Nursing care of an infant with nephrogenic diabetes insipidus

Aradine, Carolyn Ruth.

January 1966

Thesis (M.S.)--University of Wisconsin, School of Nursing, 1966. / Typewritten. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 89-91).

Die molekulare Pathophysiologie der hypothalamisch-renalen Osmoregulation bei Mäusen mit X-chromosomalem nephrogenen Diabetes insipidus

Schliebe, Nicole

January 2009

Zugl.: Leipzig, Univ., Diss., 2009

Autosomal Dominant Neurohypophyseal Diabetes Insipidus in Two Families

Hedrich, Christian Michael, Zachurzok-Buczynska, Agnieszka, Gawlik, Aneta, Russ, Susanne, Hahn, Gabriele, Köhler, Katrin, Malecka-Tendera, Ewa, Hübner, Angela

19 February 2014

Background: Autosomal dominant familial neurohypophyseal diabetes insipidus (adFNDI) is a rare disease with symptoms of polydipsia, polyuria and dehydration caused by arginine vasopressin deficiency. Disease onset is within infancy or adolescence. A variety of disease-causing mutations of the arginine vasopressin neurophysin II gene (AVP) on chromosome 20p13 have been described. Methods: Two Polish families with adFNDI were screened for mutations. Processing of wild-type (WT) and mutant AVP was monitored using immunocytochemical methods in stably transfected Neuro2A cells. AVP secretion into the cell culture supernatant was investigated with an enzyme immunoassay. Results: In the first family a heterozygous p.G96D mutation was identified. Some patients additionally carried a novel heterozygous mutation p.A159T. The second family presented with a heterozygous mutation p.C98G. Confocal laser microscopy unveiled accumulation of p.G96D and p.C98G prohormones in the cellular bodies, whereas WT and p.A159T prohormones and/or processed products were located in the tips of cellular processes. Reduced levels of AVP in supernatant culture medium of p.G96D and p.C98G transfected cells in comparison to p.A159T and WT cells were found. Conclusions: We conclude that the p.G96D and p.C98G mutations cause adFNDI in the two reported families. The sequence variant p.A159T does not seem to have disease-causing effects. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Neurophysiologe II

Wasserharnruhr

Diabetes insipidus

Arginin-Vasopressin

Diabetes insipidus

Arginine vasopressin

Neurophysin II

AVP gene

ddc:610

rvk:XA 10000

Autosomal Dominant Neurohypophyseal Diabetes Insipidus in Two Families: Molecular Analysis of the Vasopressin-Neurophysin II Gene and Functional Studies of Three Missense Mutations

Hedrich, Christian Michael, Zachurzok-Buczynska, Agnieszka, Gawlik, Aneta, Russ, Susanne, Hahn, Gabriele, Köhler, Katrin, Malecka-Tendera, Ewa, Hübner, Angela

January 2009

Background: Autosomal dominant familial neurohypophyseal diabetes insipidus (adFNDI) is a rare disease with symptoms of polydipsia, polyuria and dehydration caused by arginine vasopressin deficiency. Disease onset is within infancy or adolescence. A variety of disease-causing mutations of the arginine vasopressin neurophysin II gene (AVP) on chromosome 20p13 have been described. Methods: Two Polish families with adFNDI were screened for mutations. Processing of wild-type (WT) and mutant AVP was monitored using immunocytochemical methods in stably transfected Neuro2A cells. AVP secretion into the cell culture supernatant was investigated with an enzyme immunoassay. Results: In the first family a heterozygous p.G96D mutation was identified. Some patients additionally carried a novel heterozygous mutation p.A159T. The second family presented with a heterozygous mutation p.C98G. Confocal laser microscopy unveiled accumulation of p.G96D and p.C98G prohormones in the cellular bodies, whereas WT and p.A159T prohormones and/or processed products were located in the tips of cellular processes. Reduced levels of AVP in supernatant culture medium of p.G96D and p.C98G transfected cells in comparison to p.A159T and WT cells were found. Conclusions: We conclude that the p.G96D and p.C98G mutations cause adFNDI in the two reported families. The sequence variant p.A159T does not seem to have disease-causing effects. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/610

ddc:610

A comparative study of insulin and non-insulin dependent diabetics on measures of therapeutic relationship, self-disclosure and disease control

Getting, Ila Jean.

