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21	Räumliche und zeitliche Aspekte der intrazellulären pH-Regulation in Epithelien / Spatial and temporal characteristics of intracellular pH-regulation in epithelial cells Schewe, Bettina January 2008 (has links) Die Speicheldrüsen der Schmeißfliege Calliphora vicina produzieren bei Stimulierung mit dem Neurohormon Serotonin (5-Hydroxytryptamine, 5-HT) einen KCl-reichen Primärspeichel. Der transepitheliale K+-Transport wird durch eine apikal lokalisierte vakuoläre H+-ATPase (V-ATPase) energetisiert. Stimulierung der Speicheldrüsen mit 5-HT aktiviert die apikale V-ATPase, die Protonen aus der Zelle in das Drüsenlumen transportiert. Trotz des auswärts gerichteten Protonentransportes führt die 5-HT-Stimulierung kurioserweise zu einer intrazellulären Ansäuerung. Die Ursachen dieser 5-HT-induzierten Ansäuerung waren unzureichend untersucht. Deshalb war das Ziel dieser Arbeit die Identifikation aller Transporter, die an der intrazellulären pH-(pHi)-Regulation in unstimulierten Speicheldrüsen von Calliphora vicina beteiligt sind und an der Entstehung und Regulation der 5-HT-induzierten pHi-Änderungen mitwirken. Von besonderem Interesse war hierbei die funktionelle Mitwirkung der V-ATPase, deren Beteiligung an der pHi-Regulation in tierischen Zellen bisher wenig untersucht war. Wesentliche Ergebnisse dieser Arbeit waren: • Messungen des pHi-Wertes in der unstimulierten Drüse zeigten, dass vor allem die V-ATPase und mindestens ein Na+-abhängiger HCO3--Transporter an der Aufrechterhaltung des Ruhe-pHi beteiligt sind. • Zur Wiederherstellung des Ruhe-pHi nach einer intrazellulären Ansäuerung (NH4Cl-Vorpuls) tragen ebenfalls im Wesentlichen die V-ATPase und mindestens ein Na+-abhängiger HCO3--Transporter bei. Der Na+/H+-Antiporter hat in der unstimulierten Drüse keinen messbaren Einfluss auf den Ruhe-pHi. • Die Wiederherstellung des Ruhe-pHi nach einer intrazellulären Alkalisierung (Na-acetat-Vorpuls) ist Cl--abhängig, aber auch unter extremen Bedingungen waren die Zellen noch in der Lage sich vollständig von einer intrazellullären Alkalisierung zu erholen. Einen entscheidenden Anteil daran hat offenbar die hohe intrazelluläre Puerkapazität. • Ein Na+-abhängiger Glutamat-Transporter ist per se kein pHi-regulierender Transporter, seine Aktivität hat jedoch Einfluss auf den Ruhe-pHi in der unstimulierten Speicheldrüse von Calliphora vicina. • 10 nM 5-HT induzieren in den Calliphora Speicheldrüsen eine intrazelluläre Ansäuerung. An dieser Ansäuerung ist der Na+/H+-Antiporter entscheidend beteiligt. Auch eine klare Cl--Abhängigkeit der 5-HT-induzierten Ansäuerung konnte beobachtet werden. Wahrscheinlich ist eine gekoppelte Aktivität von Na+/H+-Antiporter und Cl-/HCO3--Antiporter. • Messungen mit einem O2-empndlichen Fluoreszenzfarbstoff zeigten, dass Stimulierung der Speicheldrüsen mit 5-HT die Zellatmung aktivierte. Der cAMP- und der IP3/Ca2+-Weg tragen auf komplexe Weise zu der 5-HT-induzierten Aktivierung der Zellatmung und damit auch zu den 5-HT-induzierten pHi-Änderungen bei. • Mit molekularbiologischen Untersuchungen ist es gelungen den Na+-abhängigen Glutamat-Transporter, den Na+/H+-Antiporter, die Carboanhydrase und die Untereinheit C der V-ATPase in den Calliphora Speicheldrüsen direkt nachzuweisen. Zudem konnte erstmals der direkte Nachweis für die Expression eines nH+/K+-Antiporters in den Speicheldrüsen von Calliphora vicina erbracht werden. Diese Arbeit trug ganz wesentlich zum Verständnis der pHi-Regulation in der unstimulierten und stimulierten Speicheldrüse von Calliphora vicina bei. Mechanismen die zur Aufrechterhaltung und Wiederherstellung des Ruhe-pHi nach einer intrazellulären Ansäuerung bzw. Alkalisierung beitragen, konnten mit pHi-Messungen und auch molekularbiologisch nachgewiesen werden. Die Mechanismen, welche die 5-HT-induzierte intrazelluläre Ansäuerung verursachen, konnten ebenfalls aufgeklärt werden. Zudem wurde an den Calliphora Speicheldrüsen eine neue optische Methode zur Messung des O2-Verbrauchs in tierischen Geweben etabliert. / The tubular salivary glands of the blowfly Calliphora vicina consist of a single layer of epithelial cells. Stimulation with the neurohormone serotonin (5-hydroxytryptamine,5-HT) induces the secretion of a KCl-rich primary saliva. Transepithelial K+-transport is energized by a vacuolar-type H+-ATPase (V-ATPase) which is located in the apical membrane. 5-HT stimulates the apical V-ATPase which transports protons out of the cells into the lumen of the glands. Despite this outward directed proton transport, 5-HT stimulation leads to an intracellular acidication. The causes of this intracellular acidication were poorly understood. Therefore the aim of this thesis was the identication of all pHi regulating transporters which are involved in pHi regulation in the unstimulated salivary glands of Calliphora vicina and which contribute to the 5-HT-induced pHi changes. Of special interest was the functional role of the V-ATPase,whose contribution to pHi regulation in animal cells is, as yet, not well studied. Key results were: • pHi measurements in unstimulated glands showed that mainly the V-ATPase and at least one Na+-dependent HCO3--transporter are involved in maintenance of resting pHi. • V-ATPase and at least one Na+-dependent HCO3--transporter are also necessary for the recovery from an intracellular acidication (NH4Cl prepulse). • Recovery from an intracellular alkali load (Na-acetate prepulse) is partially Cl--dependent. • A Na+ dependent gluatamate-transporter is present in Calliphora salivary glands and its activity aects the resting pHi. • 10 nM 5-HT induce an intracellular acidication. This acidication is Na+-dependent, EIPA-sensitive and also Cl--dependent. No DIDS-sensitivity was observed. A coupled activity of a Na+/H+-antiporter and a Cl-/HCO3- -antiporter was suggested. • Using O2-sensitive fluorescent microbeads I could show that 5-HT stimulation of the Calliphora salivary glands activates cellular respiration. The cAMP and Ca2+-signalling pathways contribute in a complex manner to the 5-HT-induced activation of cellular respiration and consequently, also to the 5-HT-induced intracellular acidication. • The expression of a Na+ dependent glutamate-transporter, a Na+/H+-antiporter, a carbonic anhydrase, subunit C of the V-ATPase and a nH+/K+-antiporter were determined on mRNA level by RT-PCR. This thesis contributes signicantly to the understanding of pHi regulation in unstimulated and stimulated salivary glands of Calliphora vicina. Mechanisms which contribute to the maintenance and recovery of resting pHi were identied by using pHi measurements and molecular biological techniques. Mechanisms which are responsible for the 5-HT-induced intracellular acidication were also clarified. Furthermore a new optical method for measuring O2 consumption in animals cells was established by using the Calliphora salivary glands as a model. pH-Regulation V-ATPase Speichelsekretion Epithelien Calliphora pH-regulation V-ATPase saliva secretion epithelia Calliphora Life sciences
