Amyloid Deposition of the Bilateral Ureters in a Patient With Chronic Systemic AL Amyloidosis.

Amyloid of the ureter is a rare disease with less than 25 cases reported in the literature. Despite being rare, it remains an important entity as it is typically confused with a primary neoplastic process of the urinary system. We report a case of a 68-year-old male with a history of cutaneous amyloid with late presentation of bilateral ureteral involvement.

Acid detection by taste receptor cells.

Sourness is a primary taste quality that evokes an innate rejection response in humans and many other animals. Acidic stimuli are the unique sources of sour taste so a rejection response may serve to discourage ingestion of foods spoiled by acid producing microorganisms. The investigation of mechanisms by which acids excite taste receptor cells (TRCs) is complicated by wide species variability and within a species, apparently different mechanisms for strong and weak acids. The problem is further complicated by the fact that the receptor cells are polarized epithelial cells with different apical and basolateral membrane properties. The cellular mechanisms proposed for acid sensing in taste cells include, the direct blockage of apical K(+) channels by protons, an H(+)-gated Ca(2+) channel, proton conduction through apical amiloride-blockable Na(+) channels, a Cl(-) conductance blocked by NPPB, the activation of the proton-gated channel, BNC-1, a member of the Na(+) channel/degenerin super family, and by stimulus-evoked changes in intracellular pH. Acid-induced intracellular pH changes appear to be similar to those reported in other mammalian acid-sensing cells, such as type-I cells of the carotid body, and neurons found in the ventrolateral medulla, nucleus of the solitary tract, the medullary raphe, and the locus coceuleus. Like type-I carotid body cells and brainstem neurons, isolated TRCs demonstrate a linear relationship between intracellular pH (pH(i)) and extracellular pH (pH(o)) with slope, DeltapH(i)/DeltapH(o) near unity. Acid-sensing cells also appear to regulate pH(i) when intracellular pH changes occur under iso-extracellular pH conditions, but fail to regulate their pH when pH(i) changes are induced by decreasing extracellular pH. We shall discuss the current status of proposed acid-sensing taste mechanisms, emphasizing pH-tracking in receptor cells.

A novel pharmacological probe links the amiloride-insensitive NaCl, KCl, and NH(4)Cl chorda tympani taste responses.

Chorda tympani taste nerve responses to NaCl can be dissected pharmacologically into amiloride-sensitive and -insensitive components. It is now established that the amiloride-sensitive, epithelial sodium channel acts as a sodium-specific ion detector in taste receptor cells (TRCs). Much less is known regarding the cellular origin of the amiloride-insensitive component, but its anion dependence indicates an important role for paracellular shunts in the determination of its magnitude. However, this has not precluded the possibility that undetected apical membrane ion pathways in TRCs may also contribute to its origin. Progress toward making such a determination has suffered from lack of a pharmacological probe for an apical amiloride-insensitive taste pathway. We present data here showing that, depending on the concentration used, cetylpyridinium chloride (CPC) can either enhance or inhibit the amiloride-insensitive response to NaCl. The CPC concentration giving maximal enhancement was 250 microM. At 2 mM, CPC inhibited the entire amiloride-insensitive part of the NaCl response. The NaCl response is, therefore, composed entirely of amiloride- and CPC-sensitive components. The magnitude of the maximally enhanced CPC-sensitive component varied with the NaCl concentration and was half-maximal at [NaCl] = 62 +/- 11 (SE) mM. This was significantly less than the corresponding parameter for the amiloride-sensitive component (268 +/- 71 mM). CPC had similar effects on KCl and NH(4)Cl responses except that in these cases, after inhibition with 2 mM CPC, a significant CPC-insensitive response remained. CPC (2 mM) inhibited intracellular acidification of TRCs due to apically presented NH(4)Cl, suggesting that CPC acts on an apical membrane nonselective cation pathway.

Decrease in rat taste receptor cell intracellular pH is the proximate stimulus in sour taste transduction.