January 1982

Thesis (M.S.)--University of Wisconsin--Madison, 1982. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 61-66).

Analyse fonctionnelle de deux nouvelles mutations récessives de l’AQP2 impliquées dans le diabète insipide néphrogénique par expression dans les ovocytes de Xenopus laevis

Leduc-Nadeau, Alexandre

06 1900

Le diabète insipide néphrogénique (DIN) autosomal peut être causé par les mutations du gène codant pour le canal à eau aquaporine-2 (AQP2). Un modèle couramment utilisé pour l’étude des protéines membranaires telle l’AQP2 est l’expression hétérologue dans les ovocytes de Xenopus laevis. Malheureusement, les techniques déjà existantes de purification de membranes plasmiques sont soit trop longues, trop difficiles ou demandent trop de matériel, ne permettent pas l’analyse adéquate du ciblage des formes sauvage comme mutantes, un élément crucial de ce type d’étude. Nous avons donc dans un premier temps mis au point une technique rapide et efficace de purification de membranes plasmiques qui combine la digestion partielle de la membrane vitelline, sa polymérisation à la membrane plasmique suivi de centrifugations à basse vitesse pour récolter les membranes purifiées. Nous avons utilisé cette technique dans l’étude de deux nouveaux cas familiaux de patients hétérozygotes possédant les mutations V24A et R187C dans un cas et K228E et R187C dans le second cas. Pour chaque mutation, nous avons analysé autant les éléments de fonctionnalité que les paramètres d’expression des protéines mutantes. Les expériences de perméabilité membranaire démontrent que les ovocytes exprimant AQP2-V24A (Pf = 16.3 ± 3.5 x 10-4 cm/s, 10 ng) et AQP2- K228E (Pf = 19.9 ± 7.0 x 10-4 cm/s, 10 ng) ont des activités similaires à celle exprimant la forme native (Pf = 14.4 ± 5.5 x 10-4 cm/s, 1 ng), tandis que AQP2- R187C (Pf = 2.6 ± 0.6 x 10-4 cm/s, 10 ng) ne semble avoir aucune activité comme ce qui est observé chez les ovocytes non-injectés (Pf = 2.8 ± 1.0 x 10-4 cm/s). Les études de co-expression ont démontré un effet d’additivité lorsque AQP2-V24A et -K228E sont injectées avec la forme native et un effet s’apparentant à la dominance négative lorsque AQP2-R187C est injecté avec la forme native, avec AQP2-V24A ou avec –K228E. Les résultats obtenus par immunobuvardage représente bien ce qui a été démontré précédemment, on remarque la présence des mutations K228E, V24A et la forme sauvage à la membrane plasmique, contrairement à la mutation R187C. Cependant, lorsque les mutations sont exprimées dans des cellules mIMCD-3, il n’y a qu’une faible expression à la membrane de la forme –K228E et une absence totale des formes –V24A et –R187C à la membrane plasmique, contrairement à la forme native. Les résultats de nos études démontrent que tout dépendant du système d’expression les formes –K228E et –V24A peuvent être utiles dans l’étude des problèmes d’adressage à la membrane à l’aide de chaperonne chimique. De plus, la forme –R187C démontre des difficultés d’adressage qui devront être étudiées afin de mieux comprendre la synthèse des formes natives. / The autosomal nephrogenic diabetes insipidus (NDI) is caused by mutations of the gene coding for the water channel aquaporine-2 (AQP2). An oftenly used model for the study of membrane proteins such as AQP2 is the heterogenous expression in Xenopus laevis oocytes. Unfortunately, the existing techniques of plasma membranes purification are either too long, too difficult or require too much material, which does not allow adequate analysis of targeting of the native and mutants forms, which is crucial for this type of study. We developed a fast and effective plasma membrane purification technique which combines partial digestion of the vitellin membrane, its polymerization with the plasma membrane followed by a serie of low speed centrifugations to collect the purified membranes. We used this technique to study of two new family cases of heterozygote patients carrying the V24A and R187C mutations in a case and K228E and R187C in the second case. For each mutation, we analyzed the functionality and the parameters of expression of the mutant proteins. The membrane permeability experiments show that the oocytes expressing AQP2- V24A (Pf = 16.3 ± 3.5 x 10-4 cm/s, 10 ng) and AQP2-K228E (Pf = 19.9 ± 7.0 x 10-4 cm/s, 10 ng) have similar activities to the oocytes expressing the native form (Pf = 14.4 ± 5.5 x 10-4 cm/s, 1 ng), while AQP2-R187C (Pf = 2.6 ± 0.6 x 10-4 cm/s, 10 ng) doesn’t seem to have any activity like the un-injected oocytes (Pf = 2.8 ± 1.0 x 10-4 cm/s). The coexpression studies showed an additive effect when AQP2-V24A and -K228E are injected with the native form and an effect being associated with negative dominance when AQP2-R187C was injected with AQP2-V24A, -K228E and the native form. Western blot results confirmed what was observed in the functionality studies. However, when the mutations were expressed in mIMCD-3 cells, there was a slight expression of the K228E mutation to the plasma membrane and a total absence of the mutations –V24A and R187C at the plasma membrane. The results of our studies showed that depending on the expression system the mutations –K228E and -V24A can be used in targeting studies using chemical chaperones.

