Characterization of transepithelial transport of salicylate by the Malpighian tubules of Drosophila melanogaster and the effects of changes in fluid secretion rate

Abstract.  A radioisotope tracer technique is used to study mechanisms and regulation of transepithelial transport of the plant allelochemical salicylate by the Malpighian tubules of Drosophila melanogaster . Transepithelial transport of salicylate is nearly abolished in Na⁺-free saline, and inhibited by ouabain, low K⁺ or K⁺-free bathing saline. In addition, the carboxylates probenecid, unlabelled salicylate, fluorescein, and p -aminohippuric acid (PAH) significantly inhibit transepithelial transport of salicylate. The sulphonates taurocholate and phenol red also inhibit transepithelial transport of salicylate, whereas amaranth has no effect. Stimulation of fluid secretion by cAMP, cGMP or leucokinin I increases transepithelial transport of salicylate, particularly when the concentration of salicylate in the bathing saline is high. The correlation between the fluid secretion rate and transepithelial transport of salicylate shows that 64% of the changes in salicylate transport can be explained on the basis of changes in fluid secretion rate. The results show that naturally-occurring plant secondary metabolite salicylate is transported into the lumen of the Mapighian tubules of D. melanogaster by a mechanism similar to that previously described for the prototypical organic anions PAH and fluorescein. In addition, the transepithelial transport of salicylate increases in response to increases in fluid secretion rate.     

Inorganic and organic anion transport by insect renal epithelia

Insect renal organs typically exhibit high rates of transport of inorganic and organic anions, and therefore provide useful models for the study of epithelial anion transport and its control. Isolated Malpighian tubules of some species secrete a volume of iso-osmotic fluid equal to their own volume in 10-15 s, which means that cellular Cl(-) content is exchanged every 3-5 s. Anion transport can also be achieved against extreme thermodynamic gradients. The concentration of K(+) and Cl(-) in the lumen of the Malpighian tubules of some desert beetles approaches or exceeds saturation. A basolateral Na(+):K(+):2Cl(-) cotransporter plays an important role in vectorial ion transport in Malpighian tubules of many species, but there is also evidence for coupling of Cl(-) transport to the movement of a single cationic species (Na(+) or K(+)). Although an apical vacuolar H(+)-ATPase plays a primary role in energizing transepithelial secretion of chloride via channels or cotransporters in the secretory segment of the Malpighian tubule, several different ATPases have been implicated in reabsorption of Cl(-) by the lower Malpighian tubule or hindgut. Chloride transport is known to be controlled by several neuropeptides, amines and intracellular second messengers. Insect renal epithelia are also important in excretion of potentially toxic organic anions, and the transporters involved may play a role in resistance to insecticides of natural or anthropogenic origin.     

Organic cation uptake by a cultured renal epithelium

Several organic cations are actively transported by proximal renal tubules by mediated processes across both the apical and basolateral cell membranes. In order to evaluate this transport system in a cultured renal epithelium, uptake of 3H-tetraethylammonium (TEA) across the apical membrane was measured in LLCPK1 cells, a cell line with several characteristics of proximal tubules. 3H-TEA progressively entered these cells and reached a near-steady state by 30 min. Three-minute uptake was saturable with an apparent Vmax of 1,669 +/- 129 fmoles/micrograms DNA and apparent Km of 34.0 +/- 3.4 microM. 3H-TEA uptake was inhibited by an excess of nonradioactive TEA, other organic cations, sodium azide, and hypothermia. An alkaline external pH was associated with greater 3H-TEA uptake than an acid pH. However, efflux of 3H-TEA from cells was not appreciably affected by changes in external pH. Preincubation of cells in acid or alkaline media did not affect uptake. Alteration of cell pH by ammonium chloride addition or removal had little effect on 3H-TEA uptake. Finally, uptake of 3H-TEA was not accelerated by preloading cells with an excess of nonradioactive TEA. These results indicate that intact LLCPK1 cells possess a mechanism(s) in their apical membranes for the mediated transport of a prototypic organic cation. The mechanism(s) involved in this transport is uncertain. However, neither organic cation/proton nor organic cation/organic cation exchange appears to be the predominant process.     