22	Processos osmorregulatórios no caranguejo Dilocarcinus pagei (Decapoda, Trichodactylidae), um antigo invasor da água doce: estudo das atividades (Na,K)-ATPase e V-ATPase branquiais / Osmoregulatory processes in the crab Dilocarcinus pagei (Decapoda, Trichodactylidae), an old invader of freshwater: characterization of the gill (Na,K)-ATPase and V-ATPase activities Kelly Cristina Silva Firmino 03 June 2009 (has links) Os crustáceos são originariamente marinhos; ao longo da evolução, diversas espécies invadiram ambientes de salinidades menores, chegando à água doce. A capacidade dos crustáceos colonizarem com sucesso o ambiente dulcícola depende do desenvolvimento de mecanismos eficientes de hiperosmorregulação. A osmolalidade e a composição iônica da hemolinfa de um crustáceo, em meios diluídos, refletem o equilíbrio dinâmico entre a perda de íons por difusão e pela urina e sua reabsorção do meio externo, através das brânquias. A (Na,K)-ATPase branquial desempenha um papel chave no processo de captura de Na+ a partir de ambientes diluídos e suas características cinéticas vem sendo investigadas recentemente, embora as enzimas de caranguejos dulcícolas sejam pouco conhecidas. Segundo o modelo atual, a afinidade por Na+ é o parâmetro cinético mais variável entre as enzimas de diferentes espécies, refletindo a salinidade do habitat do animal, de modo que enzimas de espécies bem adaptadas à água doce apresentam afinidades maiores por Na+. Entretanto, vários resultados conflitantes têm sido relatados nos últimos anos. Recentemente, foi proposto que uma V-ATPase também desempenha papel essencial na captação de Na+ através das brânquias dos crustáceos dulcícolas. Esta enzima ainda é praticamente desconhecida: suas características cinéticas não foram estudadas e a relação entre a magnitude da sua atividade e a salinidade do meio externo não está estabelecida. Este projeto teve por objetivo a caracterização das enzimas (Na,K)-ATPase e V-ATPase das brânquias posteriores do caranguejo hololimnético Dilocarcinus pagei, considerado um antigo invasor da água doce. A (Na,K)-ATPase foi caracterizada em animais mantidos em água doce, a fim de comparar suas propriedades cinéticas com aquelas das enzimas de outras espécies de caranguejos, habitantes de meios mais salinos, visando melhorar o entendimento das adaptações bioquímicas associadas à invasão da água doce. A V-ATPase foi caracterizada em animais mantidos em água doce ou expostos por diferentes intervalos de tempo à salinidade de 21‰ ou ainda aclimatados por 10 dias a diferentes salinidades (5-21‰), visando estabelecer uma relação entre a magnitude da atividade e a salinidade do meio, além de investigar os mecanismos de regulação da atividade da enzima. A análise da fração microsomal branquial de D. pagei mantido em água doce em gradiente contínuo de sacarose mostrou dois picos protéicos (25-35% e 35-45% de sacarose), ambos com atividades K+-fosfatase, (Na,K)-ATPase e V-ATPase. Estes resultados indicam a presença de frações de membrana com densidades distintas, apresentando, em ambos os casos, as principais bombas de íons envolvidas na captação de Na+. Estas membranas podem ser originárias de locais distintos do epitélio branquial posterior assimétrico deste caranguejo. A análise por Western blotting revelou duas bandas imunoespecíficas (Mr 116 kDa e 105 kDa) correspondentes à subunidade α da (Na,K)-ATPase, sugerindo a presença de duas isoformas nas brânquias posteriores do animal. A estimulação da atividade K+-fosfatase da (Na,K)-ATPase pelo PNFF envolveu interações sítio-sítio (nH= 1,4), com V= 43,4 ± 2,2 U mg-1 e K0,5= 1,13 ± 0,06 mmol L-1. A estimulação da atividade da enzima por K+ (V= 39,9 ± 1,9 U mg-1 e K0,5= 4,2 ± 0,2 mmol L-1), Mg2+ (V= 45,0 ± 2,2 U mg-1, K0,5= 0,82 ± 0,04 mmol L-1) e NH4+ (V= 31,7 ± 1,6 U mg-1, K0,5= 19,0 ± 0,9 mmol L-1) também ocorreu por meio de interações sítio-sítio. A afinidade aparente da enzima pelo PNFF e Mg2+ foi similar às relatadas para enzimas de outros crustáceos, incluindo caranguejos habitantes de meios mais salinos. Entretanto, a enzima de D. pagei apresentou menor afinidade aparente por íons K+ que as outras espécies já estudadas. A atividade K+-fosfatase da (Na,K)-ATPase branquial de D. pagei mantido em água doce foi estimulada sinergicamente por K+ e NH4+ sugerindo a presença de dois sítios de ligação para estes íons na molécula da enzima. Ouabaína (4 mmol L-1) inibiu a atividade PNFFase total da preparação (≈ 89%), por meio de uma curva monofásica (KI= 225,6, ± 11,3 µ mol L-1), sugerindo que, se presentes na fração microsomal, as duas isoenzimas da (Na,K)-ATPase apresentam sensibilidades próximas para o inibidor. Ortovanadato (1µmol L-1) inibiu 95% da atividade PNFFase total por meio de uma curva bifásica, reforçando a sugestão da presença de duas isoenzimas na preparação. A hidrólise do ATP pela (Na,K)-ATPase branquial de D. pagei mantido em água doce ocorreu em sítios de alta (V= 6,4 ± 0,32 U mg-1 e K0,5 = 0,34 ± 0,02 µmol L-1) e baixa afinidade (V= 127,1 ± 6,2 U mg-1e KM = 84 ± 4,1 µmol L-1). Não foi encontrada uma correlação direta entre a afinidade pelo ATP e o habitat de diferentes espécies de caranguejos. A atividade (Na,K)-ATPase específica de D. pagei mantido em água doce foi cerca de 3 vezes menor que relatada para Potamon edulis, única espécie de caranguejo dulcícola para a qual este parâmetro foi relatado. Atividades específicas muito maiores foram encontradas para caranguejos estuarinos, particularmente quando aclimatados a salinidades baixas. A baixa atividade específica determinada para D. pagei pode ser atribuída ao baixo gradiente osmoiônico que este animal mantém entre a hemolinfa e o meio externo, comparado a outros caranguejos dulcícolas, que o caracteriza como uma espécie particularmente bem adaptada ao ambiente dulcícola. A estimulação da atividade da enzima por íons Na+ (V = 133,8 ± 7,3 U mg-1e K0,5= 4,7 ± 0,3 mmol L-1), Mg2+ (V= 136,5 ± 8,0 U mg-1, K0,5= 0,62 ± 0,04 mmol L-1), K+ (V = 131,7± 7,9 U mg-1 e K0,5= 0,47 ± 0,03 mmol L-1) e NH4+ (V= 