Counteracting Roles of AMP Deaminase and AMP Kinase in the Development of Fatty Liver

Lanaspa, Miguel A.; Cicerchi, Christina; García, Gabriela; Li, Nanxing; Roncal-Jiménez, Carlos A.; Rivard, Christopher J.; Hunter, Brandi; Andrés-Hernando, Ana; Ishimoto, Takuji; Sánchez‐Lozada, Laura G.; Thomas, Jeffrey; Hodges, Robert S.; Mant, Colin T.; Johnson, Richard J.

doi:10.1371/journal.pone.0048801

Cited by 162 publications

(165 citation statements)

References 43 publications

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“…S4) showed a tendency to have greater levels of phosphorylated AMP kinase, and its target protein ACC, in response to fructose compared with control cells. These results are consistent with earlier work showing that uric acid is an inhibitor of AMP kinase (26). These results also demonstrate that triglyceride accumulation is correlated with the enzymatic efficiency of uricases and that, whereas ancient uricases are capable of managing uric acid levels in our assay conditions, more derived versions such as recombinant human uricase are not able to manage uric acid.…”

Section: Resultssupporting

confidence: 93%

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Evolutionary history and metabolic insights of ancient mammalian uricases

Kratzer

Lanaspa

Murphy

et al. 2014

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

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252

249

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Uricase is an enzyme involved in purine catabolism and is found in all three domains of life. Curiously, uricase is not functional in some organisms despite its role in converting highly insoluble uric acid into 5-hydroxyisourate. Of particular interest is the observation that apes, including humans, cannot oxidize uric acid, and it appears that multiple, independent evolutionary events led to the silencing or pseudogenization of the uricase gene in ancestral apes. Various arguments have been made to suggest why natural selection would allow the accumulation of uric acid despite the physiological consequences of crystallized monosodium urate acutely causing liver/kidney damage or chronically causing gout. We have applied evolutionary models to understand the history of primate uricases by resurrecting ancestral mammalian intermediates before the pseudogenization events of this gene family. Resurrected proteins reveal that ancestral uricases have steadily decreased in activity since the last common ancestor of mammals gave rise to descendent primate lineages. We were also able to determine the 3D distribution of amino acid replacements as they accumulated during evolutionary history by crystallizing a mammalian uricase protein.Further, ancient and modern uricases were stably transfected into HepG2 liver cells to test one hypothesis that uricase pseudogenization allowed ancient frugivorous apes to rapidly convert fructose into fat. Finally, pharmacokinetics of an ancient uricase injected in rodents suggest that our integrated approach provides the foundation for an evolutionarily-engineered enzyme capable of treating gout and preventing tumor lysis syndrome in human patients.hyperuricemia | pseudogene | evolution

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Section: Resultssupporting

confidence: 93%

“…Transduction and generation of stable clones expressing uricases was performed as previously described (26). The coding sequences of the various uricases were inserted into the pLVXIRES Puro vector by direct cloning using EcoRI and NotI sites.…”

Section: Discussionmentioning

confidence: 99%

Evolutionary history and metabolic insights of ancient mammalian uricases

Kratzer

Lanaspa

Murphy

et al. 2014

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

Self Cite

252

249

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“…108-112 Stimulation of this pathway results in inhibition of AMP kinase while at the same time inducing mitochondrial oxidative stress and intracellular uric acid generation, resulting in both fat accumulation (from stimulation of fat synthesis and blockade of fatty acid oxidation) and increased gluconeogenesis. [109][110][111][112] The ability of fructose to cause obesity is not simply from its caloric value but rather from its capacity to induce leptin resistance (thereby blocking satiety responses) while at the same time reducing ATP production by blocking fat oxidation. 109,[113][114][115] Laboratory animals fed fructose develop features of metabolic syndrome and, if prone, will even develop diabetes.…”

Section: The Rise In Intake Of Added Sugars and Their Effect On Africmentioning

confidence: 99%

“…[109][110][111][112] The ability of fructose to cause obesity is not simply from its caloric value but rather from its capacity to induce leptin resistance (thereby blocking satiety responses) while at the same time reducing ATP production by blocking fat oxidation. 109,[113][114][115] Laboratory animals fed fructose develop features of metabolic syndrome and, if prone, will even develop diabetes. 116,117 Features of metabolic syndrome can be induced even with caloric restriction provided the sugar (or fructose) content is high, 116 demonstrating that it is not overnutrition but rather the presence of fructose that is responsible for the development of metabolic syndrome.…”

