34 research outputs found
Skeletal muscle ACC2 S212 phosphorylation is not required for the control of fatty acid oxidation during exercise
During submaximal exercise fatty acids are a predominant energy source for muscle contractions. An important regulator of fatty acid oxidation is acetyl‐CoA carboxylase (ACC), which exists as two isoforms (ACC1 and ACC2) with ACC2 predominating in skeletal muscle. Both ACC isoforms regulate malonyl‐CoA production, an allosteric inhibitor of carnitine palmitoyltransferase 1 (CPT‐1); the primary enzyme controlling fatty acyl‐CoA flux into mitochondria for oxidation. AMP‐activated protein kinase (AMPK) is a sensor of cellular energy status that is activated during exercise or by pharmacological agents such as metformin and AICAR. In resting muscle the activation of AMPK with AICAR leads to increased phosphorylation of ACC (S79 on ACC1 and S221 on ACC2), which reduces ACC activity and malonyl‐CoA; effects associated with increased fatty acid oxidation. However, whether this pathway is vital for regulating skeletal muscle fatty acid oxidation during conditions of increased metabolic flux such as exercise/muscle contractions remains unknown. To examine this we characterized mice lacking AMPK phosphorylation sites on ACC2 (S212 in mice/S221 in humans‐ACC2‐knock‐in [ACC2‐KI]) or both ACC1 (S79) and ACC2 (S212) (ACC double knock‐in [ACCD‐KI]) during submaximal treadmill exercise and/or ex vivo muscle contractions. We find that surprisingly, ACC2‐KI mice had normal exercise capacity and whole‐body fatty acid oxidation during treadmill running despite elevated muscle ACC2 activity and malonyl‐CoA. Similar results were observed in ACCD‐KI mice. Fatty acid oxidation was also maintained in muscles from ACC2‐KI mice contracted ex vivo. These findings indicate that pathways independent of ACC phosphorylation are important for regulating skeletal muscle fatty acid oxidation during exercise/muscle contractions
Thienopyridone Drugs Are Selective Activators of AMP-Activated Protein Kinase β1-Containing Complexes
SummaryThe AMP-activated protein kinase (AMPK) is an αβγ heterotrimer that plays a pivotal role in regulating cellular and whole-body metabolism. Activation of AMPK reverses many of the metabolic defects associated with obesity and type 2 diabetes, and therefore AMPK is considered a promising target for drugs to treat these diseases. Recently, the thienopyridone A769662 has been reported to directly activate AMPK by an unexpected mechanism. Here we show that A769662 activates AMPK by a mechanism involving the β subunit carbohydrate-binding module and residues from the γ subunit but not the AMP-binding sites. Furthermore, A769662 exclusively activates AMPK heterotrimers containing the β1 subunit. Our findings highlight the regulatory role played by the β subunit in modulating AMPK activity and the possibility of developing isoform specific therapeutic activators of this important metabolic regulator
The outcome of renal ischemia-reperfusion injury is unchanged in AMPK-β1 deficient mice
AIM: Activation of the master energy-regulator AMP-activated protein kinase (AMPK) in the heart reduces the severity of ischemia-reperfusion injury (IRI) but the role of AMPK in renal IRI is not known. The aim of this study was to determine whether activation of AMPK by acute renal ischemia influences the severity of renal IRI. METHODS: AMPK expression and activation and the severity of renal IRI was studied in mice lacking the AMPK β1 subunit and compared to wild type (WT) mice. RESULTS: Basal expression of activated AMPK, phosphorylayed at αThr¹⁷², was markedly reduced by 96% in AMPK-β1⁻/⁻ mice. Acute renal ischaemia caused a 3.2-fold increase in α1-AMPK activity and a 2.5-fold increase in α2-AMPK activity (P<0.001) that was associated with an increase in AMPK phosphorylation of the AMPK-α subunit at Thr¹⁷² and Ser⁴⁸⁵, and increased inhibitory phosphorylation of the AMPK substrate acetyl-CoA carboxylase. After acute renal ischemia AMPK activity was reduced by 66% in AMPK-β1⁻/⁻ mice compared with WT. There was no difference, however, in the severity of renal IRI at 24-hours between AMPK-β1⁻/⁻ and WT mice, as measured by serum urea and creatinine and histological injury score. In the heart, macrophage migration inhibitory factor (MIF) released during IRI contributes to AMPK activation and protects from injury. In the kidney, however, no difference in AMPK activation by acute ischemia was observed between MIF⁻/⁻ and WT mice. Compared with the heart, expression of the MIF receptor CD74 was found to be reduced in the kidney. CONCLUSION: The failure of AMPK activation to influence the outcome of IRI in the kidney contrasts with what is reported in the heart. This difference might be due to a lack of effect of MIF on AMPK activation and lower CD74 expression in the kidney
