to the GLUT3 (SLC2A3) gene. Data also supports a functional role of GLUT3 in proliferation, as inhibiting GLUT3 expression reduces glucose import and proliferation of mesenchymal lung tumor cells, whereas ectopic expression in epithelial cells sustains proliferation in low glucose. In an analysis of a large microarray data collection of human NSCLC samples, GLUT3 expression is found to correlate with EMT markers, and is prognostic of poor overall survival. Taken collectively, the data reveal an important role for GLUT3 in lung cancer, when tumor cells loose their epithelial characteristics to become more invasive. Owing to the restricted expression of this transporter in healthy individuals, its presence in lung tumor cells may represent a noteworthy prospect for targeted therapy. The contrastingly ubiquitous nature of GLUT1 in normal and transformed tissue warrants in vivo investigation to determine expression patterns and contribution tumor development. To that end, generation of autochthonous lung cancer mouse models allows assessment of the effect of tumor exclusive GLUT1 loss. Ensuing preliminary results allude to a possible role of GLUT1 in specific histological lesions. The significance of this specificity is currently under investigation.

EPFL2015

New optical tools for non-invasive imaging and quantification of glucose and nicotinamide riboside in living cells and animals

Aleksandra Konovalova

Glucose is one of the most important metabolites that plays a key role in living organisms, as it is the primary energy source. Glucose metabolism is also an integral part in the pathogenesis of diabetes and cancer. Despite this tremendous impact of glucose, there are no tools for imaging of glucose uptake non-invasively and in a real-time manner working in both living cells and animals without utilization of hazardous radiation and suitable for convenient preclinical use. The first part of this thesis is describing the development of a probe for imaging glucose uptake based on a highly sensitive and versatile bioluminescence technique. We set a goal to design a probe, which should be reliable, robust, easy to use and simply represent the glucose uptake in both living cells and animals. In addition the synthesis of the probe should be straightforward and high-yielding. This part of the thesis is composed of two projects utilizing different approaches to the probe design and probeâs mechanism of action. The first project was based on the Staudinger Ligation for imaging of glucose uptake by modifying the glucose molecule with an azide moiety and using luciferin caged with a reactive phosphine as a counter-partner for the assay. The second project describes the development of a cleavable disulfide glucose-conjugate probe. For the first project we aimed to synthesize a library of glucose pro bioluminescent probes, validate them in a cell-free and cell-based assay and identify the hit compound. Then we proved the GLUT-specificity of the uptake of our hit compound in living cells and animals. The robust and reproducible assay method for measurement of glucose uptake was established. The probe was applied for imaging of antidiabetic drugsâ influence on glucose uptake. We have also demonstrated its superior properties over 2-NBDG that is currently the most used probe in preclinical research. However, the probe utilized in the second project namely cleavable disulfide glucose conjugate probe was not so sensitive as glucose-azide. Nevertheless, we showed a successful application of this probe for imaging of glucose uptake in living cells and animals. The second part of this thesis describes the design and evaluation of the bioluminescent probe for imaging of nicotinamide riboside (NR) uptake. NR is a recently discovered NAD+ precursor that is naturally present in cow's milk. Despite its importance in modern research and a high potential as a new medicine for treatment of various types of diseases, including diabetes, there are no tools to visualize NR uptake in preclinical research. Also, there is a lack of knowledge on where and how NR can be absorbed in mammals. Here we established the Staudinger Ligation-based approach to develop an imaging tool for NR uptake. After the successful synthesis of azido-nicotinamide riboside molecule, we demonstrated its specificity and utility for imaging in living cells and animals. Findings described in this part cover not only the imaging of NR uptake, but also the possibility of existence of specific NR transporter in mammalian cells, which has not been discovered and described yet.

EPFL2016