Increased protein glycation in fructosamine 3-kinase-deficient mice.

Amines, including those present on proteins, spontaneously react with glucose to form fructosamines in a reaction known as glycation. In the present paper, we have explored, through a targeted gene inactivation approach, the role of FN3K (fructosamine 3-kinase), an intracellular enzyme that phosphorylates free and protein-bound fructose-epsilon-lysines and which is potentially involved in protein repair. Fn3k-/- mice looked healthy and had normal blood glucose and serum fructosamine levels. However, their level of haemoglobin-bound fructosamines was approx. 2.5-fold higher than that of control (Fn3k+/+) or Fn3k+/- mice. Other intracellular proteins were also significantly more glycated in Fn3k-/- mice in erythrocytes (1.8-2.2-fold) and in brain, kidney, liver and skeletal muscle (1.2-1.8-fold), indicating that FN3K removes fructosamines from intracellular proteins in vivo. The urinary excretion of free fructose-epsilon-lysine was 10-20-fold higher in fed mice compared with mice starved for 36 h, and did not differ between fed Fn3k+/+ and Fn3k-/- mice, indicating that food is the main source of urinary fructose-epsilon-lysine in these mice and that FN3K does not participate in the metabolism of food-derived fructose-epsilon-lysine. However, in starved animals, the urinary excretion of fructose-epsilon-lysine was 2.5-fold higher in Fn3k-/- mice compared with Fn3k+/+ or Fn3k+/- mice. Furthermore, a marked increase (5-13-fold) was observed in the concentration of free fructose-epsilon-lysine in tissues of fed Fn3k-/- mice compared with control mice, indicating that FN3K participates in the metabolism of endogenously produced fructose-epsilon-lysine. Taken together, these data indicate that FN3K serves as a protein repair enzyme and also in the metabolism of endogenously produced free fructose-epsilon-lysine.

[1]  D. Vertommen,et al.  Variability in erythrocyte fructosamine 3-kinase activity in humans correlates with polymorphisms in the FN3K gene and impacts on haemoglobin glycation at specific sites. , 2006, Diabetes & metabolism.

[2]  B. Szwergold,et al.  Some Clues as to the Regulation, Expression, Function, and Distribution of Fructosamine‐3‐Kinase and Fructosamine‐3‐Kinase‐Related Protein , 2005, Annals of the New York Academy of Sciences.

[3]  F. Opperdoes,et al.  Tissue Distribution and Evolution of Fructosamine 3-Kinase and Fructosamine 3-Kinase-related Protein* , 2004, Journal of Biological Chemistry.

[4]  D. Vertommen,et al.  Identification of Fructosamine Residues Deglycated by Fructosamine-3-kinase in Human Hemoglobin* , 2004, Journal of Biological Chemistry.

[5]  F. Collard,et al.  A mammalian protein homologous to fructosamine-3-kinase is a ketosamine-3-kinase acting on psicosamines and ribulosamines but not on fructosamines. , 2003, Diabetes.

[6]  Steven Clarke,et al.  Aging as war between chemical and biochemical processes: Protein methylation and the recognition of age-damaged proteins for repair , 2003, Ageing Research Reviews.

[7]  F. Collard,et al.  Identification of a Pathway for the Utilization of the Amadori Product Fructoselysine in Escherichia coli * , 2002, The Journal of Biological Chemistry.

[8]  F. Collard,et al.  Fructosamine 3-kinase is involved in an intracellular deglycation pathway in human erythrocytes. , 2002, The Biochemical journal.

[9]  Paul J Thornalley,et al.  Assay of advanced glycation endproducts (AGEs): surveying AGEs by chromatographic assay with derivatization by 6-aminoquinolyl-N-hydroxysuccinimidyl-carbamate and application to Nepsilon-carboxymethyl-lysine- and Nepsilon-(1-carboxyethyl)lysine-modified albumin. , 2002, The Biochemical journal.

[10]  P. Finot,et al.  Nutritional and metabolic consequences of the early Maillard reaction of heat treated milk in the pig , 2002, European journal of nutrition.

[11]  E. Stadtman,et al.  Methionine sulfoxide reductase (MsrA) is a regulator of antioxidant defense and lifespan in mammals , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[12]  B. Szwergold,et al.  Human fructosamine-3-kinase: purification, sequencing, substrate specificity, and evidence of activity in vivo. , 2001, Diabetes.

[13]  E. Schaftingen,et al.  Identification, cloning, and heterologous expression of a mammalian fructosamine-3-kinase. , 2000, Diabetes.

[14]  G. Fischer,et al.  Enzymes that catalyse the restructuring of proteins. , 2000, Current opinion in structural biology.

[15]  S. Young,et al.  Phenotypic Analysis of Seizure-prone Mice Lacking l-Isoaspartate (d-Aspartate)O-Methyltransferase* , 1999, The Journal of Biological Chemistry.

[16]  D. Ferrington,et al.  Repair of oxidized calmodulin by methionine sulfoxide reductase restores ability to activate the plasma membrane Ca-ATPase. , 1999, Biochemistry.

[17]  S. Young,et al.  Deficiency of a protein-repair enzyme results in the accumulation of altered proteins, retardation of growth, and fatal seizures in mice. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[18]  G. Gould,et al.  The glucose transporter family: structure, function and tissue-specific expression. , 1993, The Biochemical journal.

[19]  N. Ahmed,et al.  Glycation and diabetic complications. , 1991, JPMA. The Journal of the Pakistan Medical Association.

[20]  R. Bronson,et al.  Neonatal lethality and lymphopenia in mice with a homozygous disruption of the c-abl proto-oncogene , 1991, Cell.

[21]  J. Baker,et al.  Use of protein-based standards in automated colorimetric determinations of fructosamine in serum. , 1985, Clinical chemistry.

[22]  A. Cerami,et al.  Nonenzymatic glycosylation and the pathogenesis of diabetic complications. , 1984, Annals of internal medicine.

[23]  R. E. Perry,et al.  Application of affinity chromatography for separation and quantitation of glycosylated hemoglobins. , 1983, The Journal of laboratory and clinical medicine.

[24]  R Shapiro,et al.  Sites of nonenzymatic glycosylation of human hemoglobin A. , 1980, The Journal of biological chemistry.

[25]  H. Nakatsuji,et al.  Utilization in Rats of 14C-L-Lysine-labeled Casein Browned by Amino-carbonyl Reaction , 1977 .

[26]  M. M. Bradford A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. , 1976, Analytical biochemistry.

[27]  D. Drabkin,et al.  SPECTROPHOTOMETRIC STUDIES II. PREPARATIONS FROM WASHED BLOOD CELLS; NITRIC OXIDE HEMOGLOBIN AND SULFHEMOGLOBIN , 1935 .

[28]  Received , 1868, Buffalo medical and surgical journal.

[29]  H. Erbersdobler,et al.  Balance Experiments on Human Volunteers with ε-Fructoselysine (FL) and Lysinoalanine (LAL) , 2005 .

[30]  J. Baynes,et al.  The Amadori product on protein: structure and reactions. , 1989, Progress in clinical and biological research.

[31]  H. Erbersdobler,et al.  Transport and metabolism studies with fructose amino acids. , 1981, Progress in food & nutrition science.

[32]  P. Finot,et al.  Metabolic transit of early and advanced Maillard products. , 1981, Progress in food & nutrition science.

[33]  J. Hodge,et al.  The Amadori rearrangement. , 1955, Advances in carbohydrate chemistry.