Cation and anion balance in the xylem exudate of tobacco roots

Summary The sum of Na, K, Ca, Mg in the exudate of tobacco generally exceeded the sum of mineral anions. Insufficient organic acids were present to account for the differences and bicarbonate appeared to be the other anion involved. Amino acids were present in very low concentrations relative to mineral cations. When nitrate salts only were in the external solutions, the anions were mostly, but not entirely, nitrate. When chloride salts only were in the external solutions, the cations far exceeded the level of mineral anions in the exudate. It is postulated that nitrate is actively transported when nitrate salts are in the external solution regardless of the cation, but when anions other than nitrate are in the external solution, the cations are actively transported with the anions passively following. Nitrate transport was via a symplasm, but that of the other anions seemed to be different. When bicarbonate is the only anion in the external solution and when present at relatively high concentrations (5 × 10⁻³ M or higher), the volume of exudate is decreased. It appears that the organic acids which were synthesized as a result of the bicarbonate absorption were not transferred to the xylem vessels.     

Regulation of renal proximal and distal tubule transport: sodium, chloride and organic anions

Renal tubular transport and its regulation are reviewed for Na(+) (and Cl(-)), and for fluid and organic anions (including urate). Filtered Na(+) (and Cl(-)) is reabsorbed along the tubules but only in mammals and birds does most reabsorption occur in the proximal tubules. Reabsorption involves active transport of Na(+) and passive reabsorption of Cl(-). The active Na(+) step always involves Na-K-ATPase at the basolateral membrane, but the entry step at luminal membrane varies among tubule segments and among vertebrate classes (except for Na(+)-2Cl(-)-K(+) cotransporter in diluting segment). Regulation can involve intrinsic, neural and endocrine factors. Proximal tubule fluid reabsorption is dependent on Na(+) reabsorption in all vertebrates studied, except ophidian reptiles. Fluid secretion occurs in glomerular and aglomerular fishes, reptiles and even mammals, but its significance is not always clear. A non-specific transport system for net secretion of organic anions (OAs) exists in the proximal renal tubules of almost all vertebrates. Net transepithelial secretion involves: (1) transport into the cells at the basolateral side against an electrochemical gradient by a tertiary active transport process, in which the final step involves OA/alpha-ketoglutarate exchange and (2) movement out of the cells across the luminal membrane down an electrochemical gradient by unknown carrier-mediated process(es). Regulation may involve protein kinase C and mitogen-activated protein kinase. Urate is net secreted in the proximal tubules of birds and reptiles. This process is urate-specific in reptiles but in birds, it may involve both a urate-specific system and the general OA system.     

Characterization of tetraethylammonium uptake across the basolateral membrane of the Drosophila Malpighian (renal) tubule

Basolateral transport of the prototypical type I organic cation tetraethylammonium (TEA) by the Malpighian tubules of Drosophila melanogaster was studied using measurements of basolateral membrane potential (V(bl)) and uptake of [(14)C]-labeled TEA. TEA uptake was metabolically dependent and saturable (maximal rate of mediated TEA uptake by all potential transport processes, reflecting the total transport capacity of the membrane, 0.87 pmol.tubule(-1).min(-1); concentration of TEA at 0.5 of the maximal rate of TEA uptake value, 24 muM). TEA uptake in Malpighian tubules was inhibited by a number of type I (e.g., cimetidine, quinine, and TEA) and type II (e.g., verapamil) organic cations and was dependent on V(bl). TEA uptake was reduced in response to conditions that depolarized V(bl) (high-K(+) saline, Na(+)-free saline, NaCN) and increased in conditions that hyperpolarized V(bl) (low-K(+) saline). Addition of TEA to the saline bathing Malpighian tubules rapidly depolarized the V(bl), indicating that TEA uptake was electrogenic. Blockade of K(+) channels with Ba(2+) did not block effects of TEA on V(bl) or TEA uptake indicating that TEA uptake does not occur through K(+) channels. This is the first study to provide physiological evidence for an electrogenic carrier-mediated basolateral organic cation transport mechanism in insect Malpighian tubules. Our results also suggest that the mechanism of basolateral TEA uptake by Malpighian tubules is distinct from that found in vertebrate renal tubules.     