125,6 ± 6,3 U mg-1, K0,5= 1,90 ± 0,09 mmol L-1) ocorreu por meio de interações sítio-sítio. A afinidade aparente por Na+ da enzima de D. pagei é baixa, se comparada às relatadas para outros animais dulcícolas, e similar às encontradas para espécies estuarino/marinhas. Em contraste, a afinidade aparente por K+ é 2,5 a 5 vezes maior que as determinadas para espécies habitantes de meios mais salinos e aparentemente está mais relacionada ao habitat do animal que a afinidade por Na+. Esta possibilidade é coerente com o fato da (Na,K)-ATPase branquial dos crustáceos apresentar os sítios de ligação de K+ expostos para a hemolinfa, o que possibilita a modulação da atividade da enzima pela concentração de K+ na hemolinfa. Ao contrário do observado para várias outras espécies de caranguejos, a atividade (Na,K)-ATPase branquial de D. pagei não foi estimulada sinergisticamente por K+ e NH4+. Entretanto, a presença de um dos íons no meio reacional provoca o aumento da afinidade aparente da enzima pelo outro em cerca de 3 vezes. Fisiologicamente, esta característica cinética pode ser importante para garantir o transporte de ambos os íons pela enzima, mesmo em presença de concentrações relativamente elevadas do outro. Ouabaína (3 mmol L-1) inibiu a atividade ATPase total (≈ 78%) por meio de uma curva bifásica (KI= 6,21 ± 0,32 µmol L-1 e 101,2 ± 5,1 µmol L-1), reforçando os resultados anteriores no sentido de demonstrar a existência de duas isoenzimas da (Na,K)-ATPase nas brânquias posteriores de D. pagei. Observou-se também uma inibição bifásica por ortovanadato (10 µmol L-1), que inibiu a atividade ATPase total em 85%. O pH ótimo para a atividade V-ATPase branquial de D. pagei foi de 7,5. A modulação da atividade V-ATPase do animal mantido em água doce por ATP (V= 26,5 ± 1,3 U mg-1; K0,5= 3,9 ± 0,2 mmol L-1) e Mg2+ (V = 27,9 ± 1,4 U mg-1; K0,5 =0,80 ± 0,04 mmol L-1) ocorreu por meio de interações cooperativas. Já a inibição da atividade ATPase insensível ao ortovanadato por bafilomicina A1 ocorreu segundo uma curva monofásica (KI= 55,0 ± 2,8 nmol L-1). Cerca de 44 % da atividade ATPase total foi inibida, correspondendo à V-ATPase. A atividade V-ATPase branquial de D. pagei diminuiu acentuadamente em resposta à exposição à salinidade de 21‰. Após 1h de exposição, a atividade diminuiu cerca de 3 vezes, chegando a 4 vezes após 24h, o que indica a atuação de mecanismos eficientes de regulação a curto prazo. Curiosamente, a atividade V-ATPase foi cerca de 2 vezes maior para um tempo de aclimatação de 120h a 21‰, comparado a 24 h, embora 2 vezes menor que a estimada em água doce. Passadas 240 h, a atividade voltou aos baixos níveis observados entre 1h e 24h, o que indica a ação de mecanismos de regulação a longo prazo. Além da diminuição da atividade específica também foi observado aumento da afinidade da enzima por ATP (12 vezes) e Mg2+ (3 vezes) em resposta à exposição dos animais a 21‰. Similarmente, ocorreu um aumento de até 190 vezes na afinidade da enzima por bafilomicina A1. Propõe-se que, em resposta à alteração de salinidade, ocorrem mudanças conformacionais tanto em V1 (onde se encontram os sítios de ligação de ATP e Mg2+) quanto V0 (onde se localiza o sítio de ligação de bafilomicina), resultando numa maior exposição do sítio para o inibidor e no aumento da afinidade por Mg2+ e ATP. Como os aumentos de afinidade são observados já após 1h de exposição, este mecanismo parece ser independente da expressão protéica e, portanto, não estaria relacionado à expressão de isoformas diferentes de alguma das subunidades da enzima. A diminuição da atividade V-ATPase branquial de D. pagei em resposta à exposição a uma salinidade elevada é compatível com os mecanismos propostos para a atuação desta enzima no processo de captura ativa de Na+ em crustáceos dulcícolas. Após 10 dias de aclimatação ainda se tem atividade V-ATPase detectável nas frações microsomais das brânquias posteriores do animal, possivelmente envolvida nas funções de regulação ácido-base e excreção de amônia. Os resultados obtidos para a aclimatação de D. pagei por um período de 10 dias a salinidades entre 5 e 21‰ mostraram também uma diminuição acentuada da atividade V-ATPase em resposta ao aumento da salinidade. Entretanto, com exceção da salinidade mais baixa (5‰) não se observou aumento da afinidade da enzima por bafilomicina, sugerindo que esta alteração seja limitada a tempos de aclimatação mais curtos. Entretanto, também se verificou um aumento acentuado da afinidade da enzima por ATP e Mg2+. / Crustacean arose in the sea but, during evolution, several species invaded lower salinity biotopes, reaching fresh water. The ability of crustaceans to successfully colonize the freshwater biotope depends on efficient mechanisms of hyperosmoregulation. In dilute media, crustaceans\' hemolymph osmolality and ionic composition reflect a balance between diffusive and urinary ion losses, and active ion capture through the gills. The gill (Na,K)- ATPase plays a pivotal role in Na+ capture from dilute environments and its kinetic characteristics are under investigation in recent years, although freshwater crab enzymes are poorly known. According to the most recent model, the apparent affinity for Na+ is the most variable kinetic parameter among gill enzymes from different species, and reflects the salinity of the species\' habitat. Thus, enzymes from species which are well adapted to freshwater usually present higher affinities for Na+. However, several recent results are incompatible with this model. On the other hand, it has been proposed that a V-ATPase is also involved in Na+ capture through the gills of hololimnetic crustaceans. This enzyme is almost completely unknown: its kinetic characteristics have not been studied yet and the relationship between the magnitude of its activity in the gills and the external medium salinity has not been established. This work aimed to characterize the (Na,K)-ATPase and V-ATPase from the posterior gill from the holimnetic crab Dilocarcinus pagei, considered an old fresh water colonizer. The (Na,K)- ATPase was characterized in animals maintained in fresh water, in order to establish a comparison of its kinetic properties with those of enzymes from other crab species that inhabit more saline media. This comparison may enhance our understanding of the biochemical adaptations associated to fresh water invasion. V-ATPase was characterized in animals kept in fresh water or exposed for varying time intervals to a medium of 21? salinity, or else acclimated for 10 days to media of different