Identifying the direct effects of ammonia on the brain

Elevated concentrations of ammonia in the brain as a result of hyperammonemia leads to cerebral dysfunction involving a spectrum of neuropsychiatric and neurological symptoms (impaired memory, shortened attention span, sleep-wake inversions, brain edema, intracranial hypertension, seizures, ataxia and coma). Many studies have demonstrated ammonia as a major player involved in the neuropathophysiology associated with liver failure and inherited urea cycle enzyme disorders. Ammonia in solution is composed of a gas (NH(3)) and an ionic (NH(4) (+)) component which are both capable of crossing plasma membranes through diffusion, channels and transport mechanisms and as a result have a direct effect on pH. Furthermore, NH(4) (+) has similar properties as K(+) and, therefore, competes with K(+) on K(+) transporters and channels resulting in a direct effect on membrane potential. Ammonia is also a product as well as a substrate for many different biochemical reactions and consequently, an increase in brain ammonia accompanies disturbances in cerebral metabolism. These direct effects of elevated ammonia concentrations on the brain will lead to a cascade of secondary effects and encephalopathy

Brain edema in acute liver failure and chronic liver disease: Similarities and differences

Hepatic encephalopathy (HE) is a complex neuropsychiatric syndrome that typically develops as a result of acute liver failure or chronic liver disease. Brain edema is a common feature associated with HE. In acute liver failure, brain edema contributes to an increase in intracranial pressure, which can fatally lead to brain stem herniation. In chronic liver disease, intracranial hypertension is rarely observed, even though brain edema may be present. This discrepancy in the development of intracranial hypertension in acute liver failure versus chronic liver disease suggests that brain edema plays a different role in relation to the onset of HE. Furthermore, the pathophysiological mechanisms involved in the development of brain edema in acute liver failure and chronic liver disease are dissimilar. This review explores the types of brain edema, the cells, and pathogenic factors involved in its development, while emphasizing the differences in acute liver failure versus chronic liver disease. The implications of brain edema developing as a neuropathological consequence of HE, or as a cause of HE, are also discussed

Elevated cerebral lactate : implications in the pathogenesis of hepatic encephalopathy

Hepatic encephalopathy (HE), a complex neuropsychiatric syndrome, is a frequent complication of liver failure/disease. Increased concentrations of lactate are commonly observed in HE patients, in the systemic circulation, but also in the brain. Traditionally, increased cerebral lactate is considered a marker of energy failure/impairment however alterations in lactate homeostasis may also lead to a rise in brain lactate and result in neuronal dysfunction. The latter may involve the development of brain edema. This review will target the significance of increased cerebral lactate in the pathogenesis of HE

Oxidative stress: a systemic factor implicated in the pathogenesis of hepatic encephalopathy

Although ammonia is considered the main factor involved in the pathogenesis of hepatic encephalopathy (HE), it correlates well with the severity of HE in acute liver failure, but not in chronic liver disease. Oxidative stress is another factor believed to play a role in the pathogenesis of this syndrome; it represents an imbalance between the production and neutralization of reactive oxygen species, which leads to cellular dysfunction. In the setting of liver disease, oxidative stress represents a systemic phenomenon induced by several mechanisms: decreased antioxidant synthesis, increased systemic release of oxidant enzymes, generation of reactive oxygen species, and impaired neutrophil function. High ammonia concentrations induce cerebral oxidative stress, thus contributing to severe hepatic encephalopathy, as observed in acute liver failure. In chronic liver disease, significantly lower degrees of hyperammonemia (<500 μM) do not induce cerebral nor systemic oxidative stress. Data from both animal and human studies sustain that there is a synergistic effect between systemic oxidative stress, and ammonia that is implicated in the pathogenesis of hepatic encephalopathy

Induction of systemic oxidative stress leads to brain oedema in portacaval shunted rats

