Kinetic study of the tubular dopamine outward transporter in the rat and dog kidney

Chronic alcohol consumption leads to neurochemical changes in the nucleus accumbens that are not fully reversed by withdrawal

Neuropeptide Y (NPY)- and acetylcholine-containing interneurons of the nucleus accumbens (NAc) seem to play a major role in the rewarding effects of alcohol. This study investigated the relationship between chronic alcohol consumption and subsequent withdrawal and the expression of NPY and acetylcholine in the NAc, and the possible involvement of nerve growth factor (NGF) in mediating the effects of ethanol. Rats ingesting an aqueous ethanol solution over 6months and rats subsequently deprived from ethanol during 2months were used to estimate the total number and the somatic volume of NPY and cholinergic interneurons, and the numerical density of cholinergic varicosities in the NAc. The tissue content of choline acetyltransferase (ChAT) and catecholamines were also determined. The number of NPY interneurons increased during alcohol ingestion and returned to control values after withdrawal. Conversely, the number and the size of cholinergic interneurons, and the amount of ChAT were unchanged in ethanol-treated and withdrawn rats, but the density of cholinergic varicosities was reduced by 50% during alcohol consumption and by 64% after withdrawal. The concentrations of dopamine and norepinephrine were unchanged both during alcohol consumption and after withdrawal. The administration of NGF to withdrawn rats significantly increased the number of NPY-immunoreactive neurons, the size of cholinergic neurons and the density of cholinergic varicosities. Present data show that chronic alcohol consumption leads to long-lasting neuroadaptive changes of the cholinergic innervation of the NAc and suggest that the cholinergic system is a potential target for the development of therapeutic strategies in alcoholism and abstinence.

The role of neuronal and extraneuronal plasma membrane transporters in the inactivation of peripheral catecholamines

Catecholamines are translocated across plasma membranes by transporters that belong to two large families with mainly neuronal or extraneuronal locations. In mammals, neuronal uptake of catecholamines involves the dopamine transporter (DAT) at dopaminergic neurons and the norepinephrine transporter (NET) at noradrenergic neurons. Extraneuronal uptake of catecholamines is mediated by organic cation transporters (OCTs), including the classic corticosterone-sensitive extraneuronal monoamine transporter. Catecholamine transporters function as part of uptake and metabolizing systems primarily responsible for inactivation of transmitter released by neurons. Additionally, the neuronal catecholamine transporters, recycle catecholamines for rerelease, thereby reducing requirements for transmitter synthesis. In a broader sense, catecholamine transporters function as part of integrated systems where catecholamine synthesis, release, uptake, and metabolism are regulated in a coordinated fashion in response to the demands placed on the system. Location is also important to function. Neuronal transporters are essential for rapid termination of the signal in neuronal-effector organ transmission, whereas non-neuronal transporters are more important for limiting the spread of the signal and for clearance of catecholamines from the bloodstream. Besides their presynaptic locations, NET and DAT are also present at several extraneuronal locations, including syncytiotrophoblasts of the placenta and endothelial cells of the lung (NET), stomach and pancreas (DAT). The extraneuronal monoamine transporter shows a broad tissue distribution, whereas the other two non-neuronal catecholamine transporters (OCT1 and OCT2) are mainly localized to the liver, kidney, and intestine. Altered function of peripheral catecholamine transporters may be involved in disturbances of the autonomic nervous system, such as occurs in congestive heart failure and hypernoradrenergic hypertension. Peripheral catecholamine transporters provide important targets for clinical imaging of sympathetic nerves and diagnostic localization and treatment of neuroendocrine tumors, such as neuroblastomas and pheochromocytomas.