Remodeling of Purinergic Receptor-Mediated Ca2+ Signaling as a Consequence of EGF-Induced Epithelial-Mesenchymal Transition in Breast Cancer Cells
Background The microenvironment plays a pivotal role in tumor cell proliferation, survival and migration. Invasive cancer cells face a new set of environmental challenges as they breach the basement membrane and colonize distant organs during the process of metastasis. Phenotypic switching, such as that which occurs during epithelial-mesenchymal transition (EMT), may be associated with a remodeling of cell surface receptors and thus altered responses to signals from the tumor microenvironment. Methodology/Principal Findings We assessed changes in intracellular Ca 2+ in cells loaded with Fluo-4 AM using a fluorometric imaging plate reader (FLIPR TETRA) and observed significant changes in the potency of ATP (EC 50 0.175 μM (-EGF) versus 1.731 μM (+EGF), P<0.05), and the nature of the ATP-induced Ca 2+ transient, corresponding with a 10-fold increase in the mesenchymal marker vimentin (P<0.05). We observed no change in the sensitivity to PAR2-mediated Ca 2+ signaling, indicating that these alterations are not simply a consequence of changes in global Ca 2+ homeostasis. To determine whether changes in ATP-mediated Ca 2+ signaling are preceded by alterations in the transcriptional profile of purinergic receptors, we analyzed the expression of a panel of P2X ionotropic and P2Y metabotropic purinergic receptors using real-time RT-PCR and found significant and specific alterations in the suite of ATP-activated purinergic receptors during EGF-induced EMT in breast cancer cells. Our studies are the first to show that P2X 5 ionotropic receptors are enriched in the mesenchymal phenotype and that silencing of P2X 5 leads to a significant reduction (25%, P<0.05) in EGF-induced vimentin protein expression. Conclusions The acquisition of a new suite of cell surface purinergic receptors is a feature of EGF-mediated EMT in MDA-MB-468 breast cancer cells. Such changes may impart advantageous phenotypic traits and represent a novel mechanism for the targeting of cancer metastasis
Dual Functions of ASCIZ in the DNA Base Damage Response and Pulmonary Organogenesis
Zn2+-finger proteins comprise one of the largest protein superfamilies with diverse biological functions. The ATM substrate Chk2-interacting Zn2+-finger protein (ASCIZ; also known as ATMIN and ZNF822) was originally linked to functions in the DNA base damage response and has also been proposed to be an essential cofactor of the ATM kinase. Here we show that absence of ASCIZ leads to p53-independent late-embryonic lethality in mice. Asciz-deficient primary fibroblasts exhibit increased sensitivity to DNA base damaging agents MMS and H2O2, but Asciz deletion or knock-down does not affect ATM levels and activation in mouse, chicken, or human cells. Unexpectedly, Asciz-deficient embryos also exhibit severe respiratory tract defects with complete pulmonary agenesis and severe tracheal atresia. Nkx2.1-expressing respiratory precursors are still specified in the absence of ASCIZ, but fail to segregate properly within the ventral foregut, and as a consequence lung buds never form and separation of the trachea from the oesophagus stalls early. Comparison of phenotypes suggests that ASCIZ functions between Wnt2-2b/ß-catenin and FGF10/FGF-receptor 2b signaling pathways in the mesodermal/endodermal crosstalk regulating early respiratory development. We also find that ASCIZ can activate expression of reporter genes via its SQ/TQ-cluster domain in vitro, suggesting that it may exert its developmental functions as a transcription factor. Altogether, the data indicate that, in addition to its role in the DNA base damage response, ASCIZ has separate developmental functions as an essential regulator of respiratory organogenesis
Mutations in the Gal83 Glycogen-Binding Domain Activate the Snf1/Gal83 Kinase Pathway by a Glycogen-Independent Mechanism
The yeast Snf1 kinase and its mammalian ortholog, AMP-activated protein kinase (AMPK), regulate responses to metabolic stress. Previous studies identified a glycogen-binding domain in the AMPK β1 subunit, and the sequence is conserved in the Snf1 kinase β subunits Gal83 and Sip2. Here we use genetic analysis to assess the role of this domain in vivo. Alteration of Gal83 at residues that are important for glycogen binding of AMPK β1 abolished glycogen binding in vitro and caused diverse phenotypes in vivo. Various Snf1/Gal83-dependent processes were upregulated, including glycogen accumulation, expression of RNAs encoding glycogen synthase, haploid invasive growth, the transcriptional activator function of Sip4, and activation of the carbon source-responsive promoter element. Moreover, the glycogen-binding domain mutations conferred transcriptional regulatory phenotypes even in the absence of glycogen, as determined by analysis of a mutant strain lacking glycogen synthase. Thus, mutation of the glycogen-binding domain of Gal83 positively affects Snf1/Gal83 kinase function by a mechanism that is independent of glycogen binding