Background & Aims The pathogenesis of hepatic encephalopathy (HE) is multifactorial and often associated with the development of brain oedema. In addition to ammonia playing a central role, systemic oxidative stress is believed to aggravate the neuropsychological effects of ammonia in patients with chronic liver disease (CLD). The aim of this study was to (i) induce systemic oxidative stress in hyperammonaemic portacaval anastomosed (PCA) rats by inhibiting the antioxidant glutathione using Dimethyl maleate (DEM) and (ii) investigate whether a synergistic relationship between ammonia and oxidative stress contributes to the pathogenesis of brain oedema in CLD. Methods Four-week PCA and sham-operated rats received DEM (0.4–4 mg/kg/day) for the last 10 days before sacrifice when oxidative stress markers [reactive oxygen species (ROS) and malondialdehyde (MDA)] were assessed in blood and frontal cortex. Brain water content was measured using a specific gravimetric technique. Results Dimethyl maleate induced an increase in ROS and MDA in the blood, but not in the brain, of the PCA rats, compared with non-treated PCA rats. This was accompanied with an increase in brain water content (PCA+DEM: 78.45 ± 0.13% vs. PCA: 77.38 ± 0.11%, P < 0.001). Higher doses of DEM induced systemic oxidative stress in sham-operated controls, but brain oedema did not develop. Conclusions Dimethyl maleate provoked systemic, not central, oxidative stress in PCA rats, resulting in the development of brain oedema. Independently, hyperammonaemia and systemic oxidative stress do not precipitate brain oedema; therefore, our findings sustain that a synergistic effect between hyperammonaemia and systemic oxidative stress is responsible for the development of brain oedema in HE

Pathogenèse de l’oedème cérébral dans l’encéphalopathie hépatique minimale : rôles du stress oxydatif et du lactate

L’encéphalopathie hépatique (EH) est un syndrome neuropsychiatrique découlant des complications de l'insuffisance hépatique. Les patients souffrant d'une insuffisance hépatique chronique (IHC) présentent fréquemment une EH minimale (EHM) caractérisée par des dysfonctions cognitives subtiles qui affectent leur qualité de vie. L'insuffisance hépatique entraîne une hyperammoniémie, le facteur central dans la pathogenèse de l'EH. Pourtant, les taux d'ammoniaque sérique ne sont pas corrélés avec la sévérité de l'EH lors d'une IHC, suggérant que d'autres facteurs y contribuent. L'oedème cérébral est une caractéristique neuropathologique décrite chez les patients souffrant d'une EHM et plusieurs facteurs dont le stress oxydatif, les altérations du métabolisme énergétique et l'augmentation de la glutamine cérébrale pourraient contribuer à la pathogenèse de l'oedème cérébral lors d'une EHM induite par une IHC. Les mécanismes sous-jacents exacts ainsi que les relations entre ces facteurs et l'ammoniaque ne sont pas connus. Présentement, le seul traitement efficace de l'IHC est la transplantation hépatique, une option thérapeutique très limitée. Le but de cette thèse est de contribuer à l'avancement des connaissances sur les mécanismes sous-jacents liés au rôle du stress oxydatif, de la glutamine et du lactate dans la pathogenèse de l'oedème cérébral lors d'une EHM induite par une IHC afin d'envisager de nouvelles options thérapeutiques. Les objectifs précis étaient: 1. Établir le rôle de l’ammoniaque et sa relation avec le stress oxydatif dans la pathogenèse de l'oedème cérébral lors d'une EHM induite par une IHC. 2. Établir le rôle du stress oxydatif dans la pathogenèse de l'oedème cérébral, sa relation avec l'ammoniaque et l'effet du traitement avec des antioxydants. 3. Confirmer l'effet synergique entre l'ammoniaque et le stress oxydatif dans la pathogenèse de l'oedème cérébral. 