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Target Concepts:
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Query: UMLS:C0024523 (
malabsorption
)
7,319
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Fructose, a naturally occurring monosaccharide, is increasingly used as an added sweetener in processed foods in the form of high fructose corn syrup. Increased fructose intake combined with the identification of children with clinical evidence of isolated fructose
malabsorption
(IFM) has stimulated interest in possible disorders of fructose absorption. The intestinal absorption of fructose is carried out by the facilitative hexose transporter, which has been designated as
GLUT5
. Functional properties and tissue distribution of
GLUT5
suggest that IFM might be due to mutations in the
GLUT5
gene. To test this hypothesis, we screened the
GLUT5
gene for mutations in a group of eight patients with IFM and in one subject with global
malabsorption
, as compared with 15 healthy parents of subjects and up to 6 unrelated controls. No mutations were found in the protein coding region of this gene in any of the subjects. A single G to A substitution in the 5' untranslated region of exon 1 was identified in the subject with global
malabsorption
. This subject and her healthy mother were heterozygous for the variant sequence, suggesting that it was unlikely to be clinically significant. In addition, sequence analysis of each of the 12
GLUT5
exons was performed in the index case and confirmed the negative single-strand conformation polymorphism findings. These studies demonstrate that IFM does not result from the expression of mutant GLUT5 protein.
...
PMID:Molecular analysis of the fructose transporter gene (GLUT5) in isolated fructose malabsorption. 894 59
Carbohydrates are mostly digested to glucose, fructose and galactose before absorption by the small intestine. Absorption across the brush border and basolateral membranes of enterocytes is mediated by sodium-dependent and -independent membrane proteins. Glucose and galactose transport across the brush border occurs by a Na(+)/glucose (galactose) co-transporter (SGLT1), whereas passive fructose transport is mediated by a uniporter (
GLUT5
). The passive exit of all three sugars out of the cell across the basolateral membrane occurs through two uniporters (GLUT2 and
GLUT5
). Mutations in SGLT1 cause a major defect in glucose and galactose absorption (glucose-galactose
Malabsorption
), but mutations in GLUT2 do not appear to disrupt glucose and galactose absorption. Studies on GLUT1 null mice and Fanconi-Bickel patients suggest that there is another exit pathway for glucose and galactose that may involve exocytosis. There are no known defects of fructose absorption.
...
PMID:Intestinal absorption in health and disease--sugars. 1464 59
Since 1967, fructose has become the primary commercial sweetener in the food industry. Large amounts of fructose can be toxic and have been correlated with atherosclerosis,
malabsorption
, hyperuricemia, lactic acidosis, and cataracts. To understand the deleterious and critical role(s) fructose plays in normal metabolism, it is essential to know how and where fructose is metabolized. The fructose transporter,
GLUT5
, and the specialized enzymes ketohexokinase, aldolase, and triokinase comprise the well-defined fructose-specific metabolic pathway found in liver, kidney, and small intestine. It is estimated that 50-70% of ingested fructose is metabolized in these tissues; where and how the remaining 30-50% is metabolized is not well defined. Prediction of tissues capable of metabolizing fructose via this pathway was done using expressed sequence tags (ESTs) in Unigene and a gene-specific virtual northern blot (VNB) algorithm. Unigene and VNB combined correctly predicted the expression of the genes required for fructose metabolism in liver, kidney, and small intestine. Both methods indicated brain, breast, lymphocytes, muscle, placenta, and stomach additionally express this set of genes. Expression of the genes for
GLUT5
(glut5) and ketohexokinase (khk) in neurons was validated by immunohistochemistry and RNA in situ hybridization, respectively. Using stringent controls, clear expression of glut5 and khk was localized to Purkinje cells in the cerebellum. Cerebellum was used to oxidize fructose to carbon dioxide. Together, these data suggest that these neurons in the brain are able to utilize fructose as a carbon source.
...
