Induction of glycinebetaine uptake into Xenopus oocytes by injection of poly(A)+ RNA from renal cells exposed to high extracellular NaCl

Madin-Darby canine kidney (MDCK) cells accumulate glycinebetaine via Na(+)-dependent transport in response to hypertonic stress. When extracellular tonicity is increased by the addition of NaCl, Vmax for glycinebetaine transport increases without an associated change in Km, consistent with an increase in the number of functioning transporters. To test whether increased transport activity results from increased gene expression, we injected poly(A)+ RNA (mRNA) from MDCK cells into Xenopus oocytes and assayed for glycinebetaine uptake in ovo. RNA-induced Na(+)-dependent uptake is observed in oocytes injected with mRNA from cells exposed to high extracellular NaCl, but not in oocytes injected with either water or mRNA from cells maintained in isotonic medium. Unfractionated mRNA induces glycinebetaine uptake in ovo at a rate which is approximately 3-fold higher than in water-injected controls. Size-fractionated mRNA (median size 2.8 kilobases) induces uptake at a rate which is approximately 7-fold higher than controls. Such RNA-induced transport activity in ovo is consistent with heterologous expression of Na(+)/glucinebetaine cotransporters encoded by renal mRNA. Increased transporter mRNA in cells exposed to hypertonicity probably underlies the pattern of expression observed in ovo. This can account for the observed rise in MDCK cell glycinebetaine transport during hypertonic stress.     

Functional expression of the intestinal peptide-proton co-transporter in Xenopus laevis oocytes.

The expression of the intestinal peptide-proton cotransporter was examined in Xenopus laevis oocytes by microinjection of poly(A)+ mRNA prepared from rabbit intestinal mucosal cells. The concomitant expression of the glucose-sodium co-transporter was used as the control for the effectiveness of the expression technique. There was significant endogenous activity of Gly-Sar uptake in water-injected oocytes, but the uptake activity increased nearly 3-fold in poly(A)+ mRNA-injected oocytes. The expression of the peptide transporter was time-dependent. There was no detectable expression on day 1 after injection. The expression became noticeable on day 2 and increased with time, reaching a maximum on day 4. There was no further change on days 5 and 6. The endogenous uptake rate measured in water-injected oocytes, on the contrary, showed a slight decrease during this time. The expressed peptide transporter retained its substrate specificity, having affinity for the dipeptides, Gly-Sar and Gly-Pro, and no or little affinity for the free amino acids, Gly and Sar. The expressed peptide transporter also showed a dependence on a transmembrane H+ gradient for maximal activity. These data demonstrate that the mammalian intestinal peptide-proton co-transporter can be successfully expressed in Xenopus laevis oocytes. This expression system can provide an effective assay procedure to clone the gene encoding the transporter.     

Expression of Size-Selected RNA Encoding Brain Serotonin Transporter in Xenopus laevis Oocytes

The mRNA that encodes a serotonin transporter was expressed using the Xenopus laevis oocyte expression system. Poly(A)+ RNA isolated from mouse brainstem was injected into Xenopus laevis oocytes, and the ability of oocytes to take up serotonin was measured 3 days postinjection. RNA-dependent serotonin uptake was sensitive to citalopram, a specific inhibitor of serotonin uptake, whereas background levels of serotonin uptake were not citalopram sensitive. Two RNA size fractions, 4.0 and 4.5 kb, were most efficient in stimulating uptake. Injection into Xenopus laevis oocytes of the 4.5-kb size fraction of mouse brainstem RNA resulted in threefold more serotonin uptake than did injection of unfractionated poly(A)+ RNA.     

Expression of rat liver canalicular sulfate carrier in Xenopus laevis oocytes

Poly(A)+ RNA (mRNA)extracted from rat liver was injected into Xenopus laevis oocytes and the expression of sulfate transport was determined by measuring [35S] sulfate uptake. Compared to water-injected oocytes, which exhibited virtually no sulfate uptake, injection of rat liver mRNA resulted in a time- and dose-dependent increase in uptake of sulfate. Depending on the method used for the isolation of the mRNA, sulfate uptake was stimulated after injection (40 ng after 6 days) between 8- and 72-fold compared to water-injected oocytes. Sulfate uptake of oocytes injected with mRNA was found to be sensitive to 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (IC50 less than 20 microM) and could also be inhibited by thiosulfate. Sulfate uptake of injected oocytes showed Michaelis-Menten kinetics (apparent Km, 0.31 mM) which is similar to the Km of the sulfate/bicarbonate antiporter of rat liver canalicular plasma membranes. After fractionation by a sucrose density gradient, the mRNA encoding for the expressed rat liver sulfate carrier was found in fractions containing messages of 3.5-4.0 kilobases in length.     