Taste receptor cells (TRCs) respond to acid stimulation, initiating perception of sour taste. Paradoxically, the pH of weak acidic stimuli correlates poorly with the perception of their sourness. A fundamental issue surrounding sour taste reception is the identity of the sour stimulus. We tested the hypothesis that acids induce sour taste perception by penetrating plasma membranes as H(+) ions or as undissociated molecules and decreasing the intracellular pH (pH(i)) of TRCs. Our data suggest that taste nerve responses to weak acids (acetic acid and CO(2)) are independent of stimulus pH but strongly correlate with the intracellular acidification of polarized TRCs. Taste nerve responses to CO(2) were voltage sensitive and were blocked with MK-417, a specific blocker of carbonic anhydrase. Strong acids (HCl) decrease pH(i) in a subset of TRCs that contain a pathway for H(+) entry. Both the apical membrane and the paracellular shunt pathway restrict H(+) entry such that a large decrease in apical pH is translated into a relatively small change in TRC pH(i) within the physiological range. We conclude that a decrease in TRC pH(i) is the proximate stimulus in rat sour taste transduction.

Effect of HCO(3)(-) on TPA- and IBMX-induced anion conductances in Necturus gallbladder epithelial cells.

Effects of HCO(3)(-) on protein kinase C (PKC)- and protein kinase A (PKA)-induced anion conductances were investigated in Necturus gallbladder epithelial cells. In HCO(3)(-)-free media, activation of PKC via 12-O-tetradecanoylphorbol 13-acetate (TPA) depolarized apical membrane potential (V(a)) and decreased fractional apical voltage ratio (F(R)). These effects were blocked by mucosal 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB), a Cl(-) channel blocker. In HCO(3)(-) media, TPA induced significantly greater changes in V(a) and F(R). These effects were blocked only when NPPB was present in both mucosal and basolateral compartments. The data suggest that TPA activates NPPB-sensitive apical Cl(-) conductance (g(Cl)(a)) in the absence of HCO(3)(-); in its presence, TPA stimulated both NPPB-sensitive g(Cl)(a) and basolateral Cl(-) conductance (g(Cl)(b)). Activation of PKA via 3-isobutyl-1-methylxanthine (IBMX) also decreased V(a) and F(R); however, these changes were not affected by external HCO(3)(-). We conclude that HCO(3)(-) modulates the effects of PKC on g(Cl)(b). In HCO(3)(-) medium, TPA and IBMX also induced an initial transient hyperpolarization and increase in intracellular pH. Because these changes were independent of mucosal Na(+) and Cl(-), it is suggested that TPA and IBMX induce a transient increase in apical HCO(3)(-) conductance.

Effects of osmolarity on taste receptor cell size and function.

Osmotic effects on salt taste were studied by recording from the rat chorda tympani (CT) nerve and by measuring changes in cell volume of isolated rat fungiform taste receptor cells (TRCs). Mannitol, cellobiose, urea, or DMSO did not induce CT responses. However, the steady-state CT responses to 150 mM NaCl were significantly increased when the stimulus solutions also contained 300 mM mannitol or cellobiose, but not 600 mM urea or DMSO. The enhanced CT responses to NaCl were reversed when the saccharides were removed and were completely blocked by addition of 100 microM amiloride to the stimulus solution. Exposure of TRCs to hyperosmotic solutions of mannitol or cellobiose induced a rapid and sustained decrease in cell volume that was completely reversible, whereas exposure to hypertonic urea or DMSO did not induce sustained reductions in cell volume. These data suggest that the osmolyte-induced increase in the CT response to NaCl involves a sustained decrease in TRC volume and the activation of amiloride-sensitive apical Na(+) channels.

Acid-induced responses in hamster chorda tympani and intracellular pH tracking by taste receptor cells.