Ovocyte

Aquaporine-2

Diabète insipide néphrogénique

mutation

Oocyte

Aquaporin-2

Nephrogenic diabetes insipidus

mutation

Analyse fonctionnelle de deux nouvelles mutations récessives de l’AQP2 impliquées dans le diabète insipide néphrogénique par expression dans les ovocytes de Xenopus laevis

Leduc-Nadeau, Alexandre

06 1900

Le diabète insipide néphrogénique (DIN) autosomal peut être causé par les mutations du gène codant pour le canal à eau aquaporine-2 (AQP2). Un modèle couramment utilisé pour l’étude des protéines membranaires telle l’AQP2 est l’expression hétérologue dans les ovocytes de Xenopus laevis. Malheureusement, les techniques déjà existantes de purification de membranes plasmiques sont soit trop longues, trop difficiles ou demandent trop de matériel, ne permettent pas l’analyse adéquate du ciblage des formes sauvage comme mutantes, un élément crucial de ce type d’étude. Nous avons donc dans un premier temps mis au point une technique rapide et efficace de purification de membranes plasmiques qui combine la digestion partielle de la membrane vitelline, sa polymérisation à la membrane plasmique suivi de centrifugations à basse vitesse pour récolter les membranes purifiées. Nous avons utilisé cette technique dans l’étude de deux nouveaux cas familiaux de patients hétérozygotes possédant les mutations V24A et R187C dans un cas et K228E et R187C dans le second cas. Pour chaque mutation, nous avons analysé autant les éléments de fonctionnalité que les paramètres d’expression des protéines mutantes. Les expériences de perméabilité membranaire démontrent que les ovocytes exprimant AQP2-V24A (Pf = 16.3 ± 3.5 x 10-4 cm/s, 10 ng) et AQP2- K228E (Pf = 19.9 ± 7.0 x 10-4 cm/s, 10 ng) ont des activités similaires à celle exprimant la forme native (Pf = 14.4 ± 5.5 x 10-4 cm/s, 1 ng), tandis que AQP2- R187C (Pf = 2.6 ± 0.6 x 10-4 cm/s, 10 ng) ne semble avoir aucune activité comme ce qui est observé chez les ovocytes non-injectés (Pf = 2.8 ± 1.0 x 10-4 cm/s). Les études de co-expression ont démontré un effet d’additivité lorsque AQP2-V24A et -K228E sont injectées avec la forme native et un effet s’apparentant à la dominance négative lorsque AQP2-R187C est injecté avec la forme native, avec AQP2-V24A ou avec –K228E. Les résultats obtenus par immunobuvardage représente bien ce qui a été démontré précédemment, on remarque la présence des mutations K228E, V24A et la forme sauvage à la membrane plasmique, contrairement à la mutation R187C. Cependant, lorsque les mutations sont exprimées dans des cellules mIMCD-3, il n’y a qu’une faible expression à la membrane de la forme –K228E et une absence