Your search keyword '"Veiga-da-Cunha, Maria"' showing total 16 results

1. Identification of the cDNA encoding human 6-phosphogluconolactonase, the enzyme catalyzing the second step of the pentose phosphate pathway

Author

Collard, François, Collet, Jean-François, Gerin, Isabelle, Veiga-da-Cunha, Maria, and Van Schaftingen, Emile

Published

1999

2. Glucokinase regulatory protein is essential for the proper subcellular localisation of liver glucokinase

Author

de la Iglesia, Núria, Veiga-da-Cunha, Maria, Van Schaftingen, Emile, Guinovart, Joan J., and Ferrer, Juan C.

Published

1999

3. Characterization of mammalian sedoheptulokinase and mechanism of formation of erythritol in sedoheptulokinase deficiency

Author

Kardon, Tamas, Stroobant, Vincent, Veiga-da-Cunha, Maria, and Schaftingen, Emile Van

Published

2008

4. Metabolite Proofreading in Carnosine and Homocarnosine Synthesis.

Author

Veiga-da-Cunha, Maria, Chevalier, Nathalie, Stroobant, Vincent, Vertommen, Didier, and Van Schaftingen, Emile

Subjects

*CARNOSINE, *ADENOSINE triphosphate, *SKELETAL muscle, *ENZYMES, *ARGININE, *HISTIDINE

Abstract

Carnosine synthase is the ATP-dependent ligase responsible for carnosine (β-alanyl-histidine) and homocarnosine (Υ-aminobutyryl- histidine) synthesis in skeletal muscle and brain, respectively. This enzyme uses, also at substantial rates, lysine, ornithine, and arginine instead of histidine, yet the resulting dipeptides are virtually absent from muscle or brain, suggesting that they are removed by a "metabolite repair" enzyme. Using a radiolabeled substrate, we found that rat skeletal muscle, heart, and brain contained a cytosolic β-alanyl-lysine dipeptidase activity. This enzyme, which has the characteristics of a metalloenzyme, was purified ≈200-fold from rat skeletal muscle. Mass spectrometry analysis of the fractions obtained at different purification stages indicated parallel enrichment of PM20D2, a peptidase of unknown function belonging to the metallopeptidase 20 family. Western blotting showed coelution of PM20D2 with β-alanyl-lysine dipeptidase activity. Recombinant mouse PM20D2 hydrolyzed β-alanyl-lysine, β-alanyl-ornithine, Υ-aminobutyryl-lysine, and Υ-aminobutyryl-ornithine as its best substrates. It also acted at lower rates on β-alanyl-arginine and Υ-aminobutyryl-arginine but virtually not on carnosine or homocarnosine. Although acting preferentially on basic dipeptides derived from β-alanine or Υ-aminobutyrate, PM20D2 also acted at lower rates on some "classic dipeptides" like β-alanyl-lysine and α-lysyl-lysine. The same activity profile was observed with human PM20D2, yet this enzyme was ~ 100-200-fold less active on all substrates tested than the mouse enzyme. Cotransfection in HEK293T cells of mouse or human PM20D2 together with carnosine synthase prevented the accumulation of abnormal dipeptides (β-alanyl-lysine, β-alanyl-ornithine, Υ-aminobutyryl-lysine), thus favoring the synthesis of carnosine and homocarnosine and confirming the metabolite repair role of PM20D2. [ABSTRACT FROM AUTHOR]

Published

2014

5. Molecular Identification of Hydroxylysine Kinase and of Ammoniophospholyases Acting on 5-Phosphohydroxy-L-lysine and Phosphoethanolamine.

Author

Veiga-Da-Cunha, Maria, Hadi, Farah, Balligand, Thomas, Stroobant, Vincent, and Van Schaftingen, Emile

