Metabolism of the covalent phosphate in glycogen

Indiana University-Purdue University Indianapolis (IUPUI)Glycogen is a highly branched polymer of glucose that functions to store glucose residues for future metabolic use. Skeletal muscle and liver comprise the largest glycogen reserves and play critical roles in maintaining whole body glucose homeostasis. In addition to glucose, glycogen contains small amounts of covalent phosphate of unknown function, origin and structure. Evidence to support the involvement of glycogen associated phosphate in glycogen metabolism comes from patients with Lafora Disease. Lafora disease is an autosomal recessive, fatal form of progressive myoclonus epilepsy. Approximately 90% of cases of Lafora disease are caused by mutations in either the EPM2A or EPM2B genes that encode, respectively, a dual specificity phosphatase called laforin and an E3 ubiquitin ligase called malin. Lafora patients accumulate intracellular inclusion bodies, known as Lafora bodies that are primarily composed of poorly branched, insoluble glycogen-like polymers. We have shown that laforin is a glycogen phosphatase capable of releasing phosphate from glycogen in vitro and that this activity is dependent on a functional carbohydrate binding domain. In studies of laforin knockout mice, we observed a progressive change in the properties and structure of glycogen that paralleled the formation of Lafora bodies. Glycogen isolated from these mice showed increased glycogen phosphate, up to 6-fold (p< 0.001) compared to WT, providing strong evidence that laforin acts as a glycogen phosphatase in vivo. Furthermore we have demonstrated that glycogen synthase introduces phosphate into glycogen during synthesis by transferring the beta-phosphate of UDP-glucose into the polymer and that laforin is capable of releasing the phosphate incorporated by glycogen synthase. Analysis of mammalian glycogen revealed the presence of covalently linked phosphate at the 2 hydroxyl and the 3 hydroxyl of glucose residues in the polysaccharide, providing the first direct evidence of the chemical nature of the phosphate linkage. We envision a glycogen damage/repair process, analogous to errors during DNA synthesis that are subsequently repaired. We propose that laforin action parallels that of DNA repair enzymes and Lafora disease results from the inability of the phosphatase to repair damaged glycogen, adding another biological polymer to the list of those prone to errors by their respective polymerizing enzymes

A secretory kinase complex regulates extracellular protein phosphorylation.

Although numerous extracellular phosphoproteins have been identified, the protein kinases within the secretory pathway have only recently been discovered, and their regulation is virtually unexplored. Fam20C is the physiological Golgi casein kinase, which phosphorylates many secreted proteins and is critical for proper biomineralization. Fam20A, a Fam20C paralog, is essential for enamel formation, but the biochemical function of Fam20A is unknown. Here we show that Fam20A potentiates Fam20C kinase activity and promotes the phosphorylation of enamel matrix proteins in vitro and in cells. Mechanistically, Fam20A is a pseudokinase that forms a functional complex with Fam20C, and this complex enhances extracellular protein phosphorylation within the secretory pathway. Our findings shed light on the molecular mechanism by which Fam20C and Fam20A collaborate to control enamel formation, and provide the first insight into the regulation of secretory pathway phosphorylation

Glycogen and its metabolism: some new developments and old themes

Glycogen is a branched polymer of glucose that acts as a store of energy in times of nutritional sufficiency for utilization in times of need. Its metabolism has been the subject of extensive investigation and much is known about its regulation by hormones such as insulin, glucagon and adrenaline (epinephrine). There has been debate over the relative importance of allosteric compared with covalent control of the key biosynthetic enzyme, glycogen synthase, as well as the relative importance of glucose entry into cells compared with glycogen synthase regulation in determining glycogen accumulation. Significant new developments in eukaryotic glycogen metabolism over the last decade or so include: (i) three-dimensional structures of the biosynthetic enzymes glycogenin and glycogen synthase, with associated implications for mechanism and control; (ii) analyses of several genetically engineered mice with altered glycogen metabolism that shed light on the mechanism of control; (iii) greater appreciation of the spatial aspects of glycogen metabolism, including more focus on the lysosomal degradation of glycogen; and (iv) glycogen phosphorylation and advances in the study of Lafora disease, which is emerging as a glycogen storage disease

