Metabolic disorder | EPFL Graph Search

A metabolic disorder is a disorder that negatively alters the body's processing and distribution of macronutrients, such as proteins, fats, and carbohydrates. Metabolic disorders can happen when abnormal chemical reactions in the body alter the normal metabolic process. It can also be defined as inherited single gene anomaly, most of which are autosomal recessive. Signs and symptoms Some of the symptoms that can occur with metabolic disorders are lethargy, weight loss, jaundice and seizures. The symptoms expressed would vary with the type of metabolic disorder. There are four categories of symptoms: acute symptoms, late-onset acute symptoms, progressive general symptoms and permanent symptoms. Causes Inborn error of metabolism Inherited metabolic disorders are one cause of metabolic disorders, and occur when a defective gene causes an enzyme deficiency. These diseases, of which there are many subtypes, are known as inborn errors of metabolism. Metabolic di

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

Enhanced activation of cellular AMPK by dual-small molecule treatment: AICAR and A769662

Laurent Bultot, Maria Deak, Kei Sakamoto

AMP-activated protein kinase (AMPK) is a key cellular energy sensor and regulator of metabolic homeostasis. Activation of AMPK provides beneficial outcomes in fighting against metabolic disorders such as insulin resistance and type 2 diabetes. Currently, there is no allosteric AMPK activator available for the treatment of metabolic diseases, and limited compounds are available to robustly stimulate cellular/tissue AMPK in a specific manner. Here we investigated whether simultaneous administration of two different pharmacological AMPK activators, which bind and act on different sites, would result in an additive or synergistic effect on AMPK and its downstream signaling and physiological events in intact cells. We observed that cotreating primary hepatocytes with the AMP mimetic 5-aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside (AICAR) and a low dose (1 mu M) of the allosteric activator A769662 produced a synergistic effect on AMPK Thr172 phosphorylation and catalytic activity, which was associated with a more profound increase/decrease in phosphorylation of downstream AMPK targets and inhibition of hepatic lipogenesis compared with single-compound treatment. Mechanistically, we found that co-treatment does not stimulate LKB1, upstream kinase for AMPK, but it protects against dephosphorylation of Thr172 phosphorylation by protein phosphatase PP2C alpha in an additive manner in a cell-free assay. Collectively, we demonstrate that AICAR sensitizes the effect of A769662 and promotes AMPK activity and its downstream events. The study demonstrates the feasibility of promoting AMPK activity by using two activators with distinct modes of action in order to achieve a greater activation of AMPK and downstream signaling.

Amer Physiological Soc2014

Functional analysis of Bicc1 and novel interacting proteins in renal tubule cell metabolism and polycystic kidneys

Lucía Carolina Leal Esteban

Genetic disorders known as ciliopathies develop polycystic kidneys, including autosomal dominant and autosomal recessive polycystic kidney diseases (ADPKD and ARPKD). Several signaling pathways including the cAMP/PKA pathway are implicated in driving cystic growth. However, the mechanisms underlying cysts formation is still elusive. Renal cysts also arise in patients and in mouse models with mutations in the RNA-binding protein Bicaudal-C (Bicc1). Bicc1 binds specific mRNAs such as adenylate cyclase VI (AC6) mRNA for translational repression. Conducting a structure-function analysis, we demonstrated that Bicc1 self-polymerizes through its sterile alpha motif (SAM domain) to form cytoplasmic clusters, which specifically localize and silence bound mRNAs. Altered glucose and lipid metabolism also sustain cystic growth in polycystic kidneys, but the cause of these perturbations is unclear. Here, we found that Bicc1 is essential for normal expression of the gluconeogenic enzymes FBP1 and PEPCK specifically in kidneys, and to maintain euglycemia. In a proteomic interactome screen using a knock-in cell line, we found that TAP-tagged Bicc1 binds the C-Terminal to Lis-Homology domain (CTLH) complex, the mammalian orthologue of the glucose-induced degradation (Gid) complex that triggers degradation of FBP1 in S. cerevisiae. Bicc1 stimulates FBP1 expression in vitro in cultured murine inner medullary collecting duct (mIMCD3) cells, albeit independently of its interaction with the CTLH complex. Instead, Bicc1 and CTLH complex seem to mutually downregulate each other. Bicc1 interactome is also enriched with metabolic related proteins. Here we found that Bicc1 coimmunoprecipitates with rate-limiting metabolic enzymes and contributes to maintain their protein levels, and that deletion of Bicc1 significantly alters the renal metabolome while enhances autophagy. Altogether, these results implicate Bicc1 as an important metabolic regulator in the etiology of polycystic kidneys.

EPFL2017