4. Établir le rôle du lactate et de la glutamine dans la pathogenèse de l'oedème cérébral et leur relation avec l’ammoniaque. Pour atteindre ces objectifs, 2 modèles animaux d'EHM obtenus par microchirurgie chez le rat ont été utilisés: 1) la ligature de voie biliaire, un modèle d'IHC et 2) l'anastomose porto-cave, un modèle d'hyperammoniémie induite par la dérivation portosystémique. Nos résultats démontrent que l'ammoniaque et le stress oxydatif indépendamment n'induisent pas l'oedème cérébral lors d'une EHM. Pourtant, lorsque les 2 facteurs agissent ensemble ils présentent ii un effet synergique qui entraîne le développement de l'oedème cérébral, le stress oxydatif étant une première insulte, qui est suivie par l'hyperammoniémie comme deuxième insulte. En plus, le stress oxydatif a été mis en évidence seulement au niveau systémique, et non au niveau central dans notre modèle d'IHC en association avec l'oedème cérébral, suggérant que le stress oxydatif systémique est une conséquence de la dysfonction hépatique et que l'hyperammoniémie n’induit pas le stress oxydatif ni systémique ni central. Nous avons démontré qu’une augmentation du lactate cérébral est une conséquence directe de l'hyperammoniémie et joue un rôle important dans la pathogenèse de l'oedème cérébral lors d'une EHM induite par une IHC, tandis qu’une augmentation de la glutamine au niveau cérébral n'est pas un facteur clé. La compréhension de ces mécanismes a entraîné la proposition de 3 nouvelles stratégies thérapeutiques potentielles pour l'EHM. Elles ciblent la diminution de l'ammoniaque sérique, la réduction du stress oxydatif et l'inhibition de la synthèse du lactate.Hepatic encephalopathy (HE) is a metabolic neuropsychiatric syndrome which occurs as a complication of liver failure/disease. Patients with chronic liver disease (CLD) present often with minimal HE (MHE) characterized by subtle cognitive dysfunction which impairs their quality of life. Impaired liver function leads to hyperammonemia which is a central factor in the pathogenesis of HE. However, ammonia alone is poorly correlated with the severity of HE during CLD, strongly suggesting other factors may contribute. Brain edema is a neuropathological feature described in MHE patients and several factors such as oxidative stress, energy metabolism alterations and an increase in glutamine may to contribute to the pathogenesis of brain edema during HE related to CLD. However the exact underlying mechanisms and the relationships between these factors and ammonia are poorly understood. To date, the only effective treatment of CLD remains liver transplantation, a limited therapeutic option. The aim of this thesis is to advance the knowledge into the mechanisms underlying the role of oxidative stress, glutamine and lactate in the pathogenesis of brain edema during MHE associated with CLD in order to uncover new therapeutic options. The study objectives were: 1. Define the role of ammonia and its relationship with oxidative stress in the pathogenesis of brain edema in CLD. 2. Define the role of oxidative stress in the pathogenesis of brain edema, its relationship with ammonia as well as the effect of antioxidant treatment. 3. Confirm a synergistic role of ammonia and oxidative stress in the pathogenesis of brain edema. 4. Define the role of lactate and glutamine in the pathogenesis of brain edema and their relationship with ammonia. To achieve these objectives, we used 2 microsurgical rat models: 1) bile-duct ligation, a cirrhosis model and 2) portacaval anastomosis, a hyperammonemia model following portal-systemic shunting. Our findings demonstrate that ammonia and systemic oxidative stress independently do not induce brain edema in MHE related to CLD. However, when both factors are present, they exert a synergistic effect leading to the development of brain edema with oxidative stress presenting as a “first hit”, followed by hyperammonemia as a “second hit”. Moreover, solely systemic and not central oxidative stress was observed in our CLD rat model in relation to brain edema implying that systemic oxidative stress is a consequence of liver dysfunction and that central oxidative stress is not a direct iv effect of hyperammonemia in the setting of CLD. Moreover, we revealed that increased cerebral lactate is a direct consequence of hyperammonemia and also plays an important role in the pathogenesis of brain edema, while increased cerebral glutamine does not. The understanding of these mechanisms led to the proposal of three different strategies as potential HE therapies. These are directed towards lowering ammonia, reducing oxidative stress and inhibiting lactate synthesis