Subjects

*VITAMIN B6, *ENZYMES, *GENOMES, *PROTEINS, *PHOSPHORYLASES

Abstract

The purpose of the present work was to identify the catalytic activity of AGXT2L1 and AGXT2L2, two closely related, putative pyridoxal-phosphate-dependent enzymes encoded by vertebrate genomes. The existence of bacterial homologues (40- 50% identity with AGXT2L1 and AGXT2L2) forming bi- or trifunctional proteins with a putative kinase belonging to the family of aminoglycoside phosphotransferases suggested that AGXT2L1 and AGXT2L2 acted on phosphorylated and aminated compounds. Vertebrate genomes were found to encode a homologue (AGPHD1) of these putative bacterial kinases, which was therefore likely to phosphorylate an amino compound bearing a hydroxyl group. These and other considerations led us to hypothesize that AGPHD1 corresponded to 5-hydroxy-L-lysine kinase and that AGXT2L1 and AGXT2L2 catalyzed the pyridoxal-phosphate-dependent breakdown of phosphoethanolamine and 5-phosphohydroxy-L-lysine. The three recombinant human proteins were produced and purified to homogeneity. AGPHD1 was indeed found to catalyze the GTP-dependent phosphorylation of 5-hydroxy-L-lysine. The phosphorylation product made by this enzyme was metabolized by AGXT2L2, which converted it to ammonia, inorganic phosphate, and 2-aminoadipate semialdehyde. AGXT2L1 catalyzed a similar reaction on phosphoethanolamine, converting it to ammonia, inorganic phosphate, and acetaldehyde. AGPHD1 and AGXT2L2 are likely to be the mutated enzymes in 5-hydroxylysinuria and 5-phosphohydroxylysinuria, respectively. The high level of expression of AGXT2L1 in human brain, as well as data in the literature linking AGXT2L1 to schizophrenia and bipolar disorders, suggest that these diseases may involve a perturbation of brain phosphoethanolamine metabolism. AGXT2L1 and AGXT2L2, the first ammoniophospholyases to be identified, belong to a family of aminotransferases acting on ω-amines. [ABSTRACT FROM AUTHOR]

Published

2012

6. Molecular Identification of NAT8 as the Enzyme That Acetylates Cysteine S-Conjugates to Mercapturic Acid.

Author

Veiga-da-Cunha, Maria, Tyteca, Donatienne, Stroobant, Vincent, Courtoy, Pierre J., Opperdoes, Fred R., and Van Schaftingen, Emile

Subjects

*ACETYLTRANSFERASES, *ENZYMES, *BRAIN, *CELLS, *CYSTEINE proteinases, *AMINO acids, *ENDOPLASMIC reticulum

Abstract

Our goal was to identify the reaction catalyzed by NAT8 (N-acetyltransferase 8), a putative N-acetyltransferase homologous to the enzyme (NAT8L) that produces N-acetylaspartate in brain. The almost exclusive expression of NAT8 in kidney and liver and its predicted association with the endoplasmic reticulum suggested that it was cysteinyl-S-conjugate N-acetyltransferase, the microsomal enzyme that catalyzes the last step of mercapturic acid formation. In agreement, HEK293T extracts of cells overexpressing NAT8 catalyzed the N-acetylation of S-benzyl-L-cysteine and leukotriene E4, two cysteine conjugates, but were inactive on other physiological amines or amino acids. Confocal microscopy indicated that NAT8 was associated with the eudoplasmic reticulum. Neither of the two frequent single nucleotide polymorphisms found in NAT8, E104K nor F143S, changed the enzymatic activity or the expression of the protein by ≥-fold, whereas a mutation (R149K) replacing an extremely conserved arginine suppressed the activity. Sequencing of genomic DNA and EST clones corresponding to the NATSB gene, which resulted from duplication of the NAT8 gene in the primate lineage, disclosed the systematic presence of a premature stop codon at codon 16. Furthermore, truncated NAT8B and NAT8 proteins starting from the following methionine (Met-25) showed no cysteinyl-S-conjugate N-acetyltransferase activity when transfected in HEK293T cells. Taken together, these findings indicate that NAT8 is involved in mercapturic acid formation and confirm that NAT8B is an inactive gene in humans. NAT8 homologues are found in all vertebrate genomes, where they are often encoded by multiple, tandemly repeated genes as many other genes encoding xenobiotic metabolism enzymes. [ABSTRACT FROM AUTHOR]

Published

2010

7. Molecular Identification of Carnosine Synthase as AlP-grasp Domain-containing Protein 1 (ATPGD1).

Author

Drozak, Jakub, Veiga-da-Cunha, Maria, Vertommen, Didier, Stroobant, Vincent, and Van Schaftingent, Emile

Subjects

*CARNOSINE, *VERTEBRATES, *PYROPHOSPHATES, *MASS spectrometry, *POLYPEPTIDES, *PECTORALIS muscle

