ABSTRACT
Cationic amino acid transporters (CATs) play a central role in the supply of the substrate L-arginine to intracellular nitric oxide synthases (NOS), the enzymes responsible for the synthesis of nitric oxide (NO). In heart, NO produced by cardiac myocytes has diverse and even opposite effects on myocardial contractility depending on the subcellular location of its production. Approximately a decade ago, using a combination of biophysical and biochemical approaches, we discovered and characterized high- and low-affinity CATs that function simultaneously in the cardiac myocyte plasma membrane. Later on, we reported a negative feedback regulation of NO on the activity of cardiac CATs. In this way, NO was found to modulate its own biosynthesis by regulating the amount of L-arginine that becomes available as NOS substrate. We have recently solved the molecular determinants for this NO regulation on the low-affinity high-capacity CAT-2A. This review highlights some biophysical and biochemical features of L-arginine transporters and their potential relation to cardiac muscle physiology and pathology.
ABSTRACT
Imbalance in nutrients can affect digestibility of amino acids by altering gene expression of amino acid transporters. We investigated digestibility and molecular transporters of essential amino acids in chickens fed a methionine-deficient diet. A total of 40 chicks (23 D old) were randomly assigned to either a control (0.49% methionine) or a deficient (0.28%) diet until 41 D when they were sampled for Pectoralis (P.) major, kidney, ileum, and hypothalamus for mRNA expression analysis. The ileal content was collected for apparent ileal digestibility (AID) analysis. Birds fed the deficient diet had reduced growth and worse feed efficiency compared to control. The AID of methionine was similar between both groups. The AID of other essential amino acids was higher in the deficient group than control. mRNA expression of b0,+ AT and LAT4 were upregulated in the ileum and kidney but LAT1 was downregulated only in kidney of the deficient group compared to control. In the P. major, SNAT1, SNAT2, and CAT1 were upregulated in the deficient group compared to control. A diet deficiency in methionine affects digestibility of essential amino acids and cysteine, but not the digestibility of methionine. The change in digestibility is reflected in the mRNA expression of amino acid transporters across different tissues.
Subject(s)
Amino Acid Transport Systems/genetics , Avian Proteins/genetics , Chickens/physiology , Digestion/drug effects , Gene Expression/drug effects , Methionine/deficiency , Amino Acid Transport Systems/metabolism , Animal Feed/analysis , Animal Nutritional Physiological Phenomena/drug effects , Animals , Avian Proteins/metabolism , Chickens/genetics , Chickens/growth & development , Diet/veterinary , MaleABSTRACT
In Lutzomyia longipalpis females, which are the main vectors of Leishmania infantum in the Americas, hematophagy is crucial for ovary development. The control of pH in the midgut during blood digestion is important to the functioning of the digestive enzymes, which release amino acids in the luminal compartment that are then transported through the enterocytes to the hemolymph for delivery to the ovary and other organs. In the present work, we investigated transport systems known as LuloPATs that are present in the midgut of L. longipalpis but not in other organs. These transporters achieve symport of amino acids with H+ ions, and one of them (LuloPAT1) is orthologous to a transporter described in Aedes aegypti. According to our results, the transcription levels of LuloPAT1 increased significantly immediately after a blood meal. Based on the variation of the fluorescence of fluorescein with the pH of the medium, we developed a technique that shows the acidification of the cytoplasm of gut cells when amino acids are cotransported with H+ from the lumen into the enterocytes. In our experiments, the midguts of the sandflies were dissected and opened longitudinally so that added amino acids could enter the enterocytes via the lumen (PAT carriers are apical). LuloPAT1 transporters are part of a complex of mechanisms that act synergistically to promote gut alkalinization as soon as blood intake by the vector occurs. In dissected but not longitudinally opened midguts, added amino acids could only enter through the basolateral region of enterocytes. However, alkalinization of the lumen was observed because the entry of some amino acids into the cytoplasm of enterocytes triggers a luminal alkalinization mechanism independent of LuloPATs. These findings provide new perspectives that will enable the characterization of the set of signaling pathways involved in pH regulation within the L. longipalpis midgut.
Subject(s)
Amino Acids/physiology , Protons , Psychodidae/physiology , Symporters/physiology , Animals , Gastrointestinal Tract/physiologyABSTRACT
Glutamate, the main excitatory neurotransmitter in the vertebrate brain, exerts its actions through specific membrane receptors present in neurons and glial cells. Over-stimulation of glutamate receptors results in neuronal death, phenomena known as excitotoxicity. A family of sodium-dependent, glutamate uptake transporters mainly expressed in glial cells, removes the amino acid from the synaptic cleft preventing neuronal death. The sustained sodium influx associated to glutamate removal in glial cells, activates the sodium/potassium ATPase restoring the ionic balance, additionally, glutamate entrance activates glutamine synthetase, both events are energy demanding, therefore glia cells increase their ATP expenditure favouring glucose uptake, and triggering several signal transduction pathways linked to proper neuronal glutamate availability, via the glutamate/glutamine shuttle. To further characterize these complex transporters interactions, we used the well-established model system of cultured chick cerebellum Bergmann glia cells. A time and dose-dependent increase in the activity, plasma membrane localization and protein levels of glucose transporters was detected upon d-aspartate exposure. Interestingly, this increase is the result of a protein kinase C-dependent signaling cascade. Furthermore, a glutamate-dependent glucose and glutamate transporters co-immunoprecipitation was detected. These results favour the notion that glial cells are involved in glutamatergic neuronal physiology.