Diuretic factors and second messengers stimulate secretion of the organic cation TEA by the Malpighian tubules of Drosophila melanogaster

This study showed that four factors which stimulate transepithelial fluid secretion and inorganic ion transport across the main segment of the Malpighian tubules of Drosophila melanogaster also stimulate transepithelial secretion of the prototypical organic cation tetraethylammonium (TEA). TEA fluxes across the Malpighian tubules and gut were measured using a TEA-selective self-referencing (TEA-SeR) microelectrode. TEA flux across isolated Malpighian tubules was also measured using a TEA-selective microelectrode positioned in droplets of fluid secreted by tubules set up in a modified Ramsay assay. TEA flux was stimulated by the intracellular second messengers cAMP and cGMP, which increase the lumen-positive transepithelial potential (TEP), and also by tyramine and leucokinin-I (LK-I), which decrease TEP. The largest increase was measured in response to 1 micromol l-1 LK-I which increased transepithelial TEA flux by 72%. TEA flux in the lower tubule was stimulated slightly (13%) by 1 micromol l-1 tyramine but not by any of the other factors. TEA flux across the midgut was unaffected by cAMP, cGMP or tyramine. This is the first study to demonstrate the effects of insect diuretic factors and second messengers on excretion of organic cations.     

Assessment of tissue-level kidney functions with primary cultures

Primary cultures of renal proximal tubule have become important tools for examination of the mechanisms and control of transepithelial transport processes. The utility of the culture preparations for study of integrated tissue functions depends upon their accurate expression of in vivo transport processes. Maintenance of differentiation in culture is enhanced by contractible collagen substratum. Epithelial monolayer primary cultures of flounder and chicken proximal tubule, prepared by enzymatic and mechanical maceration with differential centrifugation, exhibit functional properties at the tissue level that generally resemble known properties of the freshly isolated or in vivo proximal tubule. Transepithelial electrical resistances and potential differences are very similar or identical to those of intact tubules. Na+-dependent glucose transport, a hallmark of proximal tubule function, has the same properties in culture as the tissue in vivo. Similarly, where appropriate comparisons are possible, amino acid, uric acid, and organic anion and cation transepithelial transport processes are qualitatively very similar in culture and in vivo. These two non-mammalian primary proximal tubule culture systems adequately reflect in vivo function, and thus provide opportunities for experimental manipulation otherwise not available.     

Energized cation transport by complex III (ubiquinone-cytochrome C reductase)

Energized cyclical and net transport of cations and anions has been demonstrated in liposomes containing Complex III using a protamine-aggregation technique. Energization with reduced ubiquinone induces a rapid ion uptake followed by a more gradual efflux upon exhaustion of the available reductant. Both monovalent and divalent cations are transported, but at relatively high concentrations divalent cations are transported in preference to monovalent cations. Results are consistent with a cation:electron ratio of unity.     

The cations and anions of cyclobutanetetraone poly(phenylhydrazones)

Six cyclobutanetetraone poly(arylhydrazones) have been treated with acids and bases, and the structures of the resulting anions and cations studied by UV-Vis absorption and NMR spectroscopy. In acid media, all the hydrazones studied formed cations, which exhibited bathochromic shifts due to the extension of their resonance systems. However, in bases, only some (those which could enolize) formed anions that exhibited hypsochromic shifts; the others were unaltered.     

Characterization of mouse organic anion transporter 5 as a renal steroid sulfate transporter