salinities (5-21?), aiming to establish a relationship between the enzyme specific activity in the gill tissue and the external salinity, and also investigate the mechanisms involved in enzyme activity regulation. The analysis of D. pagei gill microsomes in a continuous-density sucrose gradient revealed two protein peaks (25-35% and 35-45% sucrose), both showing K+-phosphatase, (Na,K)-ATPase and V-ATPase activities. These results indicate the presence of membrane fractions of distinct densities, both presenting the main ion pumps involved in Na+ capture. These membranes may originate from different places in the asymmetric posterior gill epithelium from this crab. Western compared to those reported for other freshwater animals, but similar to those found for estuarine/marine species. In contrast, the apparent affinity for K+ is 2.5 to 5-fold higher than those estimated for species that inhabit more saline media, and is apparently more related to the animals\' habitat than Na+ affinity. This possibility is consistent with the location of the (Na,K)-ATPase in crabs gill tissue, with K+ binding sites exposed to the hemolymph, allowing the direct modulation of enzyme activity by hemolymph K+ concentration. In contrast to data reported for other crab species, D. pagei gill (Na,K)-ATPase activity was not synergistically stimulated by K+ and NH4 +. However, the presence of one of these ions in the reaction medium results in an increase of about 3-fold in the apparent affinity of the enzyme for the other. This kinetic characteristic may be physiologically relevant to assure the transport of both ions, even in the presence of elevated concentrations of the other. Ouabain (3 mmol L-1) inhibited total ATPase activity (? 78%) through a biphasic curve (KI= 6.21 ± 0.32 mol L-1 and 101.2 ± 5.1 mol L-1) reinforcing previous results suggesting the presence of two isoenzymes in the microsomal preparations. A biphasic inhibition by orthovanadate (10 mol L-1) to about 15% residual activity was also observed. Optimal pH for D. pagei gill V-ATPase activity was 7.5. The modulation of enzyme activity of the animal kept in fresh water by ATP (V= 26.5 ± 1.3 U mg-1; K0.5= 3.9 ± 0.2 mmol L-1) and Mg2+ (V = 27.9 ± 1.4 U mg-1; K0.5 =0.80 ± 0.04 mmol L-1) occurred with positive cooperativity. The inhibition of the orthovanadate insensitive ATPase activity by bafilomycin A1 followed a monophasic curve (KI= 55.0 ± 2.8 nmol L-1). About 44 % of total ATPase activity was inhibited, corresponding to the V-ATPase. Dilocarcinus pagei gill V-ATPase activity substantially decreased in response to animal\'s exposure to 21? salinity. After 1h exposure, the activity diminished about 3-fold, reaching 4- fold after 24h, indicating the action of efficient short-time regulation mechanisms. Interestingly, V-ATPase activity was about 2-fold higher after 120h exposure, compared to 24h, although 2- fold lower compared to that estimated in fresh water. After 240h, the activity returned to the low levels observed for 1 and 24 h, indicating efficient long-term regulation. Besides the decrease in specific activity, it was also observed an increase in enzyme\'s apparent affinity for ATP (12 fold) and Mg2+ (3 fold) in response to animal\'s exposure to 21? salinity. Simultaneously, the enzyme\'s affinity for bafilomycin A1 increased up to 190-fold. We propose that, in response to salinity alteration, conformational changes take place both in V1 (in which the ATP and Mg2+ binding sites are located) and V0 (which contains the bafilomycin A1 bindind site), resulting in higher exposition of the inhibitor binding site and also higher affinity for Mg2+ and ATP. As the affinity increases are observed after just 1h exposure, this regulatory mechanism seems to be independent of protein expression and, thus, should not be related to the expression of distinct isoforms of some enzyme subunit. The lowering of gill V-ATPase activity in D. pagei in response to exposure to an elevated salinity is consistent with the mechanisms proposed for the role of this enzyme in active Na+ capture in hololimnetic crustaceans. After 10 days at 21, the gill microsomal fractions still show a little V-ATPase activity, possibly related to acid-base regulation and ammonia excretion processes. The results obtained for the acclimation of D. pagei for 10 days at salinities in the range 5 to 21? also showed a substantial decrease of V-ATPase activity in response to the increase in medium salinity. However, except for 5?, it was not observed an increase of enzyme\'s affinity for bafilomycin, suggesting that this alteration is limited to shorter periods of exposure. However, a significant increase in the enzyme\'s affinity for ATP and Mg2+ was also observed. (Na Brânquias Dilocarcinus pagei K)-ATPase Osmorregulação V-ATPase (Na Dilocarcinus pagei Gills K)-ATPase Osmoregulation V-ATPase
23	Fisiologia molecular digestiva da larva de Musca domestica / Digestive molecular physiology of Musca domestica larvae André Coppe Pimentel 21 November 2011 (has links) A digestão nos insetos ocorre no intestino médio de forma compartimentada. A digestão inicial dos polímeros ocorre no interior da membrana peritrófica. Os oligômeros resultantes difundem-se para o espaço luminal exterior à membrana peritrófica onde são atacados por outras enzimas. Na digestão final os dímeros resultantes são hidrolisados por enzimas imobilizadas na superfície do epitélio do intestino médio. Após o processo de digestão final os monômeros são absorvidos pelas células do epitélio intestinal. Os Díptera ditos superiores, incluindo a mosca doméstica, apresentam peculiaridades digestivas que aparentemente resultam de adaptações para digerir uma dieta que consiste principalmente de bactérias. No ventrículo anterior ocorre uma diminuição no conteúdo de amido do bolo alimentar. Na porção seguinte, o bolo alimentar passa para o ventrículo médio onde as bactérias são mortas pela ação combinada de baixo pH, uma lisozima digestiva e uma proteinase tipo catepsina D. O material liberado das bactérias é digerido no ventrículo posterior, como ocorre no ventrículo inteiro da maioria dos insetos de outros grupos taxonômicos. Com o objetivo de compreender a peculiar digestão em Musca domestica, foram utilizadas suas larvas para identificar funcionalmente as regiões absortivas de nutrientes, identificar as moléculas envolvidas na absorção de nutrientes, identificar as moléculas envolvidas com tamponamento e fluxos de fluidos intestinais, sequenciar as enzimas digestivas principais e identificar os seus sítios