Concerted action of dopamine on renal and intestinal Na(+)-K(+)-ATPase in the rat remnant kidney

The present study evaluated renal and intestinal adaptations in sodium handling in uninephrectomized (Unx) rats and the role of dopamine. Two weeks after uninephrectomy, the remnant kidney in Unx rats weighed 33 +/- 2% more than the corresponding kidney in sham-operated (Sham) animals. This was accompanied by increases in urinary levels of dopamine and major metabolites [3, 4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid] and increases in maximal velocity values (169 vs. 115 nmol. mg protein(-1). 15 min(-1)) for renal aromatic L-amino acid decarboxylase, the enzyme responsible for the synthesis of renal dopamine. High salt (HS) intake increased (P < 0.05) the urinary excretion of dopamine and DOPAC in Unx and Sham rats. However, the urinary levels of L-3,4-dihydroxyphenylalanine, dopamine, and DOPAC in Sham rats during HS intake were lower than in Unx rats. Blockade of dopamine D(1) receptors (Sch-23390, 2 x 30 microg/kg) reduced the urinary excretion of sodium in Unx (31% decrease) more pronouncedly than in Sham (19% decrease) rats. However, inhibition of renal Na(+)-K(+)-ATPase activity by dopamine was of similar magnitude in Unx and Sham rats. In parallel, it was observed that uninephrectomy resulted in a significant reduction in jejunal sodium absorption and Na(+)-K(+)-ATPase activity in jejunal epithelial cells. In jejunal epithelial cells from Sham rats, dopamine (1 microM) failed to inhibit Na(+)-K(+)-ATPase activity, whereas in Unx rats it produced a significant reduction. It is concluded that uninephrectomy results in increased renal dopaminergic activity and dopamine-sensitive enhanced natriuresis. Furthermore, it is suggested that decreased jejunal absorption of sodium may take place in response to partial renal ablation, as an example of renal-intestinal cross talk.

Cellular and molecular aspects of drug transport in the kidney

The kidney plays an important role in the elimination of numerous hydrophilic xenobiotics, including drugs, toxins, and endogenous compounds. It has developed high-capacity transport systems to prevent urinary loss of filtered nutrients, as well as electrolytes, and simultaneously to facilitate tubular secretion of a wide range of organic ions. Transport systems for organic anions and cations are primarily involved in the secretion of drugs in renal tubules. The identification and characterization of organic anion and cation transporters have been progressing at the molecular level. To date, many members of the organic anion transporter (OAT), organic cation transporter (OCT), and organic anion-transporting polypeptide (oatp) gene families have been found to mediate the transport of diverse organic anions and cations. It has also been suggested that ATP-dependent primary active transporters such as MDR1/P-glycoprotein and the multidrug resistance-associated protein (MRP) gene family function as efflux pumps of renal tubular cells for more hydrophobic molecules and anionic conjugates. Tubular reabsorption of peptide-like drugs such as beta-lactam antibiotics across the brush-border membranes appears to be mediated by two distinct H+/peptide cotransporters: PEPT1 and PEPT2. Renal disposition of drugs is the consequence of interaction and/or transport via these diverse secretory and absorptive transporters in renal tubules. Studies of the functional characteristics, such as substrate specificity and transport mechanisms, and of the localization of cloned drug transporters could provide information regarding the cellular network involved in renal handling of drugs. Detailed information concerning molecular and cellular aspects of drug transporters expressed in the kidney has facilitated studies of the mechanisms underlying renal disposition as well as transporter-mediated drug interactions.

Organic cation transporters in intestine, kidney, liver, and brain

This review focuses on sodium-independent transport systems for organic cations in small intestine, liver, kidney, and brain. The roles of P-glycoproteins (MDR) and anion transporters (OATP) in organic cation transport are reported, and two members of the new transporter family OCT are described. The OCT transporters belong to a superfamily that includes multidrug-resistance proteins, facilitative diffusion systems, and proton antiporters. They mediate electrogenic transport of small organic cations with different molecular structures, independently of sodium and proton gradients. The current knowledge of the distribution and functional properties of cloned cation transport systems and of cation transport measured in intact plasma membranes is used to postulate identical or homologous transporters in intestine, liver, kidney, and brain.