HCl- and NaCl-induced hamster chorda tympani nerve responses were recorded during voltage clamp of the lingual receptive field. Voltage perturbations did not influence responses to HCl. In contrast, responses to NaCl were decreased by submucosal-positive and increased by submucosal-negative voltage clamp. Responses to HCl were insensitive to the Na+ channel blockers, amiloride and benzamil, and to methylisobutylamiloride (MIA), an Na+/H+ exchange blocker. Responses to NaCl were unaffected by MIA but were suppressed by benzamil. Microfluorometric and imaging techniques were used to monitor the relationship between external pH (pHo) and the intracellular pH (pHi) of fungiform papilla taste receptor cells (TRCs) following 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein loading. TRC pHi responded rapidly and monotonically to changes in pHo. This response was unaffected by Na+ removal or the presence of amiloride, benzamil, or MIA. The neural records and the data from isolated TRCs suggest that the principal transduction pathway for acid taste in hamster is similar to that in rat. This may involve the monitoring of changes in TRC pHi mediated through amiloride-insensitive H+ transport across TRC membranes. This is an example of cell monitoring of environmental pH through pH tracking, i.e., a linear change in pHi in response to a change in pHo, as has been proposed for carotid bodies. In taste, the H+ transport sites may be concentrated on the basolateral membranes of TRCs and, therefore, are responsive to an attenuated H+ concentration from diffusion of acids across the tight junctions.

Effects of extracellular pH, PCO2, and HCO3- on intracellular pH in isolated rat taste buds.

We studied the effects of changing external pH (pHo), external bicarbonate concentration ([HCO3-]o), and PCO2 on taste receptor cell (TRC) intracellular pH (pHi) in taste bud fragments (TBFs) isolated from rat circumvallate and fungiform papillae with the pH-sensitive fluoroprobe 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) using microfluorometric and imaging techniques. In N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid-buffered solutions, TRC pHi responded rapidly and monotonically to changes in pHo between 6.5 and 8.0. The relationship between pHi and pHo was steep, with slopes varying between 0.8 and 1.2. Similarly, varying pHo by changing PCO2 at constant [HCO3-]o or changing [HCO3-]o at constant PCO2 led to rapid, monotonic changes in pHi. The relationship between pHi and pHo was once again steep, with slopes varying between 0.8 and 1.2. However, simultaneous changes in PCO2 and [HCO3-]o at constant pHo did not cause any significant changes in steady-state pHi. In imaging studies, single, isolated TRCs responded to changes in pHo, with parallel changes in pHi in the soma and apical process. In addition, changes in pHo induced parallel changes in pHi throughout TBFs. These data suggest that the steady-state TRC pHi is a function of pHo. Changes in TRC pHi may be involved in acid sensing, and salivary [HCO3-] may play a role in the maintainance of steady-state TRC pHi and in the neutralization of acid-induced changes in pHi.

pH modulates cAMP-induced increase in Na+ transport across frog skin epithelium.

Apical membrane potential (Va), fractional apical membrane resistance (FRa), and/or intracellular pH (pHi) were measured in principal cells of isolated frog (Rana pipiens) skin with microelectrodes under short-circuit conditions. Apical exposure to 0.33 mM 8-(4-chlorophenylthio)adenosine 3',5'-cyclic monophosphate (cAMP) depolarized Va, decreased FRa and increased short-circuit current (Isc). cAMP-induced 50% larger effects on Va and Isc at external pH (pHo) of 8.0 than at pHo 6.4. Increasing pHo from 6.4 to 8.0 in presence of cAMP further depolarized Va and increased Isc. cAMP-induced effects on Va and Isc were observed in the absence of Cl- and HCO3- and in the presence of 1 mM 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) or 10 microM 5-(N-ethyl-N-isopropyl)amiloride (EIPA) or 1 microM 5-(N-methyl-N-isobutyl)amiloride (MIA). These data indicate that Na(+)-H+ exchange, Cl(-)-HCO3- exchange, and electrogenic Na(+)-(HCO3-)n cotransport are not involved in cAMP-induced increase in Isc. Apical exposure to 2 mM Cd2+ or Zn2+ depolarized Va, decreased FRa, increased Isc and increased pHi. In HCO(3-)-free solutions containing DIDS, unilateral replacement of apical Cl- by NO3- induced a fast transient depolarization of Va and an increase in Isc. These data suggest that potential-dependent changes in pHi are involved in increases in Isc. However, when changes in Va were minimized by pretreating the basolateral membrane with 25 or 75 mM K+, the cAMP-induced increase in Isc was not blocked. These data indicate that changes in pHi do not play a strict regulatory role but are only permissive in cAMP-induced effects on Isc.