Section: The Rise In Intake Of Added Sugars and Their Effect On Africmentioning

confidence: 99%

“…Indeed, recent studies suggest that humans may be more sensitive to the effects of fructose than most mammals because uric acid mediates some of the metabolic features. [109][110][111] Humans have higher uric acid levels than most mammals as a result of a mutation in uricase, 125 an enzyme that degrades uric acid. When uricase is inhibited in rats, even small concentrations of fructose-containing sugars can induce features of metabolic syndrome.…”

Section: The Rise In Intake Of Added Sugars and Their Effect On Africmentioning

confidence: 99%

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New Insights on the Risk for Cardiovascular Disease in African Americans

Saab

Kendrick

Yracheta

et al. 2015

Journal of the American Society of Nephrology

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African Americans are at increased risk for cardiovascular and metabolic diseases, including obesity, high BP, diabetes, CKD, myocardial infarction, and stroke. Here we summarize the current risks and provide an overview of the underlying risk factors that may account for these associations. By reviewing the relationship between cardiovascular and renal diseases and the African-American population during the early 20th century, the historic and recent associations of African heritage with cardiovascular disease, and modern population genetics, it is possible to assemble strong hypotheses for the primary underlying mechanisms driving the increased frequency of disease in African Americans. Our studies suggest that underlying genetic mechanisms may be responsible for the increased frequency of high BP and kidney disease in African Americans, with particular emphasis on the role of APOL1 polymorphisms in causing kidney disease. In contrast, the Western diet, particularly the relatively high intake of fructose-containing sugars and sweetened beverages, appears to be the dominant force driving the increased risk of diabetes, obesity, and downstream complications. Given that intake of added sugars is a remediable risk factor, we recommend clinical trials to examine the reduction of sweetened beverages as a primary means for reducing cardiovascular risk in African Americans.

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Quinoa (Chenopodium quinoa Willd.) supplemented cafeteria diet ameliorates glucose intolerance in rats

Ozcaliskan Ilkay,

Karabulut,

Kamaci Ozocak

et al. 2023

Food Science & Nutrition

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Quinoa (Chenopodium quinoa Willd.) is a pseudocereal with rich nutritional composition, gluten free, and organoleptic. The primary aim of this study was to elucidate the possible protective roles of quinoa in glucose homeostasis in a model of cafeteria diet‐induced obesity. Male Wistar rats (3 weeks of age) were randomly allocated to be fed by; control chow (CON; n = 6), quinoa (QUI; n = 6), cafeteria (CAF; n = 6), or quinoa and cafeteria (CAFQ; n = 6) for 15 weeks. CAFQ resulted in decreased saturated fat, sugar, and sodium intake in comparison with CAF. Compared to CON, CAF increased body weight gain, plasma insulin, plasma glucose, decreased liver IRS‐1, AMPK mRNA expressions, and pancreatic β‐cell insulin immunoreactivity, and developed hepatocyte degeneration and microvesicular steatosis. Compared to CAF, QUI lowered body weight, plasma glucose, and plasma insulin, increased liver IRS‐1 and AMPK mRNA expressions, and pancreatic β‐cell insulin immunoreactivity. Compared to CAF, CAFQ lowered plasma glucose, increased liver IRS‐1 mRNA expressions, increased pancreatic β‐cell insulin immunoreactivity, and lowered hepatocyte degeneration and microvesicular steatosis. Dietary treatments did not influence IRS‐2, AKT2, and INSR mRNA expressions. HOMA‐IR, HOMA‐β, and QUICKI were also similar between groups. Restoration of insulin in CAFQ islets was as well as that of CON and QUI groups. In conclusion, as a functional food, quinoa may be useful in the prevention of obesity and associated metabolic outcomes such as glucose intolerance, disrupted pancreatic β‐cell function, hepatic insulin resistance, and lipid accumulation.

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Counteracting Roles of AMP Deaminase and AMP Kinase in the Development of Fatty Liver

Cited by 162 publications

References 43 publications

Evolutionary history and metabolic insights of ancient mammalian uricases

Evolutionary history and metabolic insights of ancient mammalian uricases

New Insights on the Risk for Cardiovascular Disease in African Americans

Quinoa (Chenopodium quinoa Willd.) supplemented cafeteria diet ameliorates glucose intolerance in rats

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