Evidence for the involvement of P-glycoprotein on the extrusion of taken up L-DOPA in cyclosporine A treated LLC-PK1 cells

1. The present work has examined the effects of short- (30 min) and long-term (14 h) exposure to cyclosporine A (CsA) on the uptake of L-DOPA, its decarboxylation to dopamine and the cellular extrusion of taken up L-DOPA and of newly-formed amine in monolayers of LLC-PK1 cells. 2. In the presence of benserazide (50 microM), L-DOPA was rapidly accumulated in LLC-PK1 cells (cultured in collagen-treated plastic) attaining equilibrium at 30 min of incubation. Non-linear analysis of the saturation curves revealed a Km of 113+/-16 microM and a Vmax of 5581+/-297 pmol mg(-1) protein 6 min(-1). 3. In the absence of benserazide, LLC-PK1 cells incubated with increasing concentrations of L-DOPA (10 to 500 microM) for 6 min accumulate newly-formed dopamine by a saturable process with apparent Km and Vmax values of 31+/-6 microM and 1793+/-91 pmol mg(-1) protein 6 min(-1), respectively. The fractional outflow of newly-formed dopamine was found to be 20%. Up to 200 microM of intracellular newly-formed dopamine, the outward transfer of the amine was found to be a non-saturable process. 4. Short-term exposure to CsA (0.3, 1.0 and 3.0 microg ml(-1)) was found not to change the intracellular concentrations of newly-formed dopamine, but increased the levels of dopamine in the incubation medium (143% to 224% increase) and the total amount of dopamine formed (31% to 59% increase). Long-term exposure to CsA (0.03 to 3.0 microg ml(-1)) reduced the total amount of dopamine (15% to 39% reduction) and the intracellular levels of the amine (11% to 56% reduction), without changing dopamine levels in the incubation medium. Both short- and long-term exposure to CsA resulted in a concentration-dependent increase in the fractional outflow of newly-formed dopamine. 5. Short-term exposure to CsA (3.0 microg ml(-1)) reduced the apical extrusion of intracellular L-DOPA by 15% (P<0.05), whereas long-term exposure to CsA reverted this effect and decreased its intracellular availability (15% reduction; P<0.05). 6. Detection of P-glycoprotein activity was carried out by measuring verapamil- or UIC2-sensitive rhodamine 123 accumulation. Both UIC2 (3 microg ml(-1)) and verapamil (25 microM) significantly increased the accumulation of rhodamine 123 in LLC-PK1 cells. A 30 min exposure to CsA was found not to affect the accumulation of rhodamine 123 in the presence of verapamil (25 microM), whereas a 14 h exposure to CsA was found to reduce the accumulation of rhodamine 123. 7. In conclusion, the increase and the reduction in the formation of dopamine after short- and long-term exposure to CsA, respectively, correlate with the effects of the immunosuppressant on the apical cell extrusion of taken up L-DOPA, suggesting the involvement of P-glycoprotein. The effects of CsA on the fractional outflow of newly-formed dopamine appear to be mediated by a different mechanism.

