Failure to eliminate a phosphorylated glucose analog leads to neutropenia in patients with G6PT and G6PC3 deficiency

Veiga‐da‐Cunha, Maria; Chevalier, Nathalie; Stéphenne, Xavier; Defour, Jean‐Philippe; Paczia, Nicole; Ferster, Alina; Achouri, Younès; Dewulf, Joseph; Linster, Carole L.; Bommer, Guido T.; Schaftingen, Emile Van

doi:10.1073/pnas.1816143116

Cited by 113 publications

(197 citation statements)

References 51 publications

(59 reference statements)

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“…On the contrary, administration of 1,5‐anhydroglucitol to G6PC3‐deficient mice further decreases their neutrophil count. Neutrophils isolated from patients with G6PC3 or G6PT deficiency, show concentrations of 1,5‐anhydroglucitol‐6‐phosphate (≈ 3 mM) that are far above the Ki of hexokinase 3 (the main hexokinase in neutrophils) for this inhibitor, and close to 1000‐fold higher than the concentration found in neutrophils from healthy controls …”

Section: A Metabolite Repair Defect Explains the Neutropenia Found Inmentioning

confidence: 90%

“…Identifying the toxic compound may be very difficult in the absence of ad hoc hypotheses, particularly if this compound is an unknown metabolite. Yet, identifying the exact function of a metabolite repair enzyme in the context of human inborn errors of metabolism may be very useful as it may lead to new therapeutic strategies, as appears to be the case for 1,5‐anhydroglucitol‐6‐phosphate …”

Section: When Is a Metabolite Repair Enzyme Critical?mentioning

confidence: 99%

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Inborn errors of metabolite repair

Veiga‐da‐Cunha

Schaftingen

Bommer

2019

J of Inher Metab Disea

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It is traditionally assumed that enzymes of intermediary metabolism are extremely specific and that this is sufficient to prevent the production of useless and/or toxic side-products. Recent work indicates that this statement is not entirely correct. In reality, enzymes are not strictly specific, they often display weak side activities on intracellular metabolites (substrate promiscuity) that resemble their physiological substrate or slowly catalyse abnormal reactions on their physiological substrate (catalytic promiscuity). They thereby produce non-classical metabolites that are not efficiently metabolised by conventional enzymes. In an increasing number of cases, metabolite repair enzymes are being discovered that serve to eliminate these non-classical metabolites and prevent their accumulation. Metabolite repair enzymes also eliminate non-classical metabolites that are formed through spontaneous (ie, not enzyme-catalysed) reactions. Importantly, genetic deficiencies in several metabolite repair enzymes lead to 'inborn errors of metabolite repair', such as L-2-hydroxyglutaric aciduria, D-2-hydroxyglutaric aciduria, 'ubiquitous glucose-6-phosphatase' (G6PC3) deficiency, the neutropenia present in Glycogen Storage Disease type Ib or defects in the enzymes that repair the hydrated forms of NADH or NADPH. Metabolite repair defects may be difficult to identify as such, because the mutated enzymes are non-classical enzymes that act on nonclassical metabolites, which in some cases accumulate only inside the cells, and at rather low, yet toxic, concentrations. It is therefore likely that many additional metabolite repair enzymes remain to be discovered and that many diseases of metabolite repair still await elucidation. K E Y W O R D S1,5-anhydroglucitol-6-phosphate, D-2-hydroxyglutaric aciduria, enzyme promiscuity, G6PC3, G6PT, galactose, inborn errors of metabolism, metabolite repair, NADP(H)X, neutropenia, PGM1, SGLT2 inhibitor, UGP2Abbreviations: D2HGDH, D-2-hydroxyglutarate dehydrogenase; G6PC3, ubiquitous glucose-6-phosphatase; G6PT, glucose-6-phosphate translocase of the endoplasmic