Expression of rat liver glutamine transporters in Xenopus laevis oocytes.

As a first step in attempting to isolate the Na(+)-dependent System N transporter from rat liver we have investigated the use of prophase-arrested oocytes from Xenopus laevis for the functional expression of rat liver glutamine transporters. Individual oocytes, defolliculated by collagenase treatment, were injected with 50 nl of a 1 mg.ml-1 solution of poly(A)+ RNA (mRNA) isolated from rat liver. 50 microM L-[3H]glutamine uptake was measured 1-5 days post-injection: after 48 h, poly(A)+ RNA-injected oocytes showed a 60 +/- 12% increase in Na(+)-dependent glutamine uptake compared to controls. This increased uptake showed characteristic features of hepatic System N: that is, it tolerated Li(+)-for-Na+ substitution and was inhibited by the System N substrate L-histidine (5 mM) in Li medium, unlike endogenous Na(+)-dependent glutamine transport. In subsequent experiments rat liver poly(A)+ RNA, size-fractionated by density gradient fractionation, was injected into oocytes. Injection of poly(A)+ RNA of 1.9-2.8 kilobases (kb) in size resulted in a significant stimulation of Na(+)-dependent glutamine transport to 0.362 +/- 0.080 pmol.min-1/oocyte from 0.178 +/- 0.060 pmol.min-1/oocyte in vehicle-injected oocytes (p less than 0.01). A lighter fraction, with poly(A)+ RNA of less than 1.9 kilobases size resulted in a similar increase in Na(+)-dependent glutamine uptake which was largely Li(+)-tolerant: Li(+)-stimulated glutamine uptake in oocytes injected with this fraction increased to 0.230 +/- 0.070 pmol.min-1/oocyte from 0.098 +/- 0.029 pmol.min-1/oocyte in controls (p less than 0.05). This enhanced rate of Li(+)-stimulated glutamine uptake was inhibited 28 and 70%, respectively, by 1 and 5 mM L-histidine. Na(+)-independent uptake of glutamine rose by 72 +/- 12% in oocytes injected with poly(A)+ RNA of 2.8-3.6 kb (p less than 0.001). These results demonstrate that glutamine transporters, with characteristics associated with hepatic Systems N, L, and A (or ASC), can be expressed in X. laevis oocytes injected with specific size fractions of rat liver mRNA.     

Involvement of rBAT in Na(+)-dependent and -independent transport of the neurotransmitter candidate L-DOPA in Xenopus laevis oocytes injected with rabbit small intestinal epithelium poly A(+) RNA

Although L-3,4-dihydroxyphenylalanine (L-DOPA) is claimed to be a neurotransmitter in the central nervous system (CNS), receptor or transporter molecules for L-DOPA have not been determined. In an attempt to identify a transporter for L-DOPA, we examined whether or not an active and high affinity L-DOPA transport system is expressed in Xenopus laevis oocytes injected with poly A(+) RNA prepared from several tissues. Among the poly A(+) RNAs tested, rabbit intestinal epithelium poly A(+) RNA gave the highest transport activity for L-[(14)C]DOPA in the oocytes. The uptake was approximately five times higher than that of water-injected oocytes, and was partially Na(+)-dependent. L-Tyrosine, L-phenylalanine, L-leucine and L-lysine inhibited this transport activity, whereas D-DOPA, dopamine, glutamate and L-DOPA cyclohexylester, an L-DOPA antagonist did not affect this transport. Coinjection of an antisense cRNA, as well as oligonucleotide complementary to rabbit rBAT (NBAT) cDNA almost completely inhibited the uptake of L-[(14)C]DOPA in the oocytes. On the other hand, an antisense cRNA of rabbit 4F2hc barely affected this L-[(14)C]DOPA uptake activity. rBAT was thus responsible for the L-[(14)C]DOPA uptake activity expressed in X. laevis oocytes injected with poly A(+) RNA from rabbit intestinal epithelium. As rBAT is localized at the target regions of L-DOPA in the CNS, rBAT might be one of the components involved in L-DOPAergic neurotransmission.     

Functional expression of urea channels in amphibian oocytes injected with frog urinary bladder mRNA.