Ontogeny of the cell outward dopamine transporter in canine renal tissues

The present work has determined the activities of aromatic L-amino acid decarboxylase (AAAD) and evaluated the presence of an active transport system for dopamine in renal tissues of developing dogs (newborn puppies less than 24 hours after birth, animals at the age of 10 days and 2 months) and adult animals. AAAD activity (Vmax, in pmol/mg protein/h) as determined in kidney homogenates was found to be in the adult dog kidney (Vmax = 3216 +/- 268) higher (p < 0.05) than that occurring in the three other groups of animals; no significant difference on AAAD activity was observed between the 10 day-old (Vmax = 1139 +/- 185) and the 2 month-old dogs (Vmax = 783 +/- 23). AAAD activity in newborn puppies (Vmax = 259 +/- 40) was markedly lower than in the three other groups. A considerable amount of the total dopamine formed from added L-DOPA in kidney slices, depending on the age, was found to escape into the incubation medium. The application of the Michaelis-Menten equation to the net transport of newly-formed dopamine has allowed the identification of a saturable (carrier-mediated transfer) and a non-saturable component (diffusion). The Vmax (nmol/g/15 min), Km (microM) values for the saturable component and diffusion constant (mumol-1) were as follows: adult (Vmax = 112 +/- 16; Km = 319 +/- 35; diffusion constant = 0.0009 +/- 0.0001), 2 month-old (Vmax = 19 +/- 5; Km = 48 +/- 14; diffusion constant = 0.0007 +/- 0.0002), 10 day-old (Vmax = 25 +/- 3; Km = 69 +/- 20; diffusion constant = 0.0033 +/- 0.0007) and newborn (Vmax = 6 +/- 1; Km = 16 +/- 6; diffusion constant = 0.0095 +/- 0.0010). In conclusion, renal AAAD develops with age, though some AAAD activity can already be detected at birth.(ABSTRACT TRUNCATED AT 250 WORDS)

Assessment of renal dopaminergic system activity in the nitric oxide-deprived hypertensive rat model

1. The present paper reports changes in the urinary excretion of dopamine, 5-hydroxytryptamine and amine metabolites in nitric oxide deprived hypertensive rats during long-term administration of NG-nitro-L-arginine methyl ester (L-NAME). Aromatic L-amino acid decarboxylase (AAAD) activity in renal tissues and the ability of newly-formed dopamine to leave the cellular compartment where the synthesis of the amine has occurred were also determined. 2. Twenty four hours after exposure to L-NAME, both systolic (SBP) and diastolic (DBP) blood pressure were increased by 20 mmHg; heart rate was slightly decreased. During the next 13 days both SBP and DBP increased progressively reaching 170 +/- 3 and 116 +/- 3 mmHg, respectively. 3. Baseline urinary excretion of L-DOPA, dopamine, 3,4-dihydroxyphenylacetic acid (DOPAC), 3-methoxytyramine (3-MT) and homovanillic acid (HVA) during the 4 day period of stabilization averaged 4.4 +/- 0.5, 13.8 +/- 0.3, 37.4 +/- 0.8, 180.0 +/- 2.7 and 206.1 +/- 6.7 nmol day-1, respectively. The urinary excretion of L-DOPA, dopamine and DOPAC, but not that of 3-MT and HVA, were increased from day 6-8 of L-NAME administration onwards (L-DOPA, up to 13.4 +/- 2.1; dopamine, up to 23.0 +/- 1.6; DOPAC, up to 62.8 +/- 3.7 nmol day-1). Baseline daily urinary excretion of 5-hydroxytryptamine and 5-hydroxyindolacetic acid (5-HIAA) averaged 73.5 +/- 1.1 and 241.7 +/- 5.4 nmol day-1, respectively. During the first week of L-NAME administration, the urinary excretion of both 5-hydroxytryptamine and 5-HIAA did not change significantly; however, as was found with dopamine and DOPAC, changes in the urinary excretion of 5-hydroxytryptamine were evident during the second week of L-NAME administration. 4. In experiments performed on homogenates of isolated renal tubules, the decarboxylation of L-DOPA to dopamine was dependent on the concentration of L-DOPA used (10 to 5000 microM) and saturable at 1000 microM. AAAD activity as determined in homogenates (Vmax, in nmol mg-1 protein h-1; Km in microM) was significantly (P < 0.01) higher in rats given L-NAME for 14 days (Vmax = 25 +/- 2; Km = 72 +/- 10) than in control rats (Vmax = 14 +/- 1; Km = 63 +/- 7), rats given L-NAME for 7 days (Vmax = 15 +/- 1; Km = 69 +/- 5) and rats given L-NAME plus L-arginine (Vmax = 13 +/- 1; Km = 60 +/- 3) for 14 days. 5. A considerable amount of the total dopamine formed from added L-DOPA in kidney slices escaped into the incubation medium. The application of the Michaelis-Menten equation to the net transport of newly-formed dopamine allowed the identification of a saturable (carrier-mediated transfer) and a non-saturable component (diffusion). No significant differences in the diffusional rate of transfer(0.14 +/- 0.02 micro mol-1) were observed between the four experimental groups. However, the saturable outward transfer of dopamine (Vmax, in micromol mg-1 protein h-1; Km in microM) was higher in control animals(Vmax= 2.3 +/- 0.2; Km = 568 +/- 67) than that in rats treated with L-NAME for 14 days (Vmax = 0.8 +/- 0.02;Km = 241 +/- 21), but similar to that observed in rats receiving L-NAME plus L-arginine (Vmax= 2.4+/- 0.2; Km= 618 +/- 61); the saturable dopamine outward rate of transfer in rats given L-NAME for 7days (Vmax = 3.9 +/- 0.2; Km = 1006 +/- 32) was higher than in controls.6. In conclusion, the present studies show that the hypertensive response resulting from the long-term administration of L-NAME is accompanied by an increased urinary excretion of dopamine and 5-hydroxytryptamine, which appears to follow an enhanced activity of renal AAAD. The observation that the increased AAAD activity can be reversed by the administration of L-arginine to L-NAME treated rats favours the view that the adaptational response which results in an enhanced AAAD activity probably involves a decrease in the generation of nitric oxide.