de secreção. Experimentos fisiológicos de absorção de glicose e análises de atividade enzimática permitiram acessar de maneira direta os aspectos da digestão. Contudo, experimentos de sequenciamento de bibliotecas de cDNA, análise de sequências transcritas e verificação de expressão de genes em diferentes tecidos foram abordagens fundamentais na identificação das moléculas subjacentes aos processos fisiológicos intestinas de Musca domestica. Os indícios de que absorção de glicose no intestino de Musca domestica se dê por transportadores do tipo SGLT, com a possível participação de facilitadores do tipo GLUT, permitem estabelecer um foco para futuros estudos. A descrição de sequências relacionadas ao tamponamento intestinal permitiu ampliar a discussão sobre tal processo. Ao detalhar os sítios de expressão da subunidade a da V-ATPase, do canal de cloreto e do transportador de amônia foi possível testar o modelo de tamponamento proposto anteriormente e propor a participação de outras moléculas no processo. Sequências correspondentes as atividades de carboxipeptidase, maltase e aminopeptidase descritas na literatura foram pesquisadas, gerando sequências candidatas a codificarem as referidas enzimas. Com isso, é possível descrever a digestão de oligômeros e dímeros com base nos genes transcritos e nas sequências de aminoácidos que formam as enzimas digestivas. A descoberta da sequência que transcreve uma metaloproteinase, por sua vez, abre caminhos para a descrição e caracterização de sua atividade proteolítica nos tecidos digestivos da larva de Musca domestica. Essa análise permitiu também elucidar a localização dos sítios de expressão e, portanto, as zonas de secreção de enzimas. De maneira geral, este estudo contribuiu para a compreensão de diversos aspectos da digestão de Musca domestica, elucidando questões da particular fisiologia digestiva desse inseto. / Digestion in insects occurs in the midgut in a compartmentalized way. Initial digestion takes place inside the peritrophic membrane. The resulting oligomers diffuse into the luminal space outside the peritrophic membrane where they are hydrolyzed by other enzymes. In the final digestion, the resulting dimers are hydrolyzed by enzymes immobilized on the midgut epithelium. After the final digestion, the monomers are absorbed by intestinal epithelial cells. The so-called higher Diptera, including the house fly, have digestive peculiarities apparently resulting of adaptations to digest a diet consisting mainly of bacteria. In the anterior midgut there is a decrease in the starch content of the food bolus. The bolus now passes into the middle midgut, where bacteria are killed by the combined action of low pH, a special lysozyme and a cathepsin D-like proteinase. Finally, the material released by bacteria is digested in the posterior midgut, as is observed in the whole midgut of insects of other taxa. In order to understand the peculiar digestion in Musca domestica, the larvae were used to identify (a) the functionally the nutrient absorptive regions, (b) the molecules involved in the absorption of nutrients, (c) the molecules involved in buffering and fluid flows, (d) the cDNA sequences corresponding to intestinal digestive enzymes, (e) the main sites of secretion. Physiological experiments of glucose absorption and enzyme activity analysis allowed a direct access to aspects of digestion. Otherwise, cDNA library sequencing followed by sequence annotation and tissue-specific expression analysis were fundamental approaches in the understanding of intestinal physiology of Musca domestica. Evidence that glucose absorption in the gut of Musca domestica occurs through SGLT-like transporters, with the possible participation of facilitators GLUT-like, allowed us to establish a focus for future studies. The description of cDNA sequences corresponding to proteins putatively responsible for intestinal buffering widened the discussion of this process. The finding of the expression sites of V-ATPase subunits, chloride channel, and ammonia transporter led to revising the present buffering model and the inclusion of other molecules in the process. The cDNA sequences corresponding to the activities of carboxypeptidase, aminopeptidase and maltase described in the literature were searched for as candidate sequences to encode those enzymes. This made it possible to describe the digestion of oligomers and dimers based on transcribed genes and enzyme amino acid sequences. The discovery of the metalloproteinase transcribing sequence opened a new research line: the description and characterization of its proteolytic activity in the midgut of the Musca domestica larvae. This study also allowed elucidating the location of digestive enzyme expression sites and, therefore, the putative zones of enzyme secretion. Overall, this study contributed to understanding many aspects of digestion of Musca domestica, clarifying aspects of the peculiar digestive physiology of this insect. Cyclorrarpha Digestão ácida Digestão final Diptera Transportador de glicose V-ATPase Acid digestion Cyclorrarpha Diptera Final digestion Glucose transporter V-ATPase
24	Efeito do Ãcido abscÃsico nas bombas de prÃtons vacuolares e enzimas antioxidantes em Vigna unguiculata (L.) Walp / Effect of abscisic acid in vacuolar proton pumps and antioxidant enzymes in Vigna unguiculata (L.) Walp Deborah Moura RebouÃas 16 February 2011 (has links) Conselho Nacional de Desenvolvimento CientÃfico e TecnolÃgico / O Ãcido abscÃsico (ABA) Ã um fitohormÃnio que desempenha papÃis crÃticos na regulaÃÃo das respostas das plantas ao crescimento e desenvolvimento. O vacÃolo de plantas superiores Ã uma organela que ocupa a maior parte da cÃlula. A condiÃÃo de acidez Ã mantida por duas bombas de prÃtons distintas, V-ATPase e V-PPase. Sabe-se que estas bombas de prÃtons desempenham um papel essencial nas respostas das plantas Ãs mudanÃas ambientais. O gradiente eletroquÃmico promovido por essas enzimas Ã a forÃa motriz para o acÃmulo de Ãons e outros solutos no vacÃolo, sendo importante para manter a homeostase citosÃlica de Ãons e o metabolismo celular. As enzimas antioxidantes constituem um sistema de defesa contra as espÃcies reativas de oxigÃnio, que podem provocar danos ao desenvolvimento das plantas. O objetivo deste trabalho foi estudar o efeito do Ãcido abscÃsico nos parÃmetros de crescimento e fisiolÃgicos, bem como o efeito na atividade hidrolÃtica e na expressÃo de transcritos das bombas de prÃtons vacuolares e na atividade de enzimas antioxidantes de plantas de Vigna unguiculata. As