Discovery of microRNAs associated with breast cancer EMT using bioinformatics and next-generation sequencing
Abstract B093: Breast cancer is the most common malignancy among women worldwide, with mortality often associated with distant metastasis. In recent years, microRNAs (miRs) have emerged as a new class of regulatory molecules that act as tumor suppressors or oncogenes and are capable of affecting metastatic processes such as epithelial-to-mesenchymal transition (EMT) and mesenchymal-to-epithelial transition (MET). Our study aimed to identify miRs associated with breast cancer EMT through miR profiling of EMT in PMC42 (ET vs LA, -/+ EGF) and MDA-MB-468 (control vs EGF, hypoxia) human breast cancer cells using microarray and Next Generation Sequencing (miR-Seq). Several miRs were reproducibly different between the untreated cells, as well as up- or down-regulated in response to epidermal growth factor (EGF). Expression levels of 36 miRs were validated in six breast cancer cell lines comprising a range of epithelial to mesenchymal cell lines. Nine miRs were then selected and the effects of manipulating these miRs were investigated in vitro and in vivo. MDA-MB-468 cells stably overexpressing (OE) the miRs of interest were produced, validated and tested for changes in in vitro migratory potential using a monolayer wound healing assay on the Cellomics platform. We found that the rate of wound closure was significantly faster (p<0.05) in MDA-MB-468 breast cancer cells OE miR-34b/c upon EGF induction even though there were no significant differences in migrative potential using Transwell migration assay. Although these cells showed no proliferative differences, MDA-MB-468 miR-34b/c OE cells showed decreased clonogenicity (p<0.01) compared to control cells. We extended this by looking at these manipulated cells in the MDA-MB-468 xenograft model of in vivo EMT. Our data suggests that there might be a slightly slower rate of primary tumor growth and an inhibition of lymph node metastasis in vivo. Other groups have also identified miR-34 family as a p53 target gene regulating Snail1-driven EMT (Kim et al., 2011) and have shown miR-34 to suppress breast cancer metastasis by targeting Fra-1 (Yang et al., 2012). Fra-1 and several other MEK pathway components were upregulated in the PMC42 and MDA-MB-468 EMT as determined by corresponding RNA-Seq analysis, and integrative analysis of the miR-Seq and RNA-Seq data is ongoing. Our work on EMT-associated miRs is targeted to provide a better understanding of miRs for their potential uses in diagnostic and therapeutic approaches to breast cancer
Intrasteric control of AMPK via the γ1 subunit AMP allosteric regulatory site
AMP-activated protein kinase (AMPK) is a αβγ heterotrimer that is activated in response to both hormones and intracellular metabolic stress signals. AMPK is regulated by phosphorylation on the α subunit and by AMP allosteric control previously thought to be mediated by both α and γ subunits. Here we present evidence that adjacent γ subunit pairs of CBS repeat sequences (after Cystathionine Beta Synthase) form an AMP binding site related to, but distinct from the classical AMP binding site in phosphorylase, that can also bind ATP. The AMP binding site of the γ1 CBS1/CBS2 pair, modeled on the structures of the CBS sequences present in the inosine monophosphate dehydrogenase crystal structure, contains three arginine residues 70, 152, and 171 and His151. The yeast γ homolog, snf4 contains a His151Gly substitution, and when this is introduced into γ1, AMP allosteric control is substantially lost and explains why the yeast snf1p/snf4p complex is insensitive to AMP. Arg70 in γ1 corresponds to the site of mutation in human γ2 and pig γ3 genes previously identified to cause an unusual cardiac phenotype and glycogen storage disease, respectively. Mutation of any of AMP binding site Arg residues to Gln substantially abolishes AMP allosteric control in expressed AMPK holoenzyme. The Arg/Gln mutations also suppress the previously described inhibitory properties of ATP and render the enzyme constitutively active. We propose that ATP acts as an intrasteric inhibitor by bridging the α and γ subunits and that AMP functions to derepress AMPK activity