totale des formes –V24A et –R187C à la membrane plasmique, contrairement à la forme native. Les résultats de nos études démontrent que tout dépendant du système d’expression les formes –K228E et –V24A peuvent être utiles dans l’étude des problèmes d’adressage à la membrane à l’aide de chaperonne chimique. De plus, la forme –R187C démontre des difficultés d’adressage qui devront être étudiées afin de mieux comprendre la synthèse des formes natives. / The autosomal nephrogenic diabetes insipidus (NDI) is caused by mutations of the gene coding for the water channel aquaporine-2 (AQP2). An oftenly used model for the study of membrane proteins such as AQP2 is the heterogenous expression in Xenopus laevis oocytes. Unfortunately, the existing techniques of plasma membranes purification are either too long, too difficult or require too much material, which does not allow adequate analysis of targeting of the native and mutants forms, which is crucial for this type of study. We developed a fast and effective plasma membrane purification technique which combines partial digestion of the vitellin membrane, its polymerization with the plasma membrane followed by a serie of low speed centrifugations to collect the purified membranes. We used this technique to study of two new family cases of heterozygote patients carrying the V24A and R187C mutations in a case and K228E and R187C in the second case. For each mutation, we analyzed the functionality and the parameters of expression of the mutant proteins. The membrane permeability experiments show that the oocytes expressing AQP2- V24A (Pf = 16.3 ± 3.5 x 10-4 cm/s, 10 ng) and AQP2-K228E (Pf = 19.9 ± 7.0 x 10-4 cm/s, 10 ng) have similar activities to the oocytes expressing the native form (Pf = 14.4 ± 5.5 x 10-4 cm/s, 1 ng), while AQP2-R187C (Pf = 2.6 ± 0.6 x 10-4 cm/s, 10 ng) doesn’t seem to have any activity like the un-injected oocytes (Pf = 2.8 ± 1.0 x 10-4 cm/s). The coexpression studies showed an additive effect when AQP2-V24A and -K228E are injected with the native form and an effect being associated with negative dominance when AQP2-R187C was injected with AQP2-V24A, -K228E and the native form. Western blot results confirmed what was observed in the functionality studies. However, when the mutations were expressed in mIMCD-3 cells, there was a slight expression of the K228E mutation to the plasma membrane and a total absence of the mutations –V24A and R187C at the plasma membrane. The results of our studies showed that depending on the expression system the mutations –K228E and -V24A can be used in targeting studies using chemical chaperones.