A family of organic anion transporters (OAT) recently identified has important roles for the excretion or reabsorption of endogenous and exogenous compounds, and several new isoforms have been reported in this decade. Although the transepithelial transport properties of organic anions are gradually being understood, many portions of their functional characteristics in functions remain to be elucidated. A recently reported new cDNA encoding a mouse OAT5 (mOAT5) was constructed, using 3'-RACE PCR, with the total RNA isolated from a mouse kidney. When mOAT5 was expressed in Xenopus oocytes, mOAT5 transported estrone sulfate, dehydroepiandrosterone sulfate and ochratoxin A. Estrone sulfate uptake by mOAT5 displayed a time-dependent and sodium-independent manner. The Km values of estrone sulfate and dehydroepiandrosterone sulfate were 2.2 and 3.8 microM, respectively. mOAT5 interacted with chemically heterogeneous steroid or organic sulfates, such as nitrophenyl sulfate, methylumbelliferyl sulfate and estradiol sulfates. In contrast to the sulfate conjugates, mOAT5-mediated estrone sulfate uptake was not inhibited by the steroid or organic glucuronides. The mOAT5 protein having about 85 kDa molecular weight was shown to be mainly localized in the apical membrane of the proximal tubules of the outer medulla. These results suggest an important role of mOAT5 for the excretion or reabsorption of steroid sulfates in the kidney.     

Influence of neomycin pretreatment on stimulated and maturative renal transport of p-aminohippurate (PAH)

Renal tubular transport of organic anions is immature at birth and can be stimulated in adult rats by repeated administration of xenobiotics. There is some evidence of an increased synthesis of carrier proteins in renal tubular cells following stimulation as well as during postnatal development of renal tubular transport processes. The effect of pretreatment with an inhibitor of protein biosynthesis (neomycin) on stimulated and maturative transport of p-aminohippurate (PAH) was measured. Neomycin has a dose dependent long acting and reversible effect on stimulated PAH transport and on postnatal maturation of PAH excretion, and increased protein biosynthesis is the likely common basic phenomenon of both processes.     

Phosphate transport by reconstructed monolayers from cultured mouse kidney cells

A reconstructed monolayer was formed using epithelial cells from normal mouse kidney to investigate the hormonal effect on phosphate transport by the renal cells. The cells, when cultured on a Millipore filter, formed a monolayer with an apical negative transepithelial potential of 8.4 +/- 0.4 mV. When radioactive phosphate was added onto the apical surface of the monolayer (corresponding to the luminal surface of a renal tubule), the phosphate was transported through the cell layer to the basolateral surface (corresponding to the peritubular surface of a renal tubule). This transport process was saturable, energy-dependent, and inhibited by 2,4-dinitrophenol or ouabain. Dose-dependent parathyroid hormone-induced inhibition (73% of the control) was also evident in this system. Similar inhibition (69% of the control) was observed with DBcAMP. Thus, monolayers reconstructed from cultured mouse kidney cells show characteristics similar to those of renal tubules.     

Inorganic anions and the renal organic cation transport system

During renal secretion, organic cations (OC) have to pass two hydrophobic membranes (basolateral and luminal) and the intervening aqueous cytoplasm. Furthermore, an uptake in intracellular endosomes may also occur. OC transport critically depends on the presence or absence of certain inorganic anions, such as Cl-, HCO3-, and others. The interaction between inorganic anions and OC may occur during the transport across the membranes or uptake by endosomes, by alterations of the transport protein or the substrate and by changes of the intracellular pH.     

Evidence for two interacting ligand binding sites in human multidrug resistance protein 2 (ATP binding cassette C2)

Multidrug resistance protein 2 (MRP2) belongs to the ATP binding cassette family of transporters. Its substrates include organic anions and anticancer drugs. We have used transport assays with vesicles derived from Sf9 insect cells overproducing MRP2 to study the interactions of drugs, organic anions, and bile acids with three MRP2 substrates: estradiol-17-beta-d-glucuronide (E217betaG), methotrexate, and glutathione-S-dinitrophenol. Complex inhibition and stimulation patterns were obtained, different from those observed with the related transporters MRP1 and MRP3. In contrast to a previous report, we found that the rate of E217betaG transport by MRP2 increases sigmoidally with substrate concentration indicative of homotropic cooperativity. Half-maximal transport was obtained at 120 microm E217betaG, in contrast to values < 20 microm for MRP1 and 3. MRP2 stimulators, such as indomethacin and sulfanitran, strongly increased the affinity of MRP2 for E217betaG (half-maximal transport rates at 65 and 16 microm E217betaG, respectively) and shifted the sigmoidal dependence of transport rate on substrate concentration to a more hyperbolic one, without substantially affecting the maximal transport rate. Sulfanitran also stimulated MRP2 activity in cells, i.e. the transport of saquinavir through monolayers of Madin-Darby canine kidney II cells. Some compounds that stimulate E217betaG transport, such as penicillin G or pantoprazole, are not detectably transported by MRP2, suggesting that they allosterically stimulate transport without being cotransported with E217betaG. We propose that MRP2 contains two similar but nonidentical ligand binding sites: one site from which substrate is transported and a second site that regulates the affinity of the transport site for the substrate.     