sementes de V. unguiculata foram germinadas em areia, onde cresceram por 15 dias, com aplicaÃÃo de soluÃÃo nutritiva de Hoagland na ausÃncia (controle) ou presenÃa de ABA 0,1 ÂM no terceiro, no sÃtimo e no dÃcimo dias apÃs a germinaÃÃo. Os efeitos do Ãcido abscÃsico (ABA) sobre o crescimento, a condutÃncia estomÃtica, a transpiraÃÃo, a fotossÃntese, a concentraÃÃo interna de CO2, a atividade e a expressÃo da subunidade A da V-ATPase e da V-PPase e a atividade de enzimas antioxidantes de Vigna unguiculata foram analisados. ABA aumentou o crescimento das plantas, mas nÃo afetou os parÃmetros fisiolÃgicos; induziu um aumento na atividade hidrolÃtica da V-ATPase em folhas e da V- PPase em raÃzes; aumentou os transcritos de VuVHA-A e de VuVHP em folhas e diminuiu os transcritos de VuVHA-A em raÃzes e, por fim, causou aumento na atividade da catalase de folhas e de raÃzes. Esses resultados sugerem que o Ãcido abscÃsico regula a atividade e a expressÃo dos genes das bombas de prÃtons vacuolares, bem como as atividades de enzimas antioxidantes, sendo portanto importantes efetores que regulam o desenvolvimento de plantas de V. unguiculata. / Abscisic acid (ABA) is a phytohormone that plays critical roles in regulating plant responses to growth and development. The vacuole of higher plants is an organelle that occupies a larger part of the cell. The acidic condition is maintained by two distinct proton pumps, VATPase and V-PPase. It is known these proton pumps play essential roles in plant responses to environmental changes. The electrochemical gradient promoted by these enzymes is the driving force for the accumulation of ions and other solutes in the vacuole, being important to maintain cytosolic ion homeostasis and cellular metabolism. Antioxidant enzymes constitute a defense system against reactive oxygen species, which can cause damage to plant development. The aim of this study was to study the effect of the abscisic acid in the growth and physiological parameters, as well as the effect on vacuolar proton pumps and antioxidant enzymes (SOD, CAT and APX) from Vigna unguiculata cv. Pitiuba. The seeds of V. unguiculata were germinated in sand and grown for 15 days, with application of Hoagland solution in the absence (control) or presence of 0.1 ÂM ABA in the third, seventh and tenth days after germination.The effects of the abscisic acid (ABA) on the growth, stomatal conductance, transpiration, photosynthesis, internal CO2 concentration, V-ATPase subunit A and V-PPase activities and expression and antioxidant enzymes activities of Vigna unguiculata were analyzed. ABA increased the plants growth but did not affect the physiological parameters; induced an increase on V-ATPase hidrolytyc activity in leaves and on V-PPase in roots; ABA increased the transcripts of VuVHA-A and VuVHP in leaves and decreased the VuVHA-A transcripts in roots; caused increase in the leaves and roots catalase activity. These results suggest that the abscisic acid regulate the activity and the genes expression of the vacuolar proton pumps, as well as the antioxidant enzymes activity, being thus important effectors that regulate the development of V. unguiculata plants. Ãcido AbscÃsico Enzimas Antioxidantes V-ATPase Vigna Unguiculata (L.) Walp V-PPase Abscisic Acid Enzymes Antioxidants V-ATPase Vigna unguiculata (L.) Walp V-PPA BIOQUIMICA
25	Molecular identification and characterization of novel osteoclast V-ATPase subunits Cheng, Tak Sum January 2008 (has links) [Truncated abstract] Osteoclasts are multinucleated giant cells responsible for the resorption of the mineralized bone matrix during the process of bone remodelling. During activation towards bone resorption, polarization of the osteoclast results in the formation of a unique plasma membrane, the ruffled border, the actual resorptive organelle of the osteoclast. Through this domain protons are actively pumped into the resorption lacuna creating an acidic microenvironment that favours the dissolution of the mineralized bone matrix. The polarised secretion of protons is carried out by the action of the vacuolar-type (H+)-ATPase (V-ATPase), composed of functionally and structurally distinct subunits of the V1 and V0 domains. The general structure of the V-ATPase complex is highly conserved from yeast to mammals, however, multiple isoforms for specific V-ATPase subunits do exist exhibiting differential subcellular, cellular and tissue-specific localizations. This study focuses on the molecular identification and characterization of V-ATPase accessory subunit Ac45 and the d2 isoform of the V0 domain d subunit in osteoclasts. Using the techniques of cDNA Subtractive Hybridization and DNA Micro-Array analyses respectively, the accessory subunit Ac45 and the d2 isoform of the V0 domain d subunit were identified in RAW264.7-cells derived OcLs. ... Using web-based computational predictions, two possible transmembrane domains, an N-terminus 'signal anchor' sequence and a C-terminus dilysine- like endoplasmic reticulum (ER) retention signal were identified. By confocal microscopy, EYFP-tagged e was found to localize to the perinuclear region of transfected COS-7 cells in compartments representing the ER and Golgi apparatus with some localization in late endosomal/lysosomal-like vesicles. ER truncation of e did not alter its subcellular localization but exhibited significantly weaker association with Ac45 compared to the wild-type as depicted by BRET analyses. Association with the other V0 subunits remain unaffected. This may hint at a possibility that Ac45 may play a role in the masking of the ER signal of e following it's incorporation into the V0 domain. Although no solid evidence for a role in the assembly of the mammalian VATPase have been established, subunit e still represents a potential candidate whose role in the V-ATPase complex requires further investigation. Collectively, the data presented in this thesis has provided further insight into the composition of the osteoclast V-ATPase proton pump by: 1) identifying an accessory subunit, Ac45 which shows promise as a potential candidate for the regulation and/or targeting of the V-ATPase complex in osteoclasts and truncation of its targeting signal impairs osteoclastic bone resorption; 2) identification and preliminary characterization of the d2 isoform of the V0 domain d subunit whose exact role in the V-ATPase complex and in osteoclasts remains to be determined, although its has been implicated to be essential for osteoclastic function; and 3) Preliminary characterization of subunit-e, a potential assembly factor candidate for the mammalian V-ATPase V0 domain. Osteoclasts Bone resorption -- Molecular aspects Bones -- Diseases Bones -- Molecular aspects Bone cells Adenosine triphosphatase V-ATPase