Abstract

Carnosine (β-alanyl-L-histidine) and homocarnosine (γ-aminobutyryl-L-histidine) are abundant dipeptides in skeletal muscle and brain of most vertebrates and some invertebrates. The formation of both compounds is catalyzed by carnosine synthase, which is thought to convert ATP to AMP and inorganic pyrophosphate, and whose molecular identity is unknown. In the present work, we have purified carnosine synthase from chicken pectoral muscle about 1500-fold until only two major polypeptides of 100 and 90 kDa were present in the preparation. Mass spectrometry analysis of these polypeptides did not yield any meaningful candidate. Carnosine formation catalyzed by the purified enzyme was accompanied by a stoichiometric formation, not of AMP, but of ADP, suggesting that carnosine synthase belongs to the "ATP-grasp family" of ligases. A data base mining approach identified ATPGD1 as a likely candidate. As this protein was absent from chicken protein data bases, we reconstituted its sequence from a PCR-amplified cDNA and found it to fit with the 100-kDa polypeptide of the chicken carnosine synthase preparation. Mouse and human ATPGD1 were expressed in HEK293T cells, purified to homogeneity, and shown to catalyze the formation of carnosine, as confirmed by mass spectrometry, and of homocarnosine. Specificity studies carried out on all three enzymes were in agreement with published data. In particular, they acted with 15-25-fold higher catalytic efficiencies on β-alanine than on γ-aminobutyrate. The identification of the gene encoding carnosine synthase will help for a better understanding of the biological functions of carnosine and related dipeptides, which still remain largely unknown. [ABSTRACT FROM AUTHOR]

Published

2010

8. Molecular identification of ω-amidase, the enzyme that is functionally coupled with glutamine transaminases, as the putative tumor suppressor Nit2

Author

Jaisson, Stéphane, Veiga-da-Cunha, Maria, and Van Schaftingen, Emile

Subjects

*AMIDASES, *ENZYMES, *GLUTAMINE, *AMINOTRANSFERASES, *TUMOR suppressor genes, *GENETIC code, *BACILLUS subtilis genetics, *AMIDES

Abstract

Abstract: Our purpose was to identify the sequence of ω-amidase, which hydrolyses the amide group of α-ketoglutaramate, a product formed by glutamine transaminases. In the Bacillus subtilis genome, the gene encoding a glutamine transaminase (mtnV) is flanked by a gene encoding a putative ‘carbon-nitrogen hydrolase’. The closest mammalian homolog of this putative bacterial ω-amidase is ‘nitrilase 2’, whose size and amino acid composition were in good agreement with those reported for purified rat liver ω-amidase. Mouse nitrilase 2 was expressed in Escherichia coli, purified and shown to catalyse the hydrolysis of α-ketoglutaramate and other known substrates of ω-amidase. No such activity was observed with mouse nitrilase 1. We conclude that mammalian nitrilase 2 is ω-amidase. [Copyright &y& Elsevier]

Published

2009

9. Mammalian Phosphomannomutase PMM1 Is the Brain IMP-sensitive Glucose-1,6-bisphosphatase.

Author

Veiga-da-Cunha, Maria, Vleugels, Wendy, Maliekal, Pushpa, Matthijs, Gert, and van Schaftingen, Emile

Subjects

*GLUCOSE, *ENZYMES, *GENE transfection, *NUCLEIC acids, *GENETIC transformation, *BRAIN

Abstract

Glucose 1,6-bisphosphate (Glc-1,6-P2) concentration in brain is much higher than what is required for the functioning of phosphoglucomutase, suggesting that this compound has a role other than as a cofactor of phosphomutases. In cell-free systems, Glc-1,6-P2 is formed from 1,3-bisphosphoglycerate and Glc-6-P by two related enzymes: PGM2L1 (phosphoglucomutase 2-like 1) and, to a lesser extent, PGM2 (phosphoglucomutase 2). It is hydrolyzed by the IMP-stimulated brain Glc-1,6-bisphosphatase of still unknown identity. Our aim was to test whether Glc-1,6-bisphosphatase corresponds to the phosphomannomutase PMM1,an enzyme of mysterious physiological function sharing several properties with Glc-1,6-bisphosphatase. We show that IMP, but not other nucleotides, stimulated by >100-fold (Ka ≈ 20 μM) the intrinsic Glc-1,6-bisphosphatase activity of recombinant PMM1 while inhibiting its phosphoglucomutase activity. No such effects were observed with PMM2, an enzyme paralogous to PMM1 that physiologically acts as a phosphomannomutase in mammals. Transfection of HEK293T cells with PGM2L1, but not the related enzyme PGM2, caused an ≈20-fold increase in the concentration of Glc-1,6-P2. Transfection with PMM1 caused a profound decrease (>5-fold) in Glc-1,6-P2 in cells that were or were not cotransfected with PGM2L1. Furthermore, the concentration of Glc-1,6-P2 in wild type mouse brain decreased with time after ischemia, whereas it did not change in PMM1-deficient mouse brain. Taken together, these data show that PMM1 corresponds to the IMP-stimulated Glc-1,6-bisphosphatase and that this enzyme is responsible for the degradation of Glc-1,6-P2 in brain. In addition, the role of PGM2L1 as the enzyme responsible for the synthesis of the elevated concentrations of Glc-1,6-P2 in brain is established. [ABSTRACT FROM AUTHOR]

