Molecular Characterization of Mammalian Dicarbonyl/l-Xylulose Reductase and Its Localization in Kidney

Junichi Nakagawa,Syuhei Ishikura,Jun Asami,Tomoya Isaji,Noriyuki Usami,Akira Hara,Takanobu Sakurai,Katsuki Tsuritani,Koji Oda,Masayoshi Takahashi,Makoto Yoshimoto,Noboru Otsuka,Kunihiro Kitamura

doi:10.1074/jbc.m110703200

Abstract

In this report, we first cloned a cDNA for a protein that is highly expressed in mouse kidney and then isolated its counterparts in human, rat hamster, and guinea pig by polymerase chain reaction-based cloning. The cDNAs of the five species encoded polypeptides of 244 amino acids, which shared more than 85% identity with each other and showed high identity with a human sperm 34-kDa protein, P34H, as well as a murine lung-specific carbonyl reductase of the short-chain dehydrogenase/reductase superfamily. In particular, the human protein is identical to P34H, except for one amino acid substitution. The purified recombinant proteins of the five species were about 100-kDa homotetramers with NADPH-linked reductase activity for alpha-dicarbonyl compounds, catalyzed the oxidoreduction between xylitol and l-xylulose, and were inhibited competitively by n-butyric acid. Therefore, the proteins are designated as dicarbonyl/l-xylulose reductases (DCXRs). The substrate specificity and kinetic constants of DCXRs for dicarbonyl compounds and sugars are similar to those of mammalian diacetyl reductase and l-xylulose reductase, respectively, and the identity of the DCXRs with these two enzymes was demonstrated by their co-purification from hamster and guinea pig livers and by protein sequencing of the hepatic enzymes. Both DCXR and its mRNA are highly expressed in kidney and liver of human and rodent tissues, and the protein was localized primarily to the inner membranes of the proximal renal tubules in murine kidneys. The results imply that P34H and diacetyl reductase (EC ) are identical to l-xylulose reductase (EC ), which is involved in the uronate cycle of glucose metabolism, and the unique localization of the enzyme in kidney suggests that it has a role other than in general carbohydrate metabolism.

Highlights

Carbonyl compounds are routinely generated in the course of metabolic reactions and by oxidative stresses in a variety of biological systems
The cDNAs of the five species encoded polypeptides of 244 amino acids, which shared more than 85% identity with each other and showed high identity with a human sperm 34-kDa protein, P34H, as well as a murine lungspecific carbonyl reductase of the short-chain dehydrogenase/reductase superfamily
The results imply that P34H and diacetyl reductase (EC 1.1.1.5) are identical to Lxylulose reductase (EC 1.1.1.10), which is involved in the uronate cycle of glucose metabolism, and the unique localization of the enzyme in kidney suggests that it has a role other than in general carbohydrate metabolism

Summary

Introduction

Carbonyl compounds are routinely generated in the course of metabolic reactions and by oxidative stresses in a variety of biological systems. The potential relevance of aldose reductase and aldehyde reductase in detoxifying such dicarbonyl compounds has been documented [10, 11]; a question remained of whether there exists one or more reductases working in the renal system Supporting this notion, it is widely noted that renal failure is one of the major causes accounting for the accumulation of AGEs on plasma proteins and tissues, most prominently in the tubules of the nephron [12]. A data base survey of the sequences revealed that one of these candidate clones displayed significant sequence homology with mouse lung carbonyl reductase (MLCR [14]), which is a member of the short-chain dehydrogenase/reductase (SDR) superfamily [15] This inspired us to further investigate its possible involvement in renal carbonyl detoxification.

Methods

Results

Conclusion