In amphibian urinary bladder epithelium, vasopressin increases passive urea permeability, concomitant with the appearance of a facilitated urea transport. Amphibian oocytes from Xenopus laevis and Rana esculenta were microinjected with total or fractionated poly(A+) RNA isolated from frog urinary bladder epithelial cells. After several (3-5) days at 18 degrees C, the urea flux was assayed by measuring the uptake and efflux of [14C]urea in water-injected and mRNA-injected oocytes. A 2 to 3-fold increase of urea transport was detected in oocytes injected either with total mRNA or with a 6-10 kilobase mRNA fraction, when compared with water-injected oocytes. This expression of urea channels was inhibited by 0.1 mM phloretin (50% inhibition) and 0.1 mM nitrophenylthiourea (up to 70% inhibition). On the contrary, no expression was detected in brain mRNA-injected oocytes. These results show the specific functional expression of the phloretin- and NPTU-sensitive urea channel (or carrier) from frog urinary bladder epithelial cells, providing an approach for the expression cloning of these urea channels.     

Functional expression of the rabbit intestinal Na+/L-proline cotransporter (IMINO system) in Xenopus laevis oocytes

Proline absorption across small intestine takes place mainly through a Na+-dependent cotransporter localized at the brush border membrane of the enterocyte named IMINO system. It transports L-proline and 4-OH-proline but not L-alanine, neither cationic nor anionic amino acids. The present work demonstrates the functional expression of this transporter in Xenopus laevis oocytes by mRNA microinjection and radiotracer uptake techniques. Poly (A)+-RNA was isolated from rabbit jejunal mucosa and injected into oocytes. Five days after the injection, results showed 1.5 fold stimulation of 50 microM 3H-proline uptake by the injected oocytes when compared to the non injected oocytes uptake. Poly (A)+-RNA was sized fractionated and fractions were injected again. Increase on Na+-dependent L-proline uptake was obtained with a mRNA fraction between 2,4 and 4,4 kb, which was used to construct a cDNA library. The library was sequentially divided and cRNAs injected into oocytes in order to screen for an increment on the signal. A subdivision containing around 2,000 colonies was found to augment L-proline uptake 25 fold over the non injected oocytes uptake. This cRNA pool was used to further characterize the transporter. Results showed that in the absence of Na+ there was no L-proline uptake, 2 mM 4-OH-L-proline completely inhibited 50 microM proline uptake and there was no 50 microM alanine uptake. In summary, these results demonstrate the expression of the rabbit small intestine IMINO transporter in Xenopus laevis oocytes and support the next steps in the isolation of the clone.     

Expression of renal transport systems for inorganic phosphate and sulfate in Xenopus laevis oocytes.

As a first step within an experimental strategy (expression cloning) leading to the structural identification of the two brush-border membrane transport systems for phosphate and sulfate, we have studied the expression of Na(+)-dependent uptake of phosphate and sulfate in Xenopus laevis oocytes injected with rabbit kidney cortex poly(A)+ RNA (mRNA). Na(+)-dependent uptake of phosphate and sulfate was stimulated in a dose- and time-dependent manner up to 20-fold as compared to water-injected controls. After fractionation of the mRNA on a sucrose gradient (or by preparative gel electrophoresis), two neighboring fractions were identified to stimulate Na(+)-dependent phosphate uptake (average size: 3.4 kilobases) and Na(+)-dependent sulfate uptake (average size: 3.7 kilobases). The two transport systems can be discriminated by their inhibition by thiosulfate, which reduced sulfate uptake, but not phosphate uptake. Kinetic characterization of the expressed Na(+)-dependent transport activities results in properties similar to those described for transport activity in renal brush-border membrane vesicles.     

Expression of phenolic and tyrosyl ring iodothyronine deiodinases in Xenopus laevis oocytes is dependent on the tissue source of injected poly(A)+ RNA