Ovocyte

Aquaporine-2

Diabète insipide néphrogénique

mutation

Oocyte

Aquaporin-2

Nephrogenic diabetes insipidus

mutation

Caractérisation biochimique et fonctionnelle du mutant T179N de l’aquaporine-2 humaine

Matar, Jessica

04 1900

L’aquaporine-2 (AQP2) est le canal responsable de la réabsorption finale d’eau au niveau du tubule collecteur du rein. À la base, contenue dans des vésicules internes, l’AQP2 est acheminée à la membrane apicale des cellules principales du tubule collecteur suite à une stimulation par l’hormone antidiurétique (ADH). L’incapacité à accomplir cette fonction entraîne le diabète insipide néphrogénique (DIN), une maladie caractérisée par l’inhabileté du rein à concentrer l’urine, entraînant une production de volumes urinaires élevés. Alors que les mutations récessives génèrent des protéines mal structurées et incapables de former des tétramères, les mutations dominantes sont capables de s’associer à leurs homologues sauvages, engendrant ainsi un DIN même chez les patients hétérozygotes. Ce mémoire présente l’analyse biochimique et fonctionnelle d’une nouvelle mutation naturelle de l’AQP2, la mutation T179N, aussi responsable du DIN. Cette dernière est particulièrement intéressante de par son génotype qui implique un caractère dominant, et sa position extracellulaire habituellement réservée aux mutations récessives. Les études comparatives de T179N à deux modèles de mutation récessive et dominante démontrent, tant en ovocytes de Xenopus laevis qu’en lignée cellulaire mpkCCDc14, le caractère récessif de cette nouvelle mutation. Les tests d’immunobuvardage de lysats d’ovocytes en membranes totales et membranes plasmiques purifiées ont révélé que seule la forme sauvage atteint la membrane plasmique alors que le mutant T179N est séquestré dans la cellule. En accord avec ce résultat, les analyses de perméabilité fonctionnelle démontrent aussi une absence d’activité pour T179N. En cellule mpkCCDc14, le mutant T179N exprimé seul n’atteint pas la membrane plasmique suite à l’action de la forskoline, contrairement à la forme sauvage. Cependant, ce mutant peut s’associer à son homologue sauvage en coexpression tant dans les ovocytes qu’en lignée mpkCCDc14 sans toutefois engendrer l’effet typique de dominance négative. En fait, dans ce contexte de coexpression, on remarque une augmentation de la Pf de 83±7 % et une récupération d’adressage à la membrane plasmique en cellule (immunofluorescence). En conclusion, T179N serait un mutant récessif fonctionnellement récupérable lorsqu’en présence de l’AQP2 sauvage. / Aquaporin-2 (AQP2) is the channel responsible for the final reabsorption of water in the collecting duct of the kidney. Basically, contained in internal vesicles, the AQP2 is delivered to the apical membrane of the principal cells of the collecting tubule after stimulation by the antidiuretic hormone (ADH). The failure to perform this function causes nephrogenic diabetes insipidus (NDI); a disease characterized by the inability of the kidney to concentrate urine and induces the production of high urinary volumes. While recessive mutations generate poorly structured proteins unable to form tetramers, dominant mutations are capable of associating with their wild counterparts, thus generating a NDI even in heterozygous patients. This paper presents the biochemical and functional analysis of T179N, a new NDI-causing mutation of the human AQP2. The mutant is particularly interesting because of its dominant genotype, despite its extracellular position usually restricted to recessive mutations. Here, we compare T179N against archetypal recessive and dominant mutations using both Xenopus laevis oocytes and in mpkCCDc14 cell model, and show the recessive nature of the mutation. The immunoblot tests on oocytes lysates in purified total and plasma membranes revealed that only the wild type protein reaches the plasma membrane while the T179N mutant is sequestered within cellular stores. Accordingly, functional analyzes indicate that T179N is inactive. In mpkCCDc14 cells, T179N expressed alone does not reach the plasma membrane in response to forskolin stimulation, unlike the wild-type. However, T179N does show the capacity to associate with its wild-type counterpart in both oocytes and in mpkCCDc14 cells, although without displaying the typical dominant negative effect. In fact, when coexpressed along wild-type, T179N gains back the functionality, with a Pf increase of 83±7 % and adequate plasma membrane targeting in cells (immunofluorescence). In conclusion, the mutant T179N is a mild recessive mutation that is susceptible to functional recovery when in presence of wild type AQP2.

Aquaporine 2

Mutation

Diabète insipide néphrogénique

Expression hétérologue

Aquaporin 2

Nephrogenic diabetes insipidus

Heterologous expression

Estudo da ação do inibidor de fosfodiesterase (sildenafil) no diabetes insipidus induzido pelo lítio / Role of phosphodiesterase inhibitor(sildenafil) in lithium-induced diabetes insipidus

