<scp>NAD</scp>(P)<scp>HX</scp> repair deficiency causes central metabolic perturbations in yeast and human cells

Becker-Kettern, Julia; Paczia, Nicole; Conrotte, Jean-François; Zhu, Chenchen; Fiehn, Oliver; Jung, Paul P.; Steinmetz, Lars M.; Linster, Carole L.

doi:10.1111/febs.14631

Cited by 32 publications

(38 citation statements)

References 63 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Breaches of specificity in metabolic enzymes, and in particular the central ones, can be highly deleterious. The identification of repair enzymes that catabolize the resulting damage metabolites provides some indications about the nature of the potential competing substrates [5][6][7][8][9]. However, in the majority of cases, the potential threat substrates remain unknown.…”

Section: Introductionmentioning

confidence: 99%

How evolution shapes enzyme selectivity – lessons from aminoacyl‐tRNA synthetases and other amino acid utilizing enzymes

Tawfik

Gruić-Sovulj

2020

The FEBS Journal

View full text Add to dashboard Cite

Aminoacyl‐tRNA synthetases (AARSs) charge tRNA with their cognate amino acids. Many other enzymes use amino acids as substrates, yet discrimination against noncognate amino acids that threaten the accuracy of protein translation is a hallmark of AARSs. Comparing AARSs to these other enzymes allowed us to recognize patterns in molecular recognition and strategies used by evolution for exercising selectivity. Overall, AARSs are 2–3 orders of magnitude more selective than most other amino acid utilizing enzymes. AARSs also reveal the physicochemical limits of molecular discrimination. For example, amino acids smaller by a single methyl moiety present a discrimination ceiling of ~200, while larger ones can be discriminated by up to 105‐fold. In contrast, substrates larger by a hydroxyl group challenge AARS selectivity, due to promiscuous H‐bonding with polar active site groups. This ‘hydroxyl paradox’ is resolved by editing. Indeed, when the physicochemical discrimination limits are reached, post‐transfer editing – hydrolysis of tRNAs charged with noncognate amino acids, evolved. The editing site often selectively recognizes the edited noncognate substrate using the very same feature that the synthetic site could not efficiently discriminate against. Finally, the comparison to other enzymes also reveals that the selectivity of AARSs is an explicitly evolved trait, showing some clear examples of how selection acted not only to optimize catalytic efficiency with the target substrate, but also to abolish activity with noncognate threat substrates (‘negative selection’).

show abstract

Section: Introductionmentioning

confidence: 99%

How evolution shapes enzyme selectivity – lessons from aminoacyl‐tRNA synthetases and other amino acid utilizing enzymes

Tawfik

Gruić-Sovulj

2020

The FEBS Journal

View full text Add to dashboard Cite

show abstract

“…Glyceraldehyde 3‐phosphate dehydrogenase (GAPDH) catalyzes the conversion of NADH to NADHX, but no analogous enzymatic transformation of NADPH has yet been reported. Discovery of an enzymatic equivalent of the acid‐catalyzed degradation of NADPH might have biological significance . Knowing the enzymes other than GAPDH that could play a role in the formation of NAD(P)HX is therefore important.…”

Section: Methodsmentioning

confidence: 99%

Unexpected NADPH Hydratase Activity in the Nitrile Reductase QueF from Escherichia coli

et al. 2020

View full text Add to dashboard Cite

Scheme1.Proposed mechanism of reduction of preQ 0 into preQ 1 ,catalyzed by the nitrile reductase QueF.The active-site dyadCys and Asp act together in covalentcatalysis. Reduction of the thioimidate enzyme adduct occurs in two NADPH-dependent stepsv ia an iminei ntermediate (not shown).Scheme2.Reactionpathways leadingtoN ADPH degradation in spontaneous and enzyme-promoted conversions.The uncoupled pathway (NADPH conversion not leading to NADP + )i nvolves hydration of NADPH to NADPHX followed by epimerization/cyclization, leading to O2'-b-6-cyclo-1,4,5,6-tetrahydronicotinamideadenine dinucleotidephosphate [(cTHN)TPN]. The enzymatic reaction identified in this study is markedb yt he box. The coupled pathway (NADPH conversion leadingt oN ADP + )entailsformation of NADP + through knowno xidationr eactionso fN ADPH: whenO 2 is present, for example.

show abstract

“…In this disease, fever may not only result in a favoured unfolding of mutated enzymes, but also in enhancing the rate of formation of NAD(P)HX. The details of the pathophysiological mechanisms are still unknown, but both enzymes deficiencies lead to the accumulation of NADHX in cells and to perturbations in mitochondrial respiration …”

Section: Deficiency In Two Super‐conserved Repair Enzymes Leads To a mentioning

confidence: 99%

Inborn errors of metabolite repair

Veiga‐da‐Cunha

Schaftingen

Bommer

2019

J of Inher Metab Disea

View full text Add to dashboard Cite

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

show abstract

NAD(P)HX repair deficiency causes central metabolic perturbations in yeast and human cells

Cited by 32 publications

References 63 publications

How evolution shapes enzyme selectivity – lessons from aminoacyl‐tRNA synthetases and other amino acid utilizing enzymes

How evolution shapes enzyme selectivity – lessons from aminoacyl‐tRNA synthetases and other amino acid utilizing enzymes

Unexpected NADPH Hydratase Activity in the Nitrile Reductase QueF from Escherichia coli

Inborn errors of metabolite repair

Contact Info

Product

Resources

About