Regulation of apical Na+ conductive transport in epithelia by pH.

Alterations in extracellular (pHo) and/or intracellular pH (pHi) have significant effects on the apical Na+ conductive transport in tight epithelia. They influence apical membrane Na+ conductance via a direct effect on amiloride-sensitive apical Na+ channel activity and indirectly through effects on the basolateral Na+/K(+)-ATPase. Changes in pH also modulate the hormonal regulation of apical Na+ conductive transport. The pH sensitive steps in hormone action include: (i) hormone-receptor binding, (ii) increase in intracellular cyclic 3',5'-adenosine monophosphate (cAMP), (iii) mobilization of intracellular free Ca2+ ([Ca2+]i), and (iv) incorporation of new channels into the apical membrane or recruitment of existing channels. Alternately, changes in pH induce secondary effects via alterations in [Ca2+]i. A reciprocal relationship between pHi and [Ca2+]i has been demonstrated in renal epithelial cells. Natriferic hormones induce a significant increase in pHi. There is a strong temporal relation between hormone-induced increase in pHi and overall increase in transepithelial Na+ transport. This suggests that changes in pHi act as an intermediate in the second messenger cascade initiated by the hormones. Several natriferic hormones activate Na(+)-H+ exchanger, H(+)-ATPase, H+/K(+)-ATPase, H+ conductive pathways in cell membranes or potential-induced changes in pHi. However, changes in pHi do not seem to be essential for the hormone effect on Na+ conductive transport. It is suggested that the role of pHi changes during hormone action is permissive rather than strictly obligatory.

Na+ transport and pH in principal cells of frog skin: effect of antidiuretic hormone.

Intracellular pH (pHi), apical membrane potential (Va), and fractional apical membrane resistance (FRa) were measured in principal cells of isolated frog skin (Rana pipiens) with double-barreled microelectrodes under short-circuit conditions. Basolateral exposure to 10 mU/ml arginine vasotocin (AVT) depolarized Va by 30 mV, decreased FRa by 33%, increased short-circuit current (Isc) by 17 microA, and increased pHi by 0.17 pH units. The response of Va, Isc, and pHi occurred concurrently. Forskolin, theophylline, and 8-(4-chlorophenyl-thio)-adenosine 3',5'-cyclic monophosphate caused similar changes in Va, Isc, and pHi. The enhanced response of Isc, Va, and FRa to short pulses of apical amiloride applied during AVT or cAMP exposure suggests an increase in apical Na+ conductance. The presence of cAMP agonists also enhanced the response of pHi to amiloride. We conclude that the AVT- and cAMP-induced increase in Na+ transport across the apical cell membrane is associated with a change in pHi. These data are consistent with the hypothesis that changes in pHi may play a role in the second messenger cascade initiated by the antidiuretic hormone.

Potential-induced changes in intracellular pH.

In a variety of cell types and tissues there is a strong dependence of intracellular pH (pHi) on membrane potential (Vm). Since cell Vm values can be altered by hormones, ion concentrations, and changes in membrane conductances, the potential-dependent changes in pHi may serve as an important mechanism by which cells can alter their pHi to an environmental stimulus. The H+ flux across the cell membranes is thought to take place via putative H+ channels that are blocked by low concentrations of divalent metal ions. However, in Na(+)-transporting epithelia, a major part of the H+ flux seems to be via the amiloride-sensitive apical Na+ channels, which are not sensitive to divalent metal ions. The H+ flux via the Na+ channels can be modulated by natriferic hormones and intracellular second messengers. The H(+)-conductive pathways may play an important role in signal transduction in some cells.

Na+ channel blockers inhibit voltage-dependent intracellular pH changes in principal cells of frog (Rana pipiens) skin.