26	The Effects of Hypoxia with Concomitant Acidosis on Prostate Cancer Cell Survival Faysal, Joanne M. 01 January 2010 (has links) Prostate cancer is the second most common cancer among men in the United States. While treatments for prostate cancer exist, none are curative. As a solid tumor, prostate cancer can grow beyond the diffusion limits of oxygen, thereby resulting in a hypoxic environment. While hypoxia can cause death to a variety of cell types, tumor cells can develop resistance to hypoxia and survive under minimal oxygen conditions. Hypoxia in tumor cells has also been associated with poor prognosis, increased metastasis, and decreased efficacy of chemotherapy. BNIP3, a BH-3 only proapoptotic Bcl-2 family member, has been shown to play an important role in cell death under hypoxic conditions in a variety of cell types. In normoxia, BNIP3 shows little to no expression in both cardiomyocytes and many cancer cell types, but is then upregulated under hypoxic conditions. Previous work in our laboratory provides evidence that hypoxia alone, as well as the concomitant increase in BNIP3 expression, cannot cause death of rat neonatal cardiomyocytes. Instead, our studies found that hypoxia with concomitant intracellular acidosis is required. Further studies indicated that BNIP3 is also necessary for hypoxia-acidosis associated cell death in cardiomyocytes. Our results in rat neonatal cardiomyocytes led us to hypothesize that cell death could be induced in hypoxic prostate cancer cells if concomitant acidosis could be induced. Additionally, our intention was to determine if BNIP3 was required for any prostate cancer cell death that may occur under hypoxia-acidosis conditions.
27	Studies of Intracellular Transport and Anticancer Drug Action by Functional Genomics in Yeast Gustavsson, Marie January 2008 (has links) This thesis describes the use of functional genomics screens in yeast to study anticancer drug action and intracellular transport. The yeast Saccharomyces cerevisiae provides a particularly useful model system for global drug screens, due to the availability of knockout mutants for all yeast genes. A complete collection of yeast deletion mutants was screened for sensitivity to monensin, a drug that affects intracellular transport. A total of 63 deletion mutants were recovered, and most of them were in genes involved in transport beyond the Golgi. Surprisingly, none of the V-ATPase subunits were identified. Further analysis showed that a V-ATPase mutant interacts synthetically with many of the monensin-sensitive mutants. This suggests that monensin may act by interfering with the maintenance of an acidic pH in the late secretory pathway. The second part of the thesis concerns identification of the underlying causes for susceptibility and resistance to the anticancer drug 5-fluorouracil (5-FU). In a functional genomics screen for 5-FU sensitivity, 138 mutants were identified. Mutants affecting tRNA modifications were particularly sensitive to 5-FU. The cytotoxic effect of 5-FU is strongly enhanced in these mutants at higher temperature, which suggests that tRNAs are destabilized in the presence of 5-FU. Consistent with this, higher temperatures also potentiate the effect of 5-FU on wild type yeast cells. In a plasmid screen, five genes were found to confer resistance to 5-FU when overexpressed. Two of these genes, CPA1 and CPA2 encode the two subunits of the arginine-specific carbamoyl-phosphate synthase. The three other genes, HMS1, YAE1 and YJL055W are partially dependent on CPA1 and CPA2 for their effects on 5-FU resistance. The specific incorporation of [14C]5-FU into tRNA is diminished in all overexpressor strains, which suggest that they may affect the pyrimidine biosynthetic pathway. 5-fluorouracil tRNA modifications Saccharomyces cerevisiae carbamoyl phosphate synthase V-ATPase Functional genomics Funktionsgenomik
28	Inhibition of pH regulation as a therapeutic strategy in breast cancer Meehan, James January 2017 (has links) The abnormal regulation of H+ ions, leading to a reversed pH gradient in cancer cells when compared to normal cells, is considered to be one of the most distinctive features of cancer. However, this characteristic has yet to be fully exploited as a therapeutic target in cancer. This project assessed whether targeting pH regulating proteins, which permit cancer cells to survive in the hostile hypoxic and acidic tumour microenvironment, could produce an effective therapeutic response in breast cancer. The pH regulating proteins carbonic anhydrase IX (CAIX), Na+/H+ exchanger 1 (NHE1) and vacuolar (H+)-ATPase (V-ATPase) were the focus of this thesis. Initial experiments were conducted in 2D tissue culture before progressing into 3D, using models that more faithfully re-create the in vivo tumour microenvironment. Expression analysis conducted with MCF-7, MDA-MB-231 and HBL-100 human breast cancer cell lines cultured in 2D, and in 3D as multicellular tumour spheroids, showed that protein and mRNA levels of CAIX were very responsive to lower O2 concentrations. Both MDA-MB-231 and HBL-100 cells displayed large increases in CAIX expression levels in hypoxia, with the HBL-100 cell line exhibiting the largest change in CAIX mRNA (42-fold increase) and protein (78-fold increase) levels in 0.5% O2 conditions. Hypoxia inducible factor 1-α (HIF-1α) controls the expression of CAIX, but the induction of CAIX in hypoxic MCF-7 cells was lower in comparison to the other cell lines, despite the presence of similar levels of HIF-1α. The differences in CAIX expression observed between the cell lines was consistent with a varying activity of factor inhibiting HIF-1 (FIH-1), an oxygen sensor that controls signalling through HIF-1α, as siRNA targeting FIH-1 led to increased levels of CAIX in hypoxic MCF-7 cells. While NHE1 protein levels did increase in hypoxic conditions in MCF-7 cells in 3D, overall, the expression levels of both NHE1 and V-ATPase were not as responsive to changes in O2 concentrations when compared to CAIX across differing O2 conditions in each of the cell lines. Inhibitors targeting CAIX, NHE1 and V-ATPase were all shown to reduce cancer cell number in 2D culture conditions. Differing O2 conditions changed the sensitivity of these cell lines to CAIX inhibition. Cells cultured in 20% O2 conditions were responsive to CAIX inhibition, while acute hypoxic cells cultured in 0.5% O2 displayed an increased resistance to drug treatment. Chronically hypoxic cells, which had spent over 10 weeks in 0.5% O2 before treatment, exhibited a re-sensitisation to CAIX inhibition. 