PMID:Genes required for fructose metabolism are expressed in Purkinje cells in the cerebellum. 1626 70
Fructose is a hexose sugar that is being increasingly consumed in its monosaccharide form. Patients who exhibit fructose
malabsorption
can present with gastrointestinal symptoms that include chronic diarrhea and abdominal pain. However, with no clearly established gastrointestinal mechanism for fructose
malabsorption
, patient analysis by the proxy of a breath hydrogen test (BHT) is controversial. The major transporter for fructose in intestinal epithelial cells is thought to be the facilitative transporter
GLUT5
. Consistent with a facilitative transport system, we show here by analysis of past studies on healthy adults that there is a significant relationship between fructose
malabsorption
and fructose dose (r = 0.86, P < 0.001). Thus there is a dose-dependent and limited absorption capacity even in healthy individuals. Changes in fructose
malabsorption
with age have been observed in human infants, and this may parallel the developmental regulation of
GLUT5
expression. Moreover, a
GLUT5
knockout mouse has displayed the hallmarks associated with profound fructose
malabsorption
. Fructose
malabsorption
appears to be partially modulated by the amount of glucose ingested. Although solvent drag and passive diffusion have been proposed to explain the effect of glucose on fructose
malabsorption
, this could possibly be a result of the facilitative transporter GLUT2.
GLUT5
and GLUT2 mRNA have been shown to be rapidly upregulated by the presence of fructose and GLUT2 mRNA is also upregulated by glucose, but in humans the distribution and role of GLUT2 in the brush border membrane are yet to be definitively decided. Understanding the relative roles of these transporters in humans will be crucial for establishing a mechanistic basis for fructose
malabsorption
in gastrointestinal patients.
...
PMID:Intestinal fructose transport and malabsorption in humans. 2114 1
Fructose intake has increased dramatically since humans were hunter-gatherers, probably outpacing the capacity of human evolution to make physiologically healthy adaptations. Epidemiological data indicate that this increasing trend continued until recently. Excessive intakes that chronically increase portal and peripheral blood fructose concentrations to >1 and 0.1 mm, respectively, are now associated with numerous diseases and syndromes. The role of the fructose transporters
GLUT5
and GLUT2 in causing, contributing to or exacerbating these diseases is not well known.
GLUT5
expression seems extremely low in neonatal intestines, and limited absorptive capacities for fructose may explain the high incidence of
malabsorption
in infants and cause problems in adults unable to upregulate
GLUT5
levels to match fructose concentrations in the diet.
GLUT5
- and GLUT2-mediated fructose effects on intestinal electrolyte transporters, hepatic uric acid metabolism, as well as renal and cardiomyocyte function, may play a role in fructose-induced hypertension. Likewise, GLUT2 may contribute to the development of non-alcoholic fatty liver disease by facilitating the uptake of fructose. Finally,
GLUT5
may play a role in the atypical growth of certain cancers and fat tissues. We also highlight research areas that should yield information needed to better understand the role of these GLUTs in fructose-induced diseases.
...
PMID:The role of fructose transporters in diseases linked to excessive fructose intake. 2312 94
Fructose
malabsorption
came to prominence in the pediatric arena as so-called "apple juice diarrhea," with excess consumption of fructose being linked to gastrointestinal symptoms such as diarrhea and abdominal pain. Over the past two decades the amount of fructose in children's diets has been increasing in the United States. A test for fructose
malabsorption
has yet to be fully validated, due mainly to the lack of an established etiology. In animal models, however, the fructose transporter
GLUT5
is developmentally regulated, and this could be consistent with the greater susceptibility of children, especially toddlers, to fructose
malabsorption
. Additionally, the available evidence indicates the fructose breath hydrogen test has no apparent diagnostic utility in infants younger than 1 year; it may, therefore, be advisable to test for
malabsorption
by dietary exclusion in these patients. The present review aims to expound on the biological basis for fructose
malabsorption
in children and evaluate the current evidence for diagnostic procedures in order to identify clinical testing strategies that can be recommended and areas where further investigation is required.
...
PMID:Developmental changes and fructose absorption in children: effect on malabsorption testing and dietary management. 2359 Jul 6
Incomplete intestinal absorption of fructose might lead to abdominal complaints such as pain, flatulence and diarrhoea. Whether defect fructose transporters such as
GLUT5
or GLUT2 are involved in the pathogenesis of fructose
malabsorption
is a matter of debate. The hydrogen production by colonic bacteria is used for diagnosis with the hydrogen breath test. However, the appropriate fructose test dose for correct diagnosis is unclear. Subjects with fructose
malabsorption
show increased breath hydrogen levels and abdominal symptoms after fructose administration but do not report any symptoms when fructose is given together with glucose. This beneficial effect of glucose, however, cannot be explained yet but might be used for clinical care of these subjects.
...
PMID:Fructose malabsorption. 2688 54
