Mechanisms of renal ammonia production and protein turnover

Garibotto, Giacomo; Verzola, Daniela; Asioli, Sofia; Saffioti, Stefano; Menesi, Fadya; Vigo, Emanuela; Tarroni, Alice; Gandolfo, Maria Teresa

doi:10.1007/s11011-008-9121-6

Cited by 12 publications

(9 citation statements)

References 35 publications

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“…However, acute changes in acid–base balance alters renal metabolism of ammonia. The percentage of total renal ammonia excreted in urine can increase from 50 to 70% with acute acidosis and be as low as 18% in alkalosis (reviewed in (40)). In the post‐absorptive state in certain animal species (e.g.…”

Section: Interorgan Ammonia and Amino Acid Metabolismmentioning

confidence: 99%

Interorgan ammonia metabolism in liver failure: the basis of current and future therapies

Wright

Noiret

Damink

et al. 2011

Liver International

133

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Hepatic encephalopathy complicates the course of both acute and chronic liver disease and its treatment remains an unmet clinical need. Ammonia is thought to be central in its pathogenesis and remains an important target of current and future therapeutic approaches. In liver failure, the main detoxification pathway of ammonia metabolism is compromised leading to hyperammonaemia. In this situation, the other ammonia-regulating pathways in multiple organs assume important significance. The present review focuses upon interorgan ammonia metabolism in health and disease describing the role of the key enzymes, glutamine synthase and glutaminase. Better understanding of these alternative pathways are leading to the development of new therapeutic approaches.For over 100 years, ammonia has been thought to be central in the pathogenesis of hepatic encephalopathy (1). Many organs are involved in regulating whole body ammonia homeostasis (2), with the regulation of arterial levels dependent upon 'interorgan ammonia metabolism' in the context of urea cycle disruption and portalsystemic shunting. Previous meta-analysis suggest that current therapeutic strategies aimed at targeting ammonia fall short of the desired impact on clinical HE (3, 4). This review describes interorgan ammonia and amino acid metabolism in health and in patients with liver failure and how these concepts may lead to the development of more targeted therapies. Ammonia metabolism in healthNitrogen is necessary for cellular structure and energy. Humans must therefore assimilate reduced nitrogenous compounds as part of our diet, such as protein, free amino acids and ammonia (derived from the splitting of urea and other amino acids). In the body, ammonia (NH 3 ) is co-existent with its charged form ammonium (NH 4 1 ). Their relative concentrations are dependent on pH (5). At physiological pH, 98% of total ammonia exists as NH 4 1 , with gaseous NH 3 the main diffusible form transported across biological membranes. In this review, we will refer to NH 3 /NH 4 1 as simply, 'ammonia' . Ammonia is hydrophilic and easily transported in plasma. In health, ammonia transport and metabolism are tightly regulated to maintain low plasma concentrations (normal range 10-40 mmol/L), but exists in the mmol/L range in organs such as intestine or kidney. Transport of unionized ammonia into the cell is through diffusion despite low lipid solubility. In metabolic alkalosis, the conversion of NH 4 1 to NH 3 is increased, thus increasing membrane permeability. Conversely within the cell, negatively charged mitochondria show very poor permeability to NH 3 , but high NH 4 1 permeability (6). Transmembrane transport of ammonia can be facilitated by constitutive ion channels and transporters such as the Rhesus proteins (7-9) and Aquaporin (10-12), however, their precise role in whole body ammonia metabolism remains unclear.

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Section: Interorgan Ammonia and Amino Acid Metabolismmentioning

confidence: 99%

Interorgan ammonia metabolism in liver failure: the basis of current and future therapies

Wright

Noiret

Damink

et al. 2011

Liver International

133

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“…Metabolic acidosis brings about significant functional changes in the kidney, including an increase in renal plasma flow (RPF) and glomerular filtration rate (GFR), probably as adaptive mechanisms to eliminate the excess acid load. [55][56][57][58] Clinical situations imposing an excessive acid load on the kidney (such as high animal protein consumption, obesity, and diabetes) display similar renal hemodynamic changes. It has been long known that high dietary protein intake is associated with an increase in RPF and GFR in healthy subjects and patients with chronic kidney disease.…”