Published

2008

10. Metabolite Repair Enzymes Control Metabolic Damage in Glycolysis.

Author

Bommer, Guido T., Van Schaftingen, Emile, and Veiga-da-Cunha, Maria

Subjects

*METABOLIC regulation, *ENZYMES, *GLYCOLYSIS, *ENZYME specificity, *EXERGONIC reactions

Abstract

Hundreds of metabolic enzymes work together smoothly in a cell. These enzymes are highly specific. Nevertheless, under physiological conditions, many perform side-reactions at low rates, producing potentially toxic side-products. An increasing number of metabolite repair enzymes are being discovered that serve to eliminate these noncanonical metabolites. Some of these enzymes are extraordinarily conserved, and their deficiency can lead to diseases in humans or embryonic lethality in mice, indicating their central role in cellular metabolism. We discuss how metabolite repair enzymes eliminate glycolytic side-products and prevent negative interference within and beyond this core metabolic pathway. Extrapolating from the number of metabolite repair enzymes involved in glycolysis, hundreds more likely remain to be discovered that protect a wide range of metabolic pathways. Many noncanonical metabolites are produced under physiological conditions by side-activities of enzymes and by spontaneous reactions. Many of these noncanonical metabolites are repaired or reconverted to useful metabolites by metabolite repair enzymes. A single repair enzyme may catalyze several repair reactions. Metabolite repair reactions are sometimes catalyzed by a side-activity of a canonical enzyme (i.e., FBP1/2, PGK). Major pathways may require multiple metabolite repair enzymes. In the case of glycolysis, 10 canonical glycolytic enzymes are assisted by 10 repair enzymes (G6PC3, PGP, ACYP1, NAXD, NAXE, L2HGDH, GLO1, GLO2, FN3K, MDP-1) and a transporter (G6PT). Deficiencies in several of the metabolite repair enzymes can cause disease in humans or are lethal in higher vertebrates. [ABSTRACT FROM AUTHOR]

Published

2020

11. Sequence of a putative glucose 6-phosphate translocase, mutated in glycogen storage disease type Ib

Author

Gerin, Isabelle, Veiga-da-Cunha, Maria, Achouri, Younes, Collet, Jean-François, and Van Schaftingen, Emile

Published

1997

12. The metalloprotein YhcH is an anomerase providing N-acetylneuraminate aldolase with the open form of its substrate.

Author

Kentache, Takfarinas, Thabault, Leopold, Deumer, Gladys, Haufroid, Vincent, Frédérick, Raphaël, Linster, Carole L., Peracchi, Alessio, Veiga-da-Cunha, Maria, Bommer, Guido T., and Van Schaftingen, Emile

Subjects

*METALLOPROTEINS, *TRANSITION metals, *OPERONS, *GLYCANS, *ESCHERICHIA coli, *ENERGY consumption