Muscle glycogen remodeling and glycogen phosphate metabolism following exhaustive exercise of wild type and laforin knockout mice

Glycogen, the repository of glucose in many cell types, contains small amounts of covalent phosphate, of uncertain function and poorly understood metabolism. Loss-of-function mutations in the laforin gene cause the fatal neurodegenerative disorder, Lafora disease, characterized by increased glycogen phosphorylation and the formation of abnormal deposits of glycogen-like material called Lafora bodies. It is generally accepted that the phosphate is removed by the laforin phosphatase. To study the dynamics of skeletal muscle glycogen phosphorylation in vivo under physiological conditions, mice were subjected to glycogen-depleting exercise and then monitored while they resynthesized glycogen. Depletion of glycogen by exercise was associated with a substantial reduction in total glycogen phosphate and the newly resynthesized glycogen was less branched and less phosphorylated. Branching returned to normal on a time frame of days, whereas phosphorylation remained suppressed over a longer period of time. We observed no change in markers of autophagy. Exercise of 3-month-old laforin knock-out mice caused a similar depletion of glycogen but no loss of glycogen phosphate. Furthermore, remodeling of glycogen to restore the basal branching pattern was delayed in the knock-out animals. From these results, we infer that 1) laforin is responsible for glycogen dephosphorylation during exercise and acts during the cytosolic degradation of glycogen, 2) excess glycogen phosphorylation in the absence of laforin delays the normal remodeling of the branching structure, and 3) the accumulation of glycogen phosphate is a relatively slow process involving multiple cycles of glycogen synthesis-degradation, consistent with the slow onset of the symptoms of Lafora disease

Munc18c phosphorylation by the insulin receptor links cell signaling directly to SNARE exocytosis

SNARE complex assembly and mobilization of GLUT4 vesicles is coordinated through direct targeting of Munc18c by the insulin receptor tyrosine kinase

Geographical and temporal distribution of SARS-CoV-2 clades in the WHO European Region, January to June 2020

We show the distribution of severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) genetic clades over time and between countries and outline potential genomic surveillance objectives. We applied three genomic nomenclature systems to all sequence data from the World Health Organization European Region available until 10 July 2020. We highlight the importance of real-time sequencing and data dissemination in a pandemic situation, compare the nomenclatures and lay a foundation for future European genomic surveillance of SARS-CoV-2

Secreted protein kinases

none3noneVincent S. Tagliabracci;Lorenzo A. Pinna;Jack E. DixonVincent S., Tagliabracci; Pinna, Lorenzo; Jack E., Dixo

The Golgi \u2018casein kinase\u2019 Fam20C is a genuine \u2018phosvitin kinase\u2019 and phosphorylates polyserine stretches devoid of the canonical consensus

Egg yolk phosvitins, generated through the fragmentation of vitellogenins (VTGs), are among the most heavily phosphorylated proteins ever described. Despite the early discovery in 1900 that chicken phosvitin is a phosphoprotein and its subsequent employment as an artificial substrate for a number of protein kinases, the identity of the enzyme(s) responsible for its phosphorylation remained a matter of conjecture until present. Here, we provide evidence that phosvitin phosphorylation is catalyzed by a family with sequence similarity 20, member C (Fam20C), an atypical protein kinase recently identified as the genuine casein kinase and responsible for the phosphorylation of many other secreted proteins at residues specified by the S-x-E/pS consensus. Such a conclusion is grounded on the following observations: (a) the levels of Fam20C and phosphorylated VTG rise in parallel upon treatment of zebrafish with oestrogens; (b) zebrafish phosvitin is readily phosphorylated upon coexpression in U2OS cells with Fam20C, but not with its catalytically inactive mutant; (c) a peptide reproducing a stretch of 12 serines, which are phosphorylated in chicken phosvitin despite lacking the C-terminal priming motif S-x-E, is efficiently phosphorylated by both recombinant and native Fam20C. The last finding expands the repertoire of potential targets of Fam20C to include several proteins known to harbor (p-Ser)n clusters not specified by any known kinase consensus