Analyse génétique moléculaire du gène de la voie non-canonique Frizzled/Dishevelled PRICKLE1 dans les anomalies du tube neural chez l’humain

La voie de la polarité planaire cellulaire (PCP), aussi connue sous le nom de la voie non-canonique du Frizzled/Dishevelled, contrôle le processus morphogénétique de l'extension convergente (CE) qui est essentiel pour la gastrulation et la formation du tube neural pendant l'embryogenèse. La signalisation du PCP a été récemment associée avec des anomalies du tube neural (ATN) dans des modèles animaux et chez l'humain. Prickle1 est une protéine centrale de la voie PCP, exprimée dans la ligne primitive et le mésoderme pendant l'embryogenèse de la souris. La perte ou le gain de fonction de Prickle1 mène à des mouvements de CE fautifs chez le poisson zèbre et la grenouille. PRICKLE1 interagit directement avec deux autres membres de la voie PCP, Dishevelled et Strabismus/Vang. Dans notre étude, nous avons investigué le rôle de PRICKLE1 dans l'étiologie des ATN dans une cohorte de 810 patients par le re-séquençage de son cadre de lecture et des jonctions exon-intron. Le potentiel pathogénique des mutations ainsi identifiées a été évalué par des méthodes bioinformatiques, suivi par une validation fonctionnelle in vivo dans un système poisson zèbre. Nous avons identifié dans notre cohorte un total de 9 nouvelles mutations dont sept: p.Ile69Thr, p.Asn81His, p.Thr275Met, p.Arg682Cys et p.Ser739Phe, p.Val550Met et p.Asp771Asn qui affectent des acides aminés conservés. Ces mutations ont été prédites in silico d’affecter la fonction de la protéine et sont absentes dans une large cohorte de contrôles de même origine ethnique. La co-injection de ces variantes avec le gène prickle1a de type sauvage chez l’embryon de poisson zèbre a démontré qu’une mutation, p.Arg682Cys, modifie dans un sens négatif le phénotype du défaut de la CE produit par pk1 de type sauvage. Notre étude démontre que PK1 peut agir comme facteur prédisposant pour les ATN chez l’humain et élargit encore plus nos connaissances sur le rôle des gènes de la PCP dans la pathogenèse de ces malformations.The planar cell polarity pathway (PCP) or the non-canonical Frizzled/Dishevelled pathway controls the morphogenetic process of convergent extension (CE) that is essential during embryogenesis for gastrulation and neural tube formation. Recently, PCP signalling was associated with neural tube defects (NTD) in humans and animal models. The core PCP protein, Prickle1, is expressed in the primitive streak and mesoderm during mouse embryogenesis. Both gain and loss of function of Prickle1 cause faulty CE movements in zebrafish and the frog. PRICKLE1 physically interacts with two other core PCP members, Dishevelled and Strabismus/Vang. In the present study we investigated the role of PRICKLE1 in the aetiology of NTDs in a large cohort of 810 patients through resequencing of its open reading frame and exon-intron junctions. The pathogenicity of the identified mutations was assessed through bioinformatics methods followed by a functional validation in a zebrafish system, in vivo. We identified in our cohort a total of nine novel mutations, of which seven affected conserved amino acids: p.Ile69Thr, p.Asn81His, p.Thr275Met, p.Arg682Cys, p.Ser739Phe, p.Val550Met and p.Asp771As. These mutations were predicted to affect the function of the protein in silico and were absent in a large cohort of ethnically-matched controls. Co-injection of these variants with the wild type pk1 in zebrafish oocytes revealed that one mutation, p.Arg682Cys, antagonized the CE phenotype induced by the wild-type zebrafish prickle1a in a dominant fashion. Our study demonstrates that PRICKLE1 can represent a predisposing factor for human NTDs and further expands our knowledge on the role that PCP genes in the pathogenesis of these malformations

Portacaval anastomosis-induced hyperammonemia does not lead to oxidative stress

Ammonia is neurotoxic and believed to play a major role in the pathogenesis of hepatic encephalopathy (HE). It has been demonstrated, in vitro and in vivo, that acute and high ammonia treatment induces oxidative stress. Reactive oxygen species (ROS) are highly reactive and can lead to oxidization of proteins resulting in protein damage. The present study was aimed to assess oxidative status of proteins in plasma and brain (frontal cortex) of rats with 4-week portacaval anastomosis (PCA). Markers of oxidative stress, 4-hydroxy-2-nonenal (HNE) and carbonylation were evaluated by immunoblotting in plasma and frontal cortex. Western blot analysis did not demonstrate a significant difference in either HNE-linked or carbonyl derivatives on proteins between PCA and sham-operated control rats in both plasma and frontal cortex. The present study suggests PCA-induced hyperammonemia does not lead to systemic or central oxidative stress.CIHR-MOP-8283

The bile duct ligated rat : a relevant model to study muscle mass loss in cirrhosis

Muscle mass loss and hepatic encephalopathy (complex neuropsychiatric disorder) are serious complications of chronic liver disease (cirrhosis) which impact negatively on clinical outcome and quality of life and increase mortality. Liver disease leads to hyperammonemia and ammonia toxicity is believed to play a major role in the pathogenesis of hepatic encephalopathy. However, the effects of ammonia are not brain-specific and therefore may also affect other organs and tissues including muscle. The precise pathophysiological mechanisms underlying muscle wasting in chronic liver disease remains to be elucidated. In the present study, we characterized body composition as well as muscle protein synthesis in cirrhotic rats with hepatic encephalopathy using the 6-week bile duct ligation (BDL) model which recapitulates the main features of cirrhosis. Compared to sham-operated control animals, BDL rats display significant decreased gain in body weight, altered body composition, decreased gastrocnemius muscle mass and circumference as well as altered muscle morphology. Muscle protein synthesis was also significantly reduced in BDL rats compared to control animals. These findings demonstrate that the 6-week BDL experimental rat is a relevant model to study liver disease-induced muscle mass loss