Sanches, Talita Rojas Cunha

26 November 2008

Os pacientes que usam lítio (Li) para tratamento do transtorno bipolar freqüentemente apresentam poliúria e deficiência de concentração urinária, sintomas do Diabetes Insipidus nefrogênico (DIN). Animais tratados com Li apresentam baixos níveis de produção de adenosina monofosfato cíclico (AMPc) em resposta ao hormônio antidiurético (HAD). O Sildenafil (Sil), um inibidor da fosfodiesterase 5 (PDE5), eleva os níveis intracelulares de guanosina monofosfato cíclico (GMPc), levando a inserção de aquaporina 2 (AQP2) na membrana plasmática das células do ducto coletor. Portanto, inibidores de PDE podem promover a inserção de AQP2 na membrana plasmática mesmo sem a ativação do receptor de HAD, indicando a participação de uma via alternativa mediada pelo GMPc. Nós investigamos o efeito do Sil na expressão renal das proteínas de membrana AQP2, UT-A1, NKCC2, NHE3, P-ENaC em ratos com DIN induzido pelo Li. Ratos Wistar foram divididos nos seguintes grupos: grupo controle, recebendo dieta alimentar normal durante quatro semanas; grupo Li, recebendo dieta alimentar normal com 40 mmol Li por quilo de dieta durante quatro semanas; grupo Li + Sil, recebendo dieta alimentar normal com 40 mmol Li por quilo de dieta durante quatro semanas e 200 mg por quilo de dieta de Sil a partir da segunda semana; grupo Sil, recebendo dieta alimentar normal durante a primeira semana e a partir da segunda semana recebendo dieta normal com 200 mg de Sil por quilo de dieta. Os animais do grupo Li desenvolveram poliúria, diminuição da osmolalidade urinária e diminuição da expressão da AQP2. No grupo Li+Sil, o Sil foi capaz de reverter parcialmente a poliúria, diminuir o clearance de água livre, aumentar a osmolalidade urinária e aumentar a expressão da AQP2. A expressão de UTA1 foi completamente normalizada com o tratamento com Sil. A expressão das proteínas NKCC2 e NHE3 apresentaram-se aumentadas no grupo tratado com Li, e o Sil não foi capaz de reverter tal alteração. Além disso, o tratamento com Sil reverteu completamente o aumento da resistência vascular renal. Assim, concluímos que o tratamento com Sil em ratos com DIN melhora a poliúria, aumenta a smolalidade urinária e diminui o clearance de água livre pelo aumento da expressão de AQP2 e UT-A1. O tratamento com Sil pode ser benéfico para pacientes que sofrem com DIN induzida pelo Li. / Patients taking lithium to treat bipolar disorder often present polyuria and urinary concentrating defect. In addition, lithium-treated animals present lower cyclic adenosine monophosphate production in response to vasopressin. Sildenafil (Sil), a phosphodiesterase 5 (PDE5) inhibitor, elevates intracellular cyclic guanosine monophosphate (cGMP) levels, leading to plasma membrane accumulation of aquaporin 2 (AQP2). Therefore, PDE inhibitors might induce AQP2 membrane insertion even without vasopressin receptor activation by activating a parallel cGMP-mediated signal transduction pathway. We investigated the effect of sildenafil on renal expression of AQP2, UT-A1, sodium/hydrogen exchanger (NHE3), type 1 bumetanide-sensitive Na-K-2Cl cotransporter (NKCC2), and the epithelial sodium channel alpha subunit (P-ENaC). Wistar rats received lithium (40 mmol/kg food) or not for 4 weeks (Li or control), some rats also receiving sildenafil (200 mg/kg food) in weeks 2-4, with or without lithium (Li+Sil or Sil). In Li+Sil rats, urine output was markedly lower, as was water free clearance, whereas urine osmolality was higher. Semiquantitative immunoblotting revealed the following: AQP2 expression was partially normalized; UT-A1 expression was completely normalized; expression of NKCC2 and NHE3 was significantly higher in Li rats (although not significantly different between Li+Sil rats and Li rats); and P-ENaC protein expression was unaltered in all groups. Sildenafil treatment completely reversed the lithium-induced increase in renal vascular resistance. In conclusion, sildenafil treatment of lithium-induced nephrogenic diabetes insipidus (NDI) improves polyuria, increases urinary osmolality, and decreases free water clearance via upregulation of renal AQP2 and UT-A1. Sildenafil treatment could be beneficial in patients with lithium-induced NDI.

Aquaporin 2

Aquaporina 2

Cyclic nucleotides

Diabetes insípido nefrogênico

Diabetes insipidus nephrogenic

Inibidores de fodiesterase

Lithium/adverse effects

Lítio/efeitos adversos

Nucleotídeos cíclicos

Phosphodiesterase inhibitors

Efeito da carbamazepina na reabsorção de água pelo ducto coletor medular interno de ratos normais e de ratos com diabetes insípido nefrogênico induzido pelo lítio / Effect of carbamazepine on water absorption in the inner medullary collecting duct from normal rats and from rats with lithium-induced diabetes insipidus