Subject(s)
Glucose/metabolism , Glutamic Acid/metabolism , Neuroglia/metabolism , Amino Acid Transport System X-AG , Animals , Aspartic Acid/pharmacology , Carrier Proteins/metabolism , Cells, Cultured , Chick Embryo , Energy Metabolism/physiology , Excitatory Amino Acids/metabolism , Neuroglia/drug effects , Neurotransmitter Agents/metabolism , Protein Kinase C/metabolism , Signal Transduction/physiology , Sodium-Potassium-Exchanging ATPase/metabolismABSTRACT
Glutamate, the main excitatory transmitter in the vertebrate brain, exerts its actions through the activation of specific membrane receptors present in neurons and glial cells. Over-stimulation of glutamate receptors results in neuronal death, phenomena known as excitotoxicity. A family of glutamate uptake systems, mainly expressed in glial cells, removes the amino acid from the synaptic cleft preventing an excessive glutamatergic stimulation and thus neuronal damage. Autism spectrum disorders comprise a group of syndromes characterized by impaired social interactions and anxiety. One or the most common drugs prescribed to treat these disorders is Methylphenidate, known to increase dopamine extracellular levels, although it is not clear if its sedative effects are related to a plausible regulation of the glutamatergic tone via the regulation of the glial glutamate uptake systems. To gain insight into this possibility, we used the well-established model system of cultured chick cerebellum Bergmann glia cells. A time and dose-dependent increase in the activity and protein levels of glutamate transporters was detected upon Methylphenidate exposure. Interestingly, this increase is the result of an augmentation of both the synthesis as well as the insertion of these protein complexes in the plasma membrane. These results favour the notion that glial cells are Methylphenidate targets, and that by these means could regulate dopamine turnover.
Subject(s)
Dopamine Uptake Inhibitors/pharmacology , Glutamic Acid/metabolism , Methylphenidate/pharmacology , Neuroglia/metabolism , Animals , Aspartic Acid/metabolism , Cell Line , Cell Membrane/drug effects , Cell Membrane/metabolism , Chick Embryo , Dopamine/metabolism , Excitatory Amino Acid Transporter 1/metabolism , Neuroglia/drug effects , RNA/biosynthesis , RNA/isolation & purification , Up-Regulation/drug effectsABSTRACT
Adolescentes humanos frequentemente associam o fumo do tabaco ao consumo de bebidas alcoólicas. A despeito desta associação, pouco se sabe sobre a neurobiologia básica da coexposição no cérebro adolescente. No presente estudo, avaliamos os efeitos da exposição, que ocorreu do 30º ao 45º dia de vida pós natal (PN30 a PN45), à nicotina e/ou ao etanol durante a adolescência (PN38-45) e da retirada (PN50-57) na memória visuoespacial através do Labirinto Aquático de Morris (LAM: 6 sessões + 1 prova, 3 tentativas/sessão, latência = 2 min), em 4 grupos de camundongos Suíços machos e fêmeas: (1) exposição concomitante à NIC [solução de nicotina free base (50 μg/ml) em sacarina a 2% para beber] e ETOH [solução de etanol (25%, 2 g/kg) injetada i.p. em dias alternados]; (2) exposição à NIC; (3) exposição ao ETOH; (4) veículo (VEH). Uma vez que os resultados comportamentais podem sofrer a interferência de alterações motoras, avaliamos (a) a atividade locomotora no Teste de Campo Aberto (sessão única, 5 min) e (b) a coordenação e o equilíbrio no Teste de Locomoção Forçada sobre Cilindro Giratório (5 tentativas, latência = 2 min). Para os efeitos da exposição à NIC e/ou ao ETOH na eficiência do transporte de aminoácidos excitatórios, avaliamos a captação de [3H] D-aspartato no hipocampo. A expressão do transportador glial GLAST/EAAT1 foi avaliada por Western-blot. Durante a exposição, animais ETOH e NIC+ETOH apresentaram déficits de memória nas sessões de teste e de prova no LAM enquanto, na retirada, os grupos NIC e NIC+ETOH apresentaram prejuízos na retenção. Não houve diferenças significativas entre os grupos de tratamento em nenhum dos parâmetros testados em ambos os testes motores, tanto na exposição quanto na abstinência. Os grupos NIC, ETOH e NIC+ETOH tiveram uma diminuição significativa na captação de [3H] D-aspartato ao final do período de exposição, com uma normalização da atividade dos EAATs na retirada das drogas...