Separation and Determination of Heavy Metals Associated with Low Molecular Weight Chelators in Xylem Saps of Indian Mustard (<Emphasis Type="Italic">Brassica juncea</Emphasis>) by Size Exclusion Chromatography and Atomic Absorption Spectrometry

To elucidate the role of low molecular weight chelators in long-distance root-to-shoot transport of heavy metals in Indian mustard, an “off-line” size exclusion high-performance liquid chromatography–graphite furnace atomic absorption spectrometry was developed to investigate heavy metals associated with low molecular weight chelators in xylem saps of Indian mustard (Brassica juncea). The size exclusion chromatogram presented only the peaks with molecular weight for all xylem saps and directly indicated the long-distance transport of phytochelatins (PCs) of Indian mustard under Cd stress. In the absence of Cd stress, only organic acids and inorganic anions participated in the long-distance transport of Cd, but organic acids, inorganic anions, glutathione (GSH), and cysteine might relate to the long-distance transport of Cu or Zn. In the presence of Cd stress, PCs were induced, and Cd ions in xylem saps were associated with the induced PCs. As the Cd levels in nutrient solution increased, more Cd in xylem saps adopted the form of PC–Cd. Although PCs might participate in the long-distance transport of Cd under Cd stress, the majority of Cd was still transported by organic acids and inorganic anions in xylem vessels. Moreover, results indicated the existence of complexation competition for GSH and cysteine between Cd and Cu (or Zn) and complexation competition for Cd between PCs and GSH (or cysteine) in xylem vessels. Our work might be very useful for understanding the mechanism of long-distance transport of heavy metals in hyperaccumulator.     

Renal organic anion transport: a comparative and cellular perspective

A major system for net transepithelial secretion of a wide range of hydrophobic organic anions (OAs) exists in the proximal renal tubules of almost all vertebrates. This process involves transport into the cells against an electrochemical gradient at the basolateral membrane and movement from the cells into the lumen down an electrochemical gradient. Transport into the cells at the basolateral membrane, which is the dominant, rate-limiting step, is a tertiary active transport process, the final step which involves countertransport of the OA into the cells against its electrochemical gradient in exchange for alpha-ketoglutarate moving out of the cells down its electrochemical gradient. The outwardly directed gradient for alpha-ketoglutarate is maintained by metabolism ( approximately 40%) and by transport into the cells across both the basolateral and luminal membranes by separate sodium-dicarboxylate cotransporters ( approximately 60%). The inwardly directed sodium gradient driving alpha-ketoglutarate uptake is maintained by the basolateral Na(+)-K(+)-ATPase, the primary energy-requiring transport step in the total tertiary process. The basolateral OA/alpha-ketoglutarate exchange process now appears to be physiologically regulated by several factors in mammalian tubules, including peptide hormones (e.g., bradykinin) and the autonomic nervous system acting via protein kinase C (PKC) pathways and epidermal growth factor (EGF) working via the mitogen-activated protein kinase (MAPK) pathway.     