The phenolic (5' position) and tyrosyl (5 position) ring deiodinases which catalyze the peripheral metabolism of thyroid hormones have proven difficult to purify and characterize biochemically. The present studies used Xenopus laevis oocytes as an in vivo translational assay system for detecting and quantitating mRNA for these enzymes. The injection of poly(A)+ RNA prepared from a human term placenta induced 5-deiodinase activity in oocytes. The expressed activity increased for up to 96 h after injection, was proportional to the amount of RNA injected, and manifested a Michaelis-Menten constant (Km) for T3 of 1.6 nM. In oocytes injected with poly(A)+ RNA prepared from rat liver, anterior pituitary gland, or brown adipose tissue, 5-deiodinase activity could not be demonstrated. The injection of poly(A)+ RNA from 15-day-old chick embryonic liver induced both 5'- and 5-deiodinase activity, with the 5'-deiodinase activity being sensitive to inhibition by 6-n-propyl-2-thiouracil. X. laevis oocytes can thus be induced to express either phenolic or tyrosyl ring deiodinase activity, or both, by the microinjection of poly(A)+ RNA prepared from selected tissues. These findings demonstrate that the types of deiodinase activity present in different organs represent tissue specific patterns of mRNA expression and strongly suggest that the enzymes responsible for types I and III deiodinase activity are encoded by different mRNAs.     

Expression of rat liver Na+/L-alanine co-transport in Xenopus laevis oocytes. Effect of glucagon in vivo.

Poly(A)+ RNA (mRNA) isolated from rat liver was injected into Xenopus laevis oocytes, and expression of Na+/L-alanine transport was assayed by measuring Na(+)-dependent uptake of L-[3H]alanine. Expression of Na+/L-alanine transport was detected 3-7 days after mRNA injection, and was due to an increment of the Na(+)-dependent component. After injection of 40 ng of total mRNA, Na(+)-dependent uptake of L-alanine was 2.5-fold higher than in water-injected oocytes. In contrast with Na+/L-alanine transport by water-injected oocytes, expressed Na+/L-alanine transport was inhibited by N-methylaminoisobutyric acid, was inhibited by an extracellular pH of 6.5 and was saturated at approx. 1 mM-L-alanine. After sucrose-density-gradient fractionation, highest expression of Na+/L-alanine uptake was observed with mRNA of 1.9-2.5 kb in length. Compared with mRNA isolated from control rats, mRNA isolated from glucagon-treated rats showed a approx. 2-fold higher expression of Na+/L-alanine transport. The results demonstrate that both liver Na+/L-alanine transport systems (A and ASC) can be expressed in X. laevis oocytes. Furthermore, the data obtained with mRNA isolated from glucagon-treated rats suggest that glucagon regulates liver Na+/L-alanine transport (at least in part) via the availability of the corresponding mRNA.     

Characterization of the defect in the Na(+)-phosphate transporter in vitamin D-resistant hypophosphatemic mice.

Hypophosphatemic vitamin D-resistant rickets is the most common form of vitamin D-resistant rickets in man. The hypophosphatemic mouse model (Hyp) is phenotypically and biochemically similar to the human disease. Biochemically, hypophosphatemia is the hallmark of this disorder. The cause of the hypophosphatemia is thought to be secondary to a defect in the renal and/or intestinal Na(+)-phosphate transporter. The current studies were designed to investigate and characterize the localization of the defect in the Na(+)-phosphate transporter in this disorder. Phosphate uptake by renal brush border membrane vesicles (BBMV) showed a significant decrease in the slope of the initial rate of phosphate uptake in (Hyp) compared with control mice (0.009 versus 0.013, respectively). The slopes representing initial rates of phosphate uptake by jejunal BBMV were similar in (Hyp) and control mice (0.004 and 0.004, respectively). Kinetics of jejunal Na(+)-dependent phosphate uptake showed a Vmax of 0.63 +/- 0.12 and 0.64 +/- 0.12 nmol/mg protein/15 s in (Hyp) and control mice, respectively, whereas Km values were 0.12 +/- 0.08 and 0.2 +/- 0.11 mM, respectively. Similar kinetic analysis in the kidney showed a Vmax of 0.32 +/- 0.06 and 1.6 +/- 0.1 (p less than 0.01) and Km of 0.07 +/- 0.06 and 0.39 +/- 0.05 (p less than 0.02) in (Hyp) and control mice, respectively. Na(+)-dependent D-glucose uptake by BBMVs of intestine and kidney showed typical overshoot phenomena in (Hyp) and control mice. In order to explore these findings further, Na(+)-phosphate transporter expression from intestine and kidney was accomplished by microinjection of 50 ng of poly(A)+ RNA into Xenopus laevis oocytes. Na(+)-dependent phosphate uptake was expressed 6 days after the microinjection of intestinal and kidney poly(A)+ RNA from control mice. However, expression of the transporter from (Hyp) mice occurred only from the intestine, and not from the kidney. The decrease in the expression of the Na(+)-dependent phosphate transporter was not secondary to accelerated efflux of phosphate or decreased metabolism in oocytes injected with poly(A)+ RNA from (Hyp) mice.(ABSTRACT TRUNCATED AT 400 WORDS)     