Human adolescents frequently associate tobacco smoke and alcoholic drinks. Despite this association, little is known about the basic neurobiology of co-exposure in the adolescent brain. In the present study, we assessed the effects of nicotine and/or ethanol exposure (postnatal days 30 to 45: PN30-45) during adolescence (PN38-45) and withdrawal (PN50-57) on visuospacial memory through the Morris Water Maze (MWM: 6 sessions + 1 probe, 3 trials/session, latency = 2 min), in four groups of male and female Swiss mice: (1) Concomitant NIC [nicotine free base solution (50µg/ml) in 2% saccharin to drink] and ETOH [ethanol solution (25%, 2g/kg) i.p. injected every other day] exposure; (2) NIC exposure; (3) ETOH exposure; (4) Vehicle (VEH). Once behavioral results can be affected by motor disorders, we assessed (a) locomotor activity through the Open field Test (one session, 5 min) and (b) coordination and balance through the ROTAROD Test (5 trials, latency = 2 min). To investigate the effects of NIC and/or ETOH exposure on the efficiency on excitatory amino acid transport, we assessed the [3H] D-aspartate uptake in mice hippocampus. The GLAST/EAAT1, a glial transporter, was assessed by Western-blot technique. During exposure, ETOH and NIC+ETOH animals showed deficits on memory through the session and probe trial in WMW while, during withdrawal, NIC and NIC+ETOH groups showed impairments on retention. There were no significant differences between the experimental groups in any parameters assessed in both motor tests, either during exposure and withdrawal. There was a significant decrease in the [3H] D-aspartate for NIC, ETOH and NIC+ETOH groups in the end of exposure, turning to the normal levels of EAATs activity during withdrawal...
Subject(s)
Animals , Adolescent , Rats , Glutamic Acid/analysis , Ethanol/adverse effects , Memory , Nicotine/adverse effects , Alcohol Drinking , Alcohol-Related Disorders , Adolescent Behavior , Ethanol/pharmacology , Ethanol/toxicity , Memory/physiology , Nicotine/pharmacology , Nicotine/toxicity , Tobacco Use DisorderABSTRACT
The effect of dietary protein on growth, carcass traits and some specific intestinal intestinal peptide and amino acid transporters in broiler chickens was studied. Birds received a common pre-test diet, and were subsequently fed either a standard positive control diet (PC) or a reduced CP diet (RCP) from 21 to 42 d of age. Growth was negatively impacted with feeding of RCP as manifested by an increase in feed consumption and feed conversion ratio. Carcass traits also showed evidence of negative effects of feeding the RCP diet, leading to a reduction in carcass and breast meat yield and an increase in abdominal fat percentage. Blood plasma total protein was reduced when the broilers were fed the RCP diet. Expression of mRNA for one peptide (PepT1) and four AA intestinal transporters (bo,+AT; CAT2; y+LAT2; EAAT3) was measured from the jejunum. Quantified mRNA for the AA transporters y+LAT2 and EAAT3 showed that they were up-regulated in chickens fed the RCP-diet. The transport systems PepT1, bo,+AT, and CAT2, were not affected by the dietary treatment imposed. The live and processing data validated the in vivo portion of the study and elucidated the negative impact of feeding the RCP diet, while the responses observed with the expression of the various transporters may help provide some insight on the physiological consequences and adaptations that birds endure when provided diets too low in CP for abnormally extended periods of time.
Subject(s)
Animals , Meat/analysis , Diet , Chickens/classification , Amino Acids , ProteinsABSTRACT
The effect of dietary protein on growth, carcass traits and some specific intestinal intestinal peptide and amino acid transporters in broiler chickens was studied. Birds received a common pre-test diet, and were subsequently fed either a standard positive control diet (PC) or a reduced CP diet (RCP) from 21 to 42 d of age. Growth was negatively impacted with feeding of RCP as manifested by an increase in feed consumption and feed conversion ratio. Carcass traits also showed evidence of negative effects of feeding the RCP diet, leading to a reduction in carcass and breast meat yield and an increase in abdominal fat percentage. Blood plasma total protein was reduced when the broilers were fed the RCP diet. Expression of mRNA for one peptide (PepT1) and four AA intestinal transporters (bo,+AT; CAT2; y+LAT2; EAAT3) was measured from the jejunum. Quantified mRNA for the AA transporters y+LAT2 and EAAT3 showed that they were up-regulated in chickens fed the RCP-diet. The transport systems PepT1, bo,+AT, and CAT2, were not affected by the dietary treatment imposed. The live and processing data validated the in vivo portion of the study and elucidated the negative impact of feeding the RCP diet, while the responses observed with the expression of the various transporters may help provide some insight on the physiological consequences and adaptations that birds endure when provided diets too low in CP for abnormally extended periods of time.(AU)