Abstract

N-acetylneuraminate (Neu5Ac), an abundant sugar present in glycans in vertebrates and some bacteria, can be used as an energy source by several prokaryotes, including Escherichia coli. In solution, more than 99% of Neu5Ac is in cyclic form (-92% beta-anomer and -7% alpha-anomer), whereas <0.5% is in the open form. The aldolase that initiates Neu5Ac metabolism in E. coli, NanA, has been reported to act on the alphaanomer. Surprisingly, when we performed this reaction at pH 6 to minimize spontaneous anomerization, we found NanA and its human homolog NPL preferentially metabolize the open form of this substrate. We tested whether the E. coli Neu5Ac anomerase NanM could promote turnover, finding it stimulated the utilization of both beta and alpha-anomers by NanA in vitro. However, NanM is localized in the periplasmic space and cannot facilitate Neu5Ac metabolism by NanA in the cytoplasm in vivo. We discovered that YhcH, a cytoplasmic protein encoded by many Neu5Ac catabolic operons and belonging to a protein family of unknown function (DUF386), also facilitated Neu5Ac utilization by NanA and NPL and displayed Neu5Ac anomerase activity in vitro. YhcH contains Zn, and its accelerating effect on the aldolase reaction was inhibited by metal chelators. Remarkably, several transition metals accelerated Neu5Ac anomerization in the absence of enzyme. Experiments with E. coli mutants indicated that YhcH expression provides a selective advantage for growth on Neu5Ac. In conclusion, YhcH plays the unprecedented role of providing an aldolase with the preferred unstable open form of its substrate. [ABSTRACT FROM AUTHOR]

Published

2021

13. Ethylmalonyl-CoA Decarboxylase, a New Enzyme Involved in Metabolite Proofreading.

Author

Linster, Carole L., Noël, Gaëtane, Stroobant, Vincent, Vertommen, Didier, Vincent, Marie-Françoise, Bommer, Guido T., Veiga-da-Cunha, Maria, and Van Schaftingen, Emile

Subjects

*DECARBOXYLASES, *DNA, *LIPID metabolism, *BACTERIAL genetics, *ESCHERICHIA coli, *ADIPOSE tissue physiology, *LIVER, *KIDNEYS, *LABORATORY mice

Abstract

A limited number of enzymes are known that play a role analogous to DNA proofreading by eliminating non-classical metabolites formed by side activities of enzymes of intermediary metabolism. Because few such "metabolite proofreading enzymes" are known, our purpose was to search for an enzyme able to degrade ethylmalonyl-CoA, a potentially toxic metabolite formed at a low rate from butyryl-CoA by acetyl-CoA carboxylase and propionyl-CoA carboxylase, two major enzymes of lipid metabolism. We show that mammalian tissues contain a previously unknown enzyme that decarboxylates ethylmalonyl-CoA and, at lower rates, methylmalonyl-CoA but that does not act on malonyl-CoA. Ethylmalonyl-CoA decarboxylase is particularly abundant in brown adipose tissue, liver, and kidney in mice, and is essentially cytosolic. Because Escherichia coli methylmalonyl-CoA decarboxylase belongs to the family of enoyl-CoA hydratase (ECH), we searched mammalian databases for proteins of uncharacterized function belonging to the ECH family. Combining this database search approach with sequencing data obtained on a partially purified enzyme preparation, we identified ethylmalonyl-CoA decarboxylase as ECHDC1. We confirmed this identification by showing that recombinant mouse ECHDC1 has a substantial ethylmalonyl-CoA decarboxylase activity and a lower methylmalonyl-CoA decarboxylase activity but no malonyl-CoA decarboxylase or enoyl-CoA hydratase activity. Furthermore, ECHDC1-specific siRNAs decreased the ethylmalonyl-CoA decarboxylase activity in human cells and increased the formation of ethylmalonate, most particularly in cells incubated with butyrate. These findings indicate that ethylmalonyl-CoA decarboxylase may correct a side activity of acetyl-CoA carboxylase and suggest that its mutation may be involved in the development of certain forms of ethylmalonic aciduria. [ABSTRACT FROM AUTHOR]

Published

2011

14. Molecular Identification of Mammalian Phosphopentomutase and Glucose-1,6-bisphosphate Synthase, Two Members of the α-D-Phosphohexomutase Family.

Author

Maliekal, Pushpa, Sokolova, Tatiana, Vertommen, Didier, Veiga-da-Cunha, Maria, and Van Schaftingen, Emile

Subjects

*GLUCOSE, *ESCHERICHIA coli, *GLYCOLYSIS, *MASS spectrometry, *DEOXYRIBOSE, *BLOOD testing, *BIOCHEMICAL research