The renal handling of dopamine originating from L-dopa and gamma-glutamyl-L-dopa

1. The formation and outflow of dopamine and its deaminated metabolite 3,4-dihydroxyphenylacetic acid (DOPAC) was studied in cortical fragments of the rat kidney loaded with L-beta-3,4-dihydroxyphenylalanine (L-dopa) or gamma-glutamyl-L-dopa (GluDOPA). Dopamine and DOPAC in the tissues and in the effluent were assayed by means of h.p.l.c. with electrochemical detection. 2. In rats given 30 mg kg-1 L-dopa, tissue and outflow levels of both dopamine and DOPAC were 3 fold those observed with a lower dose of L-dopa (10 mg kg-1). In rats given GluDOPA (16.7 mg kg-1) levels of dopamine in renal tissues and in perifusate samples were found to be higher than those obtained with an equimolar dose of L-dopa (10 mg kg-1); however, no significant difference was observed for DOPAC. The outflow of both dopamine and DOPAC in kidney slices of rats injected with L-dopa (10 and 30 mg kg-1) or GluDOPA (16.7 mg kg-1) was found to decline monophasically with similar slopes of decline. The rate constants of loss (k, min-1) of DOPAC (10 mg kg-1 L-DOPA, k = 0.0070; 30 mg kg-1 L-DOPA, k = 0.0087; 16.7 mg kg-1 GluDOPA, k = 0.0080) were 2 to 3 fold those of dopamine (10 mg kg-1 L-dopa, k = 0.0027; 30 mg kg-1 L-DOPA, k = 0.0034; 16.7 mg kg-1 GluDOPA, k = 0.0030). With both precursors the DOPAC/dopamine ratio in perifusate samples were 2.0 fold those in the tissues. 3. Tissue and outflow levels of dopamine after incubation of renal tissues with L-DOPA, 50 and 100 MicroM were found to be lower than those observed with GluDOPA (50 and 100 MicroM). DOPAC/dopamine ratios in tissues and perifusate samples of experiments performed with L-DOPA were significantly higher(P<0.01) than those observed with GluDOPA. The outflow of both dopamine and DOPAC in renal slices incubated with L-DOPA (50 and 100 MicroM) were found to decline with time, but presented a biphasic shape. DOPAC/dopamine ratios in perifusate samples were 3 fold that in the tissues with both precursors.4. In conclusion, the present results show that both L-DOPA and GluDOPA give origin to substantial amounts of dopamine and the newly-formed amine undergoes considerable deamination to DOPAC.However, dopamine originating from GluDOPA was less deaminated than that resulting from L-DOPA;it appears that this different behaviour may concern aspects related to the formation of the amine and also those related to its deamination and disposition, namely the processes involved in the access of newly-formed dopamine to MAO.

