Structure and alternative splicing of the ketohexokinase gene

Hayward, Bruce E.; Bonthron, David T.

doi:10.1046/j.1432-1327.1998.2570085.x

Cited by 72 publications

(69 citation statements)

References 19 publications

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“…Those high-expressing tissues listed above contain KHK-C mRNA, with little or no KHK-A. In other tissues, KHK-A mRNA is present at low level, but KHK-C cannot be detected (12). There is also a shift from KHK-A to KHK-C in the liver and kidney during fetal development, which correlates with earlier observations that fructokinase activity is very low in fetal liver (16).…”

supporting

confidence: 86%

“…The human KHK gene on chromosome 2p23 has nine exons spanning 14 kb (12). Two exons (referred to as 3a and 3c, each 135 bp long) arose by an intragenic duplication and are mutually exclusively spliced into mRNA.…”

mentioning

confidence: 99%

“…The biochemically well-characterized KHK-C, usually referred to as fructokinase, is encoded by the mRNA that includes exon 3c. It is abundant in liver, renal cortex, and small intestine and also is present in the pancreatic islet (12,13).…”

mentioning

confidence: 99%

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Properties of Normal and Mutant Recombinant Human Ketohexokinases and Implications for the Pathogenesis of Essential Fructosuria

et al. 2003

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Alternative splicing of the ketohexokinase (fructokinase) gene generates a "central" predominantly hepatic isoform (ketohexokinase-C) and a more widely distributed ketohexokinase-A. Only the abundant hepatic isoform is known to possess activity, and no function is defined for the lower levels of ketohexokinase-A in peripheral tissues. Hepatic ketohexokinase deficiency causes the benign disorder essential fructosuria. The molecular basis of this has been defined in one family (compound heterozygosity for mutations Gly40Arg and Ala43Thr). Here we show that both ketohexokinase isoforms are indeed active. Ketohexokinase-A has much poorer substrate affinity than ketohexokinase-C for fructose but is considerably more thermostable. The Gly40Arg mutation seems null, rendering both ketohexokinase-A and ketohexokinase-C inactive and largely insoluble. The Ala43Thr mutant retains activity, but this mutation decreases the thermal stability of both ketohexokinase-A and ketohexokinase-C. At physiologic temperature, this results in significant loss of ketohexokinase-C activity but not of ketohexokinase-A. Affected individuals who carry both mutations therefore probably have a selective deficiency of hepatic ketohexokinase, with peripheral ketohexokinase-A being preserved. These findings raise the possibility that ketohexokinase-A serves an unknown physiologic function that remains intact in essential fructosuria. Further mutation analysis in this rare disorder could illuminate the question of whether ketohexokinase-A activity is, unlike that of ketohexokinase-C, physiologically indispensable.

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Properties of Normal and Mutant Recombinant Human Ketohexokinases and Implications for the Pathogenesis of Essential Fructosuria

et al. 2003

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“…Fructokinase exists in two alternatively spliced isoforms consisting of fructokinase C (KHK-C) and fructokinase A (KHK-A) differing in exon 3 (19,20). KHK-C is expressed primarily in the liver, kidney, and intestines, whereas KHK-A is more ubiquitous (21).…”

mentioning

confidence: 99%

Opposing effects of fructokinase C and A isoforms on fructose-induced metabolic syndrome in mice

Ishimoto

Lanaspa²,

Le³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Fructose intake from added sugars correlates with the epidemic rise in obesity, metabolic syndrome, and nonalcoholic fatty liver disease. Fructose intake also causes features of metabolic syndrome in laboratory animals and humans. The first enzyme in fructose metabolism is fructokinase, which exists as two isoforms, A and C. Here we show that fructose-induced metabolic syndrome is prevented in mice lacking both isoforms but is exacerbated in mice lacking fructokinase A. Fructokinase C is expressed primarily in liver, intestine, and kidney and has high affinity for fructose, resulting in rapid metabolism and marked ATP depletion. In contrast, fructokinase A is widely distributed, has low affinity for fructose, and has less dramatic effects on ATP levels. By reducing the amount of fructose for metabolism in the liver, fructokinase A protects against fructokinase C-mediated metabolic syndrome. These studies provide insights into the mechanisms by which fructose causes obesity and metabolic syndrome.ketohexokinase | hepatic steatosis | insulin | leptin