Section: Chronic Kidney Failure-induced Metabolic Acidosis Causes Insmentioning

confidence: 99%

Metabolic Acidosis-Induced Insulin Resistance and Cardiovascular Risk

Souto

Donapetry²,

Calviño³

et al. 2011

Metabolic Syndrome and Related Disorders

109

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Microalbuminuria has been conclusively established as an independent cardiovascular risk factor, and there is evidence of an association between insulin resistance and microalbuminuria, the former preceding the latter in prospective studies. It has been demonstrated that even the slightest degree of metabolic acidosis produces insulin resistance in healthy humans. Many recent epidemiological studies link metabolic acidosis indicators with insulin resistance and systemic hypertension. The strongly acidogenic diet consumed in developed countries produces a lifetime acidotic state, exacerbated by excess body weight and aging, which may result in insulin resistance, metabolic syndrome, and type 2 diabetes, contributing to cardiovascular risk, along with genetic causes, lack of physical exercise, and other factors. Elevated fruits and vegetables consumption has been associated with lower diabetes incidence. Diseases featuring severe atheromatosis and elevated cardiovascular risk, such as diabetes mellitus and chronic kidney failure, are typically characterized by a chronic state of metabolic acidosis. Diabetic patients consume particularly acidogenic diets, and deficiency of insulin action generates ketone bodies, creating a baseline state of metabolic acidosis worsened by inadequate metabolic control, which creates a vicious circle by inducing insulin resistance. Even very slight levels of chronic kidney insufficiency are associated with increased cardiovascular risk, which may be explained at least in part by deficient acid excretory capacity of the kidney and consequent metabolic acidosis-induced insulin resistance.

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“…To regenerate bicarbonate and maintain homeostasis, the proximal tubule synthesizes ammonia and bicarbonate from glutamine in response to variations in the acid-base status. 20,21 Renal ammoniagenesis is stimulated further by acidosis. 21 Chronic potassium depletion results in increased bicarbonate reabsorption, causing intracellular acidosis and increased ammonia production.…”

Section: Renal Ammoniagenesismentioning

confidence: 99%

“…20,21 Renal ammoniagenesis is stimulated further by acidosis. 21 Chronic potassium depletion results in increased bicarbonate reabsorption, causing intracellular acidosis and increased ammonia production. 22 Precipitating Clinical Factors That Lead to Increased Blood Ammonia and Overt HE Clinical events that may increase blood ammonia levels include GI bleeding, constipation, excessive portosystemic shunting, azotemia, and hypokalemia.…”

Section: Renal Ammoniagenesismentioning

confidence: 99%

Update on Management of Patients With Overt Hepatic Encephalopathy

Chacko

Sigal

2013

Hospital Practice

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Hepatic encephalopathy (HE) is a multifactorial neuropsychiatric disease that affects patients with cirrhosis. We review the clinical impact, pathogenesis, evaluation, management, and prevention of overt HE in patients with cirrhosis. Articles published between January 1960 and November 2012 were acquired through a MEDLINE search of different combinations of the terms hepatic encephalopathy, pathophysiology, treatment, prophylaxis, prevention, prognosis, and recurrence. The Healthcare Cost and Utilization Project database was used to obtain prevalence and cost information related to hospitalizations of patients with HE. The literature describes significant morbidity and mortality of HE in patients with cirrhosis. Overt HE develops in 30% to 45% of patients with cirrhosis and is associated with a substantial pharmacoeconomic burden, particularly HE-related hospitalizations. The development of HE in patients with cirrhosis portends a worsened prognosis and is incorporated into the Child-Pugh classification of the severity of liver disease. In the hospitalized patient, the development of HE is associated with precipitating events (eg, gastrointestinal bleeding, dehydration, infection), and in some patients, its course is characterized by frequent and severe relapses. In addition, hospitalized patients with overt HE have a 3.9-fold increased mortality risk. Patient management employs nonabsorbable disaccharides, the nonsystemic antibiotic rifaximin, or both, to treat acute HE episodes and prevent HE relapse. In open-label trials, use of the nonabsorbable disaccharide lactulose reduced the risk of overt HE recurrence in patients compared with no-lactulose control groups for ≤ a median of 14 months. In a randomized, placebo-controlled trial, rifaximin 550 mg twice daily was more effective in maintaining HE remission compared with placebo and was associated with a reduction in HE-related hospitalizations. Recent advances in treatment and preventative therapies may reduce the personal, societal, and economic impact of this disorder.

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Mechanisms of renal ammonia production and protein turnover

Cited by 12 publications

References 35 publications

Interorgan ammonia metabolism in liver failure: the basis of current and future therapies

Interorgan ammonia metabolism in liver failure: the basis of current and future therapies

Metabolic Acidosis-Induced Insulin Resistance and Cardiovascular Risk

Update on Management of Patients With Overt Hepatic Encephalopathy

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