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Section: A Metabolite Repair Defect Explains the Neutropenia Found Inmentioning

confidence: 90%

Section: When Is a Metabolite Repair Enzyme Critical?mentioning

confidence: 99%

Inborn errors of metabolite repair

Veiga‐da‐Cunha

Schaftingen

Bommer

2019

J of Inher Metab Disea

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“…Neutrophils have been traditionally considered to selectively utilize glycolysis for energy metabolism due to having only a few mitochondria [179]. Extrinsic glucose is taken up into human neutrophils via GLUT1, which is expressed and upregulated in glucose-rich environments [180]. Patients with genetic deficiency in enzymes related to glucose metabolism suffer from neutrophil dysfunctions and neutropenia [20,27,180,181].…”

Section: Neutrophilsmentioning

confidence: 99%

“…Extrinsic glucose is taken up into human neutrophils via GLUT1, which is expressed and upregulated in glucose-rich environments [180]. Patients with genetic deficiency in enzymes related to glucose metabolism suffer from neutrophil dysfunctions and neutropenia [20,27,180,181]. Neutrophils from glycogen storage disease (GSD) patients having glucose-6-phosphate transporter (G6PT) deficiency and manifest dysregulated function of energy homeostasis, ROS production, and chemotaxis, suggesting the importance of glucose metabolism in neutrophils [27].…”

Section: Neutrophilsmentioning

confidence: 99%

Carbohydrate and Amino Acid Metabolism as Hallmarks for Innate Immune Cell Activation and Function

Zhao

Raines

Huang

2020

Cells

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Immune activation is now understood to be fundamentally linked to intrinsic and/or extrinsic metabolic processes which are essential for immune cells to survive, proliferate, and perform their effector functions. Moreover, disruption or dysregulation of these pathways can result in detrimental outcomes and underly a number of pathologies in both communicable and non-communicable diseases. In this review, we discuss how the metabolism of carbohydrates and amino acids in particular can modulate innate immunity and how perturbations in these pathways can result in failure of these immune cells to properly function or induce unfavorable phenotypes.

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“…Enzymes can also occasionally catalyze an unintended reaction on a physiological substrate (i.e., catalytic promiscuity) [6,7]. Both substrate and catalytic promiscuities result in the formation of ‘unintended’, ‘noncanonical’, or ‘damaged’ metabolites (i.e., metabolite damage) that can be a useless drain on metabolism [8] and may be inhibitory [9], and/or reactive [10,11], sometimes leading to toxicity. In addition to enzyme promiscuity, spontaneous chemical reactions can occur to cellular metabolites causing metabolite damage [12].…”

Section: Introductionmentioning

confidence: 99%

Enzyme promiscuity, metabolite damage, and metabolite damage control systems of the tricarboxylic acid cycle

Niehaus

Hillmann

2020

The FEBS Journal

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Promiscuous enzymes and spontaneous chemical reactions can convert normal cellular metabolites into noncanonical or damaged metabolites. These damaged metabolites can be a useless drain on metabolism and may be inhibitory and/or reactive, sometimes leading to toxicity. Thus, mechanisms to prevent metabolite damage from occurring (metabolite damage preemption) or to convert damaged metabolites back to physiological forms (metabolite repair) are essential for sustained operation of metabolic networks. Some iconic examples of metabolite damage and its repair or preemption are associated with the tricarboxylic acid (TCA) cycle, and other metabolite damage control systems are likely to exist here due to the inherent promiscuity of TCA cycle enzymes and reactivity of TCA cycle intermediates. Here, we review known metabolite damage reactions and metabolite damage control systems associated with the TCA cycle. This includes a previously unrecognized metabolite damage control system – an oxaloacetate (OAA) enol‐keto tautomerase activity that is ‘built‐in’ to the TCA cycle. This activity is required to remove the highly inhibitory enol form of OAA and is likely to be critical for TCA cycle operation. By cataloging these instances, we show that metabolite damage and its repair or preemption is a prevalent feature of the TCA cycle and suggest many more metabolite damage control systems are likely to exist.

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Failure to eliminate a phosphorylated glucose analog leads to neutropenia in patients with G6PT and G6PC3 deficiency

Cited by 113 publications

References 51 publications

Inborn errors of metabolite repair

Inborn errors of metabolite repair

Carbohydrate and Amino Acid Metabolism as Hallmarks for Innate Immune Cell Activation and Function

Enzyme promiscuity, metabolite damage, and metabolite damage control systems of the tricarboxylic acid cycle

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