3D invasion assays demonstrated that CAIX inhibition significantly reduced the invasion of cells from MDA-MB-231 spheroids into collagen type 1 in both 20% O2 and 0.5% O2 conditions, while drugs targeting either NHE1 or V-ATPase had no such inhibitory effects. Preliminary clonogenic assays, used to assess radiation sensitivity and performed with MDA-MB-231 spheroids, indicated that inhibitors targeting CAIX and NHE1 led to a significant decrease in colony formation when combined with irradiation, compared to either drug treatment or irradiation alone. Further invasion assays, carried out with primary tissue derived from human patients, showed that drugs targeting CAIX retained their inhibitory effects when tested on heterogeneous cancer material of varying tumour subtypes. CAIX inhibition also exhibited anti-cancer effects in vivo on mouse MDA-MB-231 xenografts, significantly reducing the proliferation and growth of tumours within mice. Together, this work demonstrates that inhibitors targeting the pH regulation mechanisms of cancer cells have potential in the treatment of breast cancer, highlighted by their capacity to affect cancer cell number, cancer cell invasion, and their ability to combine with irradiation. Of the 3 pH regulatory molecules studied, CAIX appears to be the target with the most therapeutic potential.
29	Evolution of the Vacuolar H+-ATPase Enzyme Complex Finnigan, Gregory Charles, 1983- 06 1900 (has links) xvii, 167 p. : ill. (some col.) / The vacuolar proton-translocating ATPase (V-ATPase) is a multisubunit enzyme complex responsible for acidification of cellular organelles. The V-ATPase hydrolyzes ATP to pump protons across membranes to create an electrochemical gradient. Acidification of vesicular compartments is critical in numerous biological processes including protein trafficking, endocytosis, and ion homeostasis; defects in V-ATPase function can also lead to human diseases. While the function of the V-ATPase enzyme is highly conserved across eukaryotes, the molecular architecture of this protein complex has undergone unique structural changes through evolutionary time. The goal of this work is to investigate the assembly, transport, and evolution of this critical molecular machine in the model organism <italic>Saccharomyces cerevisiae</italic>. A series of genetic screens was performed in budding yeast to identify factors and pathways that are involved in promoting full V-ATPase function. I utilized several "assembly factor" alleles to serve as sensitized genetic backgrounds to partially reduce enzyme function; this work implicated sphingolipid composition in promoting full vacuolar ATPase enzyme function. I also used ancestral gene reconstruction to analyze the two isoforms of subunit a of the V<sub>0</sub> subdomain (Vph1p and Stv1p) by recreating the most recent common ancestral subunit (Anc.a). Characterization of Anc.a demonstrated that this ancient subunit was able to properly assemble and function within a hybrid V-ATPase complex. While the Vph1p-containing complex localized to the vacuole membrane and the Stv1p-containing complex was present on the Golgi/endosome, incorporation of Anc.a caused the V-ATPase to localize to both types of cellular compartments. Finally, I used ancestral reconstruction to investigate the lineage-specific gene duplication of one of the proteolipid subunits of the V<sub>0</sub> subcomplex that occurred within the fungal clade. I demonstrate that inclusion of a third proteolipid subunit within fungi (as compared to two subunits within metazoans) could have occurred via neutral processes by asymmetric degeneration of subunit-subunit interfaces that "ratcheted" the duplicated subunit with the V<sub>0</sub> ring. These results present a model that describes how macromolecular machines can increase in complexity through evolutionary time. This dissertation includes previously published co-authored material and unpublished co-authored material. / Committee in charge: George Sprague, Chairperson; Tom H. Stevens, Advisor; Victoria Herman, Member; Bruce Bowerman, Member; Ken Prehoda, Outside Member Molecular biology Genetics Biology Ancestral reconstruction Molecular evolution Protein trafficking V-ATPase Yeast genetics
30	Sorting and retention of the Golgi form of the V-type ATPase in yeast Cronan, Glen Emerson, 1977- 06 1900 (has links) xii, 45 p. : col. ill. / Regulated acidification of intercellular organelles and vesicles is essential for many cellular processes, from basic metabolism and protein sorting to synapse function and developmental signaling. These diverse processes are driven by spatiotemporal regulation of the V-ATPase, the cellular H + -pump. In yeast and higher eukaryotes V-ATPase localization is directed by the 100-kDa "a" subunit, and many human diseases are linked to mutations in "a". Saccharomyces cerevisiae contains two "a" isoforms, VPH1 and STV1, with all other V-ATPase subunits encoded for by single genes. The V-ATPase contains only one "a" subunit per complex. Complexes that contain Vph1p localize to the vacuole (lysosome), and Stv1p-containing complexes localize to the late Golgi/endosome. Here I present a set of STV1 mutants that are disrupted for Golgi retention but not V-ATPase assembly or enzymatic function. Using a forward genetic screen I defined multiple residues within a 39 amino-acid region of Stv1p that are necessary for Stv1p retention to the Golgi. The residues most strongly affecting Golgi localization are present in a small STV1 -specific insertion of eight residues, suggesting they may bind directly to sorting machinery. However, I also find that Stv1p/Vph1p chimeras containing the STV1 -specific insertion are not sufficient to direct Golgi retention in both minimal (13AA) and expanded (49AA) contexts. I conclude that the Stv1p Golgi retention signal is composed of a complex binding surface, of which the central element is a short peptide rich in amino acids with aromatic side chains. / Committee in charge: Bruce Bowerman, Chairperson; Tom H. Stevens, Advisor; Karen Guillemin, Member; George F. Sprague Jr., Member Kenneth E. Prehoda Outside Member Molecular biology Genetics Biological sciences Hydrogen ion pump Golgi retention Acidification Sorting V-ATPase

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