Bragança, Ana Carolina de

25 March 2010

Carbamazepina (Carba) é um anticonvulsivante, uma droga psicotrópica muito utilizada no tratamento de pacientes com distúrbios intelectuais. Esta droga foi utilizada para diminuir o volume urinário no Diabetes Insípido (DI), pois possui um efeito antidiurético, mas a incidência de hiponatremia é uma ocorrência comum. O lítio é uma das drogas mais importantes para o tratamento do distúrbio bipolar. No entanto, ele tem uma grande capacidade de induzir DI dificultando o seu uso em pacientes debilitados psicologicamente. Atualmente, a associação destas drogas é frequentemente utilizada para o tratamento de pacientes com distúrbios psiquiátricos e neurológicos. O objetivo deste trabalho foi investigar o efeito da Carba no ducto coletor medular interno (DCMI) de ratos normais e elucidar a sua ação no DI induzido pelo lítio: 1) Estudos in vitro- A) Estudos com microperfusão de segmentos isolados do néfron onde a permeabilidade à água (Pf, m/sec) foi determinada em DCMI perfundidos de ratos normais (n=20) na presença de Carba à 10-5 M, e na ausência de HAD. B) estudos com a técnica de Imunoblotting para avaliar a expressão da proteína Aquaporina 2 (AQP2) em suspensão de túbulos de DCMI de ratos normais incubados com 10-5 M de Carba por 30 minutos. 2) Estudos in vivo A) quatro grupos foram formados: a) Controle (n=5); b) Li (40 mmol/Kg/dieta por 3 semanas; n=4); c) Li+Carba (40 mmol Li/Kg/dieta + 400 mg carba/Kg/dia por 3 semanas; n=5); d) Carba (400 mg /Kg/dia por 3 semanas; n=5); - B) estudo da expressão da AQP2 no DCMI destes quatro grupos pela técnica de Western Blot. Resultados: 1) Estudos in vitro A) nos estudos de microperfusão a carba adicionada ao banho aumentou a Pf dos DCMI, na ausência de HAD (n=6) Controle12,3+ 3,6, Carba-62,6+14,8 (p<0,01), Recuperação (Rec)-17,4+5,5 (p<0,01). Com o intuito de estudar o mecanismo pelo qual a Carba ativa a cascata do HAD, foi utilizado o inibidor do receptor V2 do HAD (AV2; n=10): Controle-23,5+5,2, Carba-37,4±4,4 (p<0,01), Carba+AV2-19,6±5,0 (p<0,05), Rec-21,4+5,5; e Controle-18,6+7,0, AV2-27,3+7,2, AV2+Carba-25,3+5,7, Rec-32,6+6,4. O inibidor da PKA (H8; n=4) também foi utilizado: Controle-15,0+9,0, Carba-106,1+12,3 (p<0,01), Carba+H8-60,3+16,4 (p<0,01), Rec- 44,5+13,2. B) a análise densitométrica mostrou um aumento de 38,8% na expressão da AQP2 (Controle-100,0+8,3 vs. Carba-138,8+12,12, p<0,05); 1) Estudos in vivo Volume urinário (UV, mL/24h) Controle-10,7+3,0, Li-62,6+6,0 (p<0,001), Li+Carba-28,5+4,9 (p<0,001), Carba-23,3+3,0 (<0,001). Osmolalidade urinária (mOsm/Kg/H2O) Controle-819,6+175,7, Li-149,4+18,0 (p<0,01), Li+Carba-251,5+39,7 (p<0,05), Carba-396,2+75,5 (p<0,01). FENa+ (%) - Controle-0,15+0,01, Li-0,10+0,02, Li+Carba-0,12+0,02, Carba-0,11+0,02. Expressão da AQP2 (%) Controle-100,0+6,7, Li-55,8+5,4 (p<0,01), Li+Carba-75,8+9,6 (p<0,01), Carba- 99,7+4,7 (p<0,05). Não houve diferenças significantes no Na+, K+ e Osmolalidade plasmáticas. Em resumo, nossos dados revelaram que a Carba diminui o UV, aumenta a osmolalidade urinária e a expressão da AQP2 no DI induzido pelo lítio, e aumenta a permeabilidade à água, provavelmente agindo diretamente no receptor da vasopressina (V2). Estes resultados enfatizam que a hiponatremia encontrada nos pacientes que fazem uso da Carba pode ser explicada, pelo menos em parte, pelo aumento da permeabilidade osmótica no DCMI e que a poliúria do DI ocasionado pelo uso do lítio pode ser diminuída com a associação da Carba. / Carbamazepine (Carba) is an