Abstract

The molecular identity of mammalian phosphopentomutase has not yet been established unequivocally. That of glucose-1,6-bisphosphate synthase, the enzyme that synthesizes a cofactor for phosphomutases and putative regulator of glycolysis, is completely unknown. In the present work, we have purified phosphopentomutase from human erythrocytes and found it to copurify with a 68-kDa polypeptide that was identified by mass spectrometry as phosphoglucomutase 2 (PGM2), a protein of the α-D-phosphohexomutase family and sharing about 20% identity with mammalian phosphoglucomutase 1. Data base searches indicated that vertebrate genomes contained, in addition to PGM2, a homologue (PGM2L1, for PGM2-like 1) sharing about 60% sequence identity with this protein. Both PGM2 and PGM2L1 were overexpressed in Escherichia coli, purified, and their properties were studied. Using catalytic efficiency as a criterion, PGM2 acted more than 10-fold better as a phosphopentomutase (both on deoxyribose 1-phosphate and on ribose 1-phosphate) than as a phosphoglucomutase. PGM2L1 showed only low (<5%) phosphopentomutase and phosphoglucomutase activities compared with PGM2, but was about 5–20-fold better than the latter enzyme in catalyzing the 1,3-bisphosphoglycerate-dependent synthesis of glucose 1,6-bisphosphate and other aldose-bisphosphates. Furthermore, quantitative real-time PCR analysis indicated that PGM2L1 was mainly expressed in brain where glucose-1,6-bisphosphate synthase activity was previously shown to be particularly high. We conclude that mammalian phosphopentomutase and glucose-1,6-bisphosphate synthase correspond to two closely related proteins, PGM2 and PGM2L1, encoded by two genes that separated early in vertebrate evolution. [ABSTRACT FROM AUTHOR]

Published

2007

15. Fructosamine 3-kinase and other enzymes involved in protein deglycation

Author

Van Schaftingen, Emile, Delpierre, Ghislain, Collard, François, Fortpied, Juliette, Gemayel, Rita, Wiame, Elsa, and Veiga-da-Cunha, Maria

Published

2007

16. Insights into the Structure and Regulation of Glucokinase from a Novel Mutation (V62M), Which Causes Maturity-onset Diabetes of the Young.

Author

Glyn, Anna L., Odili, Stella, Zelent, Dorothy, Buettger, Carol, Castleden, Harriet A. J., Steele, Anna M., Stride, Amanda, Shiota, Chyio, Magnuson, Mark A., Lorini, Renata, d'Annunzio, Giuseppe, Stanley, Charles A., Kwagh, Jae, van Schaftingen, Emile, Veiga-da-Cunha, Maria, Barbetti, Fabrizio, Dunten, Pete, Yi Han, Grimsby, Joseph, and Taub, Rebecca

Subjects

*GENETIC mutation, *DIABETES, *BLOOD sugar, *HYPERGLYCEMIA, *ENDOCRINE diseases, *GLUCOSE, *SUCROSE, *CARBOHYDRATE intolerance, *ENZYMES, *LIVER cells, *PANCREATIC diseases, *AMINO acids

Abstract

Glucokinase (GCK) serves as the pancreatic glucose sensor. Heterozygous inactivating GCK mutations cause hyperglycemia, whereas activating mutations cause hypoglycemia. We studied the GCK V62M mutation identified in two families and co-segregating with hyperglycemia to understand how this mutation resulted in reduced function. Structural modeling locates the mutation close to five naturally occurring activating mutations in the allosteric activator site of the enzyme. Recombinant gintathionyl S-transferase.V62M GCK is paradoxically activated rather than inactivated due to a decreased S0.5 for glucose compared with wild type (4.88 versus 7.55 mM). The recently described pharmacological activator (RO0281675) interacts with GCK at this site. V62M GCK does not respond to RO0281675, nor does it respond to the hepatic glucokinase regulatory protein (GKRP). The enzyme is also thermally unstable, but this lability is apparently less pronounced than in the proven instability mutant E300K. Functional and structural analysis of seven amino acid substitutions at residue Val62 has identified a non-linear relationship between activation by the pharmacological activator and the van der Waals interactions energies. Smaller energies allow a hydrophobic interaction between the activator and glucokinase, whereas larger energies prohibit the ligand from fitting into the binding pocket. We conclude that V62M may cause hyperglycemia by a complex defect of GCK regulation involving instability in combination with loss of control by a putative endogenous activator and/or GKRP. This study illustrates that mutations that cause hyperglycemia are not necessarily kinetically inactivating but may exert their effects by other complex mechanisms. Elucidating such mechanisms leads to a deeper understanding of the GCK glucose sensor and the biochemistry of β-cells and hepatocytes. [ABSTRACT FROM AUTHOR]

Published

2005