Renal tubular dopamine outward transfer during Na(+)-H+ exchange activation by alpha 1- and alpha 2-adrenoceptor agonists

1. The present work describes the effects of inhibitors (amiloride and ethylisopropylamiloride) and activators (quinoxaline and phenylephrine) of the Na(+)-H+ exchanger on the outflow of dopamine in rat kidney slices loaded with L-dihydroxyphenylalanine (L-DOPA). 2. Incubation of kidney slices loaded with 50 microM L-DOPA in the presence of increasing concentrations of amiloride or ethylisopropylamiloride (EIPA) resulted in a concentration-dependent decrease in the outflow of newly-formed dopamine; the IC50 value for EIPA was 5.6 +/- 0.3 microM. Phenylephrine and quinoxaline were found to produce a concentration-dependent increase in the outflow of newly-formed dopamine; the EC50 values for the phenylephrine and quinoxaline were, respectively, 0.9 +/- 0.1 and 0.08 +/- 0.01 microM. 3. The facilitatory effect of phenylephrine on the outflow of dopamine was found not to be affected by yohimbine (100 nM), but was abolished by prazosin (1 microM), whereas that of quinoxaline was found to be selectively antagonized by yohimbine (100 nM), but not by prazosin (1 microM); EIPA (10 microM) was also found to abolish the effect of both phenylephrine and quinoxaline. The facilitatory effect of quinoxaline was also found to be reduced by 42-48% and 56-78% by, dibutyryl adenosine cyclic 3',5'-monophosphate (dibutyryl cyclic AMP; 250 microM) and forskolin (10 microM), respectively, but not by the protein kinase C (PKC) inhibitor, (+)-sphingosine (10 microM). In contrast, (+)-sphingosine (10 microM) was found to antagonize markedly (43- 69% reduction) the facilitatory effect of phenylephrine; dibutyrylcyclic AMP (250 microM) and forskolin (10 microM) were also found to reduce significantly the facilitatory effect of phenylephrine, by 42-53% and 44-59% respectively.4. A synergistic effect between alphal- and alpha2-adrenoceptors was observed for submaximal concentrations of quinoxaline (50 nM) and phenylephrine or submaximal concentrations of phenylephrine (0.5 microM) and quinoxaline, but not for maximal effective concentrations of either agonist. Dibutyryl cyclic AMP(250 microM) or forskolin (10 microM) produced a marked decrease (35-85% reduction) of the synergistic effect between phenylephrine and quinoxaline. The addition of phorbol 12,13-dibutyrate (PDBu; 500 nM) was found not to alter the outflow of newly-formed dopamine, but did potentiate (18-42% increase) the facilitatory effect of quinoxaline on the amine outflow. This effect was found to occur for submaximal concentrations of quinoxaline (10, 50 and 100 nM) and found to be antagonized by (+)-sphingosine(10 microM). In contrast, PDBu (500 nM) was found not to potentiate the facilitatory effect of phenylephrine on dopamine outflow.5. In conclusion, inhibition of the Na+-H+ antiport by amiloride and EIPA results in considerable reduction in the outflow of newly-formed dopamine, whereas the activation of this mechanism by both phenylephrine and quinoxaline results in facilitation of the outflow of dopamine; this effect is selectively reversed by alphal- and alpha2-adrenoceptor antagonists and EIPA. The synergistic effect between quinoxaline and phenylephrine may be related to an amplification of a reaction at a given point in the post-receptor transducing pathway.