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“…Due to alternative splicing, the expressions of the isoforms are tissue dependent. While KHKA is expressed at low levels in most tissues, high levels of KHKC are primarily expressed in the liver, kidneys, and small intestine [24,25]. Notably, only recombinant human KHKC, but not KHKA, was capable of rapidly metabolizing fructose and causing acute depletion of hepatic ATP [11].…”

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confidence: 99%

Bioactivity-guided identification of botanical inhibitors of ketohexokinase

Lanaspa

Cicerchi

et al. 2015

Planta Med

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ObjectiveIn developed countries with westernized diets, the excessive consumption of added sugar in beverages and highly refined and processed foods is associated with increased risk for obesity, diabetes, and cardiovascular diseases. As a major constituent of added sugars, fructose has been shown to cause a variety of adverse metabolic effects, such as impaired insulin sensitivity, hypertriglyceridemia, and oxidative stress. Recent studies have shown that ketohexokinase isoform C is the key enzyme responsible in fructose metabolism that drive's fructose's adverse effects. The objective of this study was to identify botanical ingredients with potential for inhibitory activity against ketohexokinase-C and fructose-induced metabolic effects by using a series of in vitro model systems. MethodsExtracts from 406 botanicals and 1200 purified phytochemicals were screened (initial concentration of 50 μg/mL and 50 μM, respectively) for their inhibitory activity using a cell free, recombinant human ketohexokinase-C assay. Dose response evaluations were conducted on botanical extracts and phytochemicals that inhibited ketohexokinase-C by > 30% and > 40%, respectively. Two different extract lots of the top botanical candidates were further evaluated in lysates of HepG2 cells overexpressing ketohexokinase-C for inhibition of fructose-induced ATP depletion. In addition, extracts were evaluated in intact Hep G2 cells for inhibition of fructose-induced elevation of triglyceride and uric acid production. ResultsAmong the botanical extracts, phloretin (Malus domestica) extracts were the most potent (IC 50 : 8.9-9.2 μg/mL) followed by extracts of Angelica archangelica (IC 50: 22.6 μg/mL-57.3 μg/mL). Among the purified phytochemicals, methoxy-isobavachalcone (Psoralea corylifolia, IC 50 = 0.2 μM) exhibited the highest potency against ketohexokinase isoform C Data Availability Statement:We have included all data of the analyses and all information that the University authors have been provided is fully accessible to the reader in the supplemental data. Funding:The study was supported by funding from startup funds of RJJ and research funding from Amway Research and Development that was received by RJJ.Competing Interests: RJJ is on the Scientific Board of Amway and XORT Therapeutics. RJJ is also author of the Sugar Fix (Rodale, 2008) and the Fat Switch (Mercola.com 2012). RJJ, MAL, MTL, and activity followed by osthole (Angelica archangelica, IC 50 = 0.7 μM), cratoxyarborenone E (Cratoxylum prunifolium, IC 50 = 1.0 μM), and α-/γ-mangostin (Cratoxylum prunifolium, IC 50 = 1.5 μM). Extracts of Angelica archangelica, Garcinia mangostana, Petroselinum crispum, and Scutellaria baicalensis exhibited ketohexokinase inhibitory activity and blocked fructose-induced ATP depletion and fructose-induced elevation in triglyerides and uric acid. ConclusionsAngelica archangelica, Garcinia mangostana, Petroselinum crispum, and Scutellaria baicalensis were the top four botanical candidiates identified with inhibitory activity against ketohe...

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Structure and alternative splicing of the ketohexokinase gene

Cited by 72 publications

References 19 publications

Properties of Normal and Mutant Recombinant Human Ketohexokinases and Implications for the Pathogenesis of Essential Fructosuria

Properties of Normal and Mutant Recombinant Human Ketohexokinases and Implications for the Pathogenesis of Essential Fructosuria

Opposing effects of fructokinase C and A isoforms on fructose-induced metabolic syndrome in mice

Bioactivity-guided identification of botanical inhibitors of ketohexokinase

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