anticonvulsant and a psychotropic medication commonly used in the treatment of patients with intellectual disability (ID). This drug has been used to try to decrease the urinary volume in Diabetes Insipidus (DI) because Carba presents an antidiuretic effect, but the incidence of the hyponatremia in neurological patients is a common ocurrence. Lithium (Li) is one of the most important drugs used to treat bipolar mood disorders. However, Li has the undesirable capacity to induce DI complicating its usage in patients psychologically weakened. Nowadays, the association of these drugs is used in the treatment of patients with psychiatric and neurological problems. Our objective was to investigate the effect of Carba in the Inner Medullary Collecting Duct (IMCD) and elucidate its effect in the lithium-induced DI: 1) In vitro study: A) Microperfusion studies the water permeability (Pf, m/sec) was determined in normal rats IMCD isolated and perfused by the standard methods. Carba 10-5M was added to the bath fluid. B) Immunoblotting studies for AQP2 protein expression in IMCD tubule suspension from normal rats incubated with Carba 10-5M for 30 minutes. 2) In vivo study A) four groups of normal rats were done - a) Control (C, n=5); b) Li (40 mmol/kg/food/3 weeks n=4) c) Li+Carba (40 mmol Li/kg/food/3 weeks and 400 mg Carba/kg/bw/2 last weeks, n=5); and Carba (400 mg Carba/kg/bw/3weeks, n=5); - B) AQP2 expression in IMCD from the four groups, by Western Blot. Results: 1) In vitro study A) in microperfusion, Carba added to the bath in Vasopressin (Vp) absence (n=6) increased Pf Control-12.3+3.6, Carba-62.6+14.8 (p<0.01), Recuperation (Rec)-17.4+5.5 (p<0.01). In order to study the mechanism by which Carba activates the Vp cascade, the antagonist of the Vp receptor 2 (AV2; n=10) was used: Control-23.5+5.2, Carba-37.4±4.4 (p<0.01), Carba+AV2-19.6±5.0 (p<0.05), Rec-21.4+5.5; and Control-18.6+7.0, AV2- 27.3+7.2, AV2+Carba-25.3+5.7, Rec-32.6+6.4. The PKA inhibitor (H8; n=4) was also used: Control-15.0+9.0, Carba-106.1+12.3 (p<0,01), Carba+H8-60.3+16.4 (p<0.01), Rec-44.5+13.2. B) the densitometric analysis showed an increased of 38.8% in AQP2 expression (Control- 100.0+8.3 vs. Carba-138.8+12.12, p<0.05); B) In vivo study Urinary volume (UV, mL/24h) Control-10.7+3.0, Li-62.6+6.0 (p<0.001), Li+Carba-28.5+4.9 (p<0.001), Carba-23.3+3.0 (p<0.001). Urinary Osmolality (mOsm/Kg/H2O) Control-819.6+175.7, Li-149.4+18.0 (p<0.01), Li+Carba-251.5+39.7 (p<0.05), Carba-396.2+75.5 (p<0.01). FENa+ (%) - Control- 0.15+0.01, Li-0.10+0.03, Li+Carba-0.12+0.02, Carba-0.11+0.02. AQP2 expression (%) Control-100.0+6.7, Li-55.8+5,4 (p<0.01), Li+Carba-75.8+9.6 (p<0.01), Carba-99.7+4.7 (p<0.05). There were no significant differences in Na+, K+ and plasma osmolality. In summary, our data showed that Carba decreased the UV, increased the UOsm and the AQP2 expression in Li-induced DI, increased the water permeability, probably acting directly in the Vp V2 receptor-Protein G complex, since its action was blocked by the specific Vp V2 receptor antagonist. These results emphazise that the hyponatremia found in patients using Carba could be explained, at least in part, by increased osmotic permeability of IMCD. In addition, poliuria observed in lithium-induced DI can be decreased with Carba-treatment.

Água

Aquaporinas

Aquaporins

Carbamazepina

Carbamazepine

Diabetes insípido nefrogênico

Diabetes insipidus nephrogenic

Hiponatremia

Hyponatremia

Lithium

Lítio

Renal collecting tubules

Túbulos renais coletores

Water