Tetraethylammonium and nicotine transport by the Malpighian tubules of insects

We examined transepithelial transport of the prototypical type I organic cation (OC) tetraethylammonium (TEA) and the plant alkaloid nicotine by the isolated Malpighian tubules (MTs) of nine insect species from six orders. Isolated tubules were exposed to radiolabelled forms of either TEA or nicotine in the bathing (basal) fluid. Luminal (apical) secreted fluid was collected and TEA or nicotine concentration was determined. Active net transport of nicotine from bath to lumen was observed by the MTs of all the insects studied. TEA was also transported from bath to lumen in MTs of all species except Rhodnius prolixus and Aedes aegypti. MTs of both of these blood feeders did not show active transport of TEA under normal physiological conditions. Transport of TEA but not nicotine increased during the moult in the MTs of Rhodnius, but the concentrations of TEA in the secreted fluid were still consistent with passive accumulation in response to the lumen-negative transepithelial potential. Nicotine transport by Rhodnius MTs was inhibited by the type II OC quinidine, a known p-glycoprotein inhibitor, but not by the type I OCs N-methylnicotinamide or cimetidine. Taken together, the results suggest that active transport of OCs by the MTs is common among species from different orders and that transepithelial TEA and nicotine transport occur through separate pathways.     

Modulation of the basolateral and apical step of transepithelial organic anion secretion in proximal tubular opossum kidney cells. Acute effects of epidermal growth factor and mitogen-activated protein kinase

The organic anion transport system in the proximal tubule of the kidney is of major importance for the excretion of a variety of endogenous and potentially toxic exogenous substances. Furthermore, the clearance of model substrates (e.g. para-aminohippurate) of this system is used for the determination of renal blood flow. We investigated regulation of organic anion secretion in a way that allowed us to examine simultaneously regulation of overall transepithelial secretion and to estimate the separate contributions of regulation of the basolateral and apical transport steps to this overall regulation. The data were verified by measurement of initial basolateral uptake rate and initial apical efflux rate. Opossum kidney cells were used as a suitable model system for proximal tubule cells, and [14C]para-aminohippurate was utilized as an organic anion. Stimulation of protein kinase C inhibited transepithelial secretion because of inhibition of both apical efflux and basolateral uptake. Inhibition of the mitogen-activated protein kinase (MAPK) kinase MEK reduced transepithelial secretion via inhibition of basolateral uptake and apical efflux. Epidermal growth factor (EGF) enhanced transepithelial secretion via stimulation of basolateral uptake but did not affect apical efflux. EGF induced stimulation of basolateral uptake was abolished by inhibition of MEK. EGF led to phosphorylation of ERK1/2, which was also abolished by inhibition of MEK. Thus, EGF stimulated basolateral uptake of organic anions via MAPKs. Transepithelial organic anion secretion can be regulated at two sites, at least: basolateral uptake and apical efflux. Both steps are under control of protein kinase C and MAPK. The pathophysiologically relevant growth factor EGF enhances transepithelial secretion via stimulation of basolateral uptake. EGF stimulates basolateral uptake via MEK and ERK1/2. Thus, renal organic anion extraction may be modulated, especially under pathophysiological conditions.     

Transepithelial transport of salicylate by the Malpighian tubules of insects from different orders

The organic anion salicylate is a plant secondary metabolite that protects plants against phytophagous insects. In this study, a combination of salicylate-selective microelectrodes and a radioisotope tracer technique was used to study the transepithelial transport of salicylate by the Malpighian tubules of 10 species of insects from five orders. Our results show that salicylate is transported into the lumen of the Malpighian tubules in all the species evaluated, except Rhodnius prolixus. The transepithelial transport of salicylate by the Malpighian tubules of Drosophila simulans, Drosophila erecta, Drosophila sechellia, and Acheta domesticus was saturable, Na⁺-dependent and inhibited by α-cyano-4-hydroxycinnamic acid. This transport system resembles that previously found in tubules of Drosophila melanogaster. In contrast, transepithelial transport of salicylate by Malpighian tubules of Tenebrio molitor, Plagiodera versicolora, Aedes aegypti, and Trichoplusia ni was unaffected by Na⁺-free bathing saline. The presence of both salicylate and salicylate metabolites in the secreted fluid samples from the Malpighian tubules of A. domesticus, R. prolixus, T. molitor, and T. ni indicates that insect Malpighian tubules may both transport and metabolize salicylate. The highest capacities to rid the hemolymph of salicylate were found in T. molitor, P. versicolora and Drosphila spp. Our results suggest that transport of salicylate by the Malpighian tubules might contribute to elimination of this organic anion from the hemolymph, particularly in some species that encounter high levels of organic anion in the diet.