Receptor number determines latency and amplitude of the thyrotropin-releasing hormone response in Xenopus oocytes injected with pituitary RNA

TRH evokes depolarizing membrane electrical responses in Xenopus laevis oocytes injected with RNA from pituitary cells. We have shown previously that the amplitude of this response is directly proportional to the dose of TRH and the amount of RNA injected. Herein we show that the number of TRH receptors expressed on oocytes after injection of rat pituitary (GH3) cell RNA or mouse thyrotropic (TtT) tumor RNA determines the latency as well as the amplitude of the response. In oocytes injected with a maximally effective amount of GH3 cell RNA, the latency of the response decreased from a maximal duration of 103 +/- 16 to 10 +/- 1 sec when the TRH concentration was increased from 5 to 3000 nM. When oocytes injected with different amounts of GH3 cell RNA were stimulated with 3000 nM TRH, the latency decreased from 31 +/- 4 to 11 +/- 0.5 sec when the amount of RNA injected was increased from 30 to 400 ng. Specific binding of [3H]methylhistidine-TRH increased when increasing amounts of TtT poly(A)+ RNA was injected, and binding correlated with increased response amplitude. To show that these effects were caused by mRNA for the TRH receptor and did not depend on other mRNAs, TtT poly(A)+ RNA was fractionated on a sucrose gradient. Using RNA from each fraction, there was an inverse correlation between response amplitude and latency. For size-fractionated RNA, as for unfractionated RNA, there was a direct correlation between specific [3H]methylhistidine-TRH binding and response amplitude.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional reconstitution of a receptor-activated signal transduction pathway in Xenopus laevis oocytes using the cloned human C5a receptor.

We have used the polymerase chain reaction to isolate and clone the cDNA encoding the human C5a receptor, and have injected the cDNA-derived receptor cRNA into Xenopus laevis oocytes for functional characterization of the receptor protein. Receptor activity was determined either electrophysiologically by measuring the agonist-dependent opening of [Ca2+]i-dependent Cl- channels, or by analysing the agonist-dependent efflux of 45Ca2+ from the oocytes. Using both methodologies, injection of pure C5a receptor cRNA failed to confer C5a sensitivity on the oocytes. In contrast, marked responses to C5a were observed when the receptor cRNA was supplemented with poly(A)+ RNA isolated from undifferentiated HL-60 cells, which is devoid of C5a receptor mRNA. Binding studies using radioiodinated C5a revealed that the C5a receptor polypeptide was in fact synthesized and targeted to the oocyte plasma membrane in oocytes injected with receptor cRNA alone, and that the level of receptor expression was not influenced by coinjection of poly(A)+ RNA from undifferentiated HL-60 cells. These results strongly suggest that the human C5a receptor requires a specific cofactor(s) lacking in Xenopus oocytes but present in undifferentiated HL-60 cells, to generate intracellular signals in oocytes. Identification and characterization of this factor will provide important information about the molecular mechanisms by which G-protein-coupled receptors activate phospholipase C.     

Polarized nature of taurine transport in LLC-PK1 and MDCK cells: Further characterization of divergent transport models

Summary Taurine transport was measured in cultured epithelial cells-LLC-PK1 and MDCK-grown on permeable membrane supports. Taurine transport by LLC-PK1 cells was greater on the apical surface compared to the basolateral surface. MDCK cells exhibited greater taurine uptake from the basolateral side. Transepithelial taurine flux was in the direction of apical to basolateral in the LLC-PK1 monolayers. There was no net transepithelial movement of taurine in the MDCK monolayers. Efflux of taurine from the apical and the basolateral membrane surfaces of LLC-PK1 cell monolayers was stimulated by external-alanine but not L-alanine. Efflux of taurine from MDCK cell monolayers was stimulated by-alanine on the basolateral surface. While the competitive inhibitor guainidinoeithane sulfonate (GES) competitively inhibited taurine uptake to a similar degree on the apical and basolateral surface of LLC-PK1 cell monolayers, GES had a more potent inhibitory effect on the basolateral taurine uptake in MDCK cells when compared to its inhibition of apical taurine transport. We conclude that there are characteristic differences in transport of taurine by apical and basolateral surfaces of LLC-PK1 and MDCK cells which may be the consequence of asymmetric distribution or unique structural properties of the taurine transporter.Supported by a grant from the National Institutes of Health (DK 37223), the American Heart Association (92-004470).     

Chinese hamster ovary mRNA-dependent, Na(+)-independent L-leucine transport in Xenopus laevis oocytes.

In freshly prepared uninjected folliculated oocytes, Na(+)-independent leucine uptake is mediated predominantly by a system L-like transport system. Removal of follicular cells, however, results in an irreversible loss of this transport activity. When total poly(A)+ mRNA derived from Chinese hamster ovary (CHO) cells was injected into prophase-arrested stage V or VI Xenopus laevis oocytes, enhanced expression of Na(+)-independent leucine transport was observed. The injected mRNAs associated with increased levels of leucine uptake were between 2 and 3 kb in length. The newly expressed leucine transport activity exhibited important differences from the known characteristics of system L, which is the dominant Na(+)-independent leucine transporter in CHO cells as well as in freshly isolated folliculated oocytes. The CHO mRNA-dependent leucine uptake in oocytes was highly sensitive to the cationic amino acids lysine, arginine, and and ornithine (> 95% inhibition). As with the leucine uptake, an enhanced lysine uptake was also observed in size-fractionated CHO mRNA-injected oocytes. The uptakes of leucine and lysine were mutually inhibitable, suggesting that the newly expressed transporter was responsible for uptakes of both leucine and lysine. The inhibition of uptake of lysine by leucine was Na+ independent, thus clearly distinguishing it from the previously reported endogenous system y+ activity. Furthermore, the high sensitivity to tryptophan of the CHO mRNA-dependent leucine transport was in sharp contrast to the properties of the recently cloned leucine transport-associated gene from rat kidney tissue, although leucine transport from both sources was sensitive to cationic amino acids. Our results suggest that there may be a family of leucine transporters operative in different tissues and possibly under different conditions.     

Expression of rat jejunal cystine carrier in Xenopus oocytes

Functional interactive cystine-lysine carriers have been expressed in Xenopus oocytes following the injection of RNA extracted from rat intestinal mucosa. Lysine-inhibitable cystine uptake was able to be measured 16 h after oocyte injection with RNA. The longer the oocytes were maintained after injection, the more cystine transport capability was induced. Uninjected or water-injected oocytes showed virtually no lysine-inhibitable cystine uptake, and no system developed after the oocytes had been isolated and maintained in vitro. The cystine uptake expressed after RNA injection was selectively inhibited by dibasic amino acids and phenylalanine but not by other amino acids or alpha-methyl-D-glucoside. Expression of the interactive cystine-lysine system was induced only by RNA isolated from intestinal tissue and not by RNA from rat liver. The Km for cystine uptake in RNA-injected oocytes was 0.01 mM and appears identical to the single system found in the RNA source tissue.     

Expression of epithelial Na channels in Xenopus oocytes

Epithelial Na channel activity was expressed in oocytes from Xenopus laevis after injection of mRNA from A6 cells, derived from Xenopus kidney. Poly A(+) RNA was extracted from confluent cell monolayers grown on either plastic or permeable supports. 1-50 ng RNA was injected into stage 5-6 oocytes. Na channel activity was assayed as amiloride- sensitive current (INa) under voltage-clamp conditions 1-3 d after injection. INa was not detectable in noninjected or water-injected oocytes. This amiloride-sensitive pathway induced by the mRNA had a number of characteristics in common with that in epithelial cells, including (a) high selectivity for Na over K, (b) high sensitivity to amiloride with an apparent K1 of approximately 100 nM, (c) saturation with respect to external Na with an apparent Km of approximately 10 mM, and (d) a time-dependent activation of current with hyperpolarization of the oocyte membrane. Expression of channel activity was temperature dependent, being slow at 19 degrees C but much more rapid at 25 degrees C. Fractionation of mRNA on a sucrose density gradient revealed that the species of RNA inducing channel activity had a sedimentation coefficient of approximately 17 S. Treatment of filter-grown cells with 300 nM aldosterone for 24 h increased Na transport in the A6 cells by up to fivefold but did not increase the ability of mRNA isolated from those cells to induce channel activity in oocytes. The apparent abundance of mRNA coding for channel activity was 10-fold less in cells grown on plastic than in those grown on filters, but was increased two- to threefold by aldosterone.