1. The relationship between Va and pHi was studied with double-barrelled microelectrodes in principal cells of frog skin (Rana pipiens) when (i) the transepithelial potential (Vt) was clamped at different values of Vt and (ii) when the pH of the apical solution was altered. 2. Under all conditions examined here, depolarization of Va was associated with an increase in pHi and hyperpolarization of Va was accompanied by a decrease in pHi. However, the changes in the basolateral cell membrane potential occurred, either in the same or opposite direction to that of Va depending on the conditions. 3. The voltage-dependent changes in pHi were not affected by H+ transport inhibitors or the complete removal of Na+, Cl- and HCO3- but were effectively inhibited by the application of amiloride (10(-4) M) or benzamil (10(-6)M) on the apical side. 4. A decrease in pH of the apical solution hyperpolarized Va and decreased pHi, an effect that was significantly attenuated when benzamil was present on the apical side. 5. The results indicate the presence of an H+ and/or OH- conductive pathway in the apical cell membrane of the principal cells. The effect of Na+ channel blockers suggests that this pathway proceeds through the apical Na+ channels.

Effect of changes in extracellular potassium on intracellular pH in principal cells of frog skin.

Intracellular pH (pHi), apical membrane potential (Va), and fractional apical membrane resistance (FRa) were measured in principal cells of isolated frog skin (Rana pipiens) with double-barreled microelectrodes under short-circuit and open-circuit conditions. Basolateral exposure to high K+ concentration or Ba2+ depolarized V(a), decreased short-circuit current, and increased FRa and pHi. However, an increase in K+ subsequent to Ba2+ application did not induce additional changes in these parameters. High basolateral K+, previously shown to increase apical K+ secretion (N. S. Bricker, T. Biber, and H. H. Ussing. J. Clin. Invest. 41: 88-99, 1963), also increased apical Na+ conductance. The depolarization and intracellular alkalinization induced by high K+ were also observed in absence of Na+, Cl-, and HCO3- and in presence of 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid. Under all these conditions pHi moved toward electrochemical equilibrium. Reduced basolateral K+ hyperpolarized V(a) and decreased pHi. The data suggest that depolarization and hyperpolarization of the apical and/or basolateral membrane are associated with an increase and decrease, respectively, in pHi without involvement of Na(+)-H+, Cl(-)-HCO3-, or K(+)-H+ exchange and are apparently also independent of an active H+ secretion pathway. This indicates the presence of a potential-dependent H+ and/or OH- conductance in the apical and/or basolateral cell membrane that may play an important role in pHi regulation and signal transduction.

A possible relationship between KCl symport and basolateral K(+)-conductance in Necturus gallbladder epithelial cells.

1. Apical membrane potential (Va), transepithelial potential (VT), fractional apical voltage ratio (FVa = delta Va/delta VT), tissue resistance (RT), and intracellular Cl- (aiCl) and K+ (aiK) activities were measured in isolated gallbladders maintained between oxygenated bicarbonate-free physiological media (23 degrees C, pH 7.2 or 8.2) in a divided chamber. The basolateral membrane potential (Vb) was calculated from the measured values of Va and VT. 2. Cl- removal from the serosal medium (which should accelerate coupled basolateral KCl exit) significantly depolarized Vb, decreased aiCl, decreased FVa, increased RT, and attenuated the depolarization of Vb (delta Vb) induced by high K+ added to the serosal side. These changes are consistent with a decrease in the K(+)-conductance of the basolateral membrane (gbK). 3. Addition of furosemide (an inhibitor of KCl cotransport) to the serosal medium induced significant increases in Vb, FVa, and high K(+)-induced delta Vb, indicating an increase in gbK. 4. In the presence of serosal furosemide, Cl- removal from the serosal medium did not significantly alter Vb, aiCl or delta Vb from their corresponding values when serosal Cl- was present. 5. Serosal furosemide had no significant effect on aiK and aiCl measured with double-barreled ion-selective microelectrodes. 6. These results suggest the possibility of a reciprocal relationship between gbK and the rate of basolateral KCl cotransport. This may contribute to the maintenance of aiK in gallbladder epithelial cells.

A modified technique for the measurement of sulfhydryl groups oxidized by reactive oxygen intermediates.

This paper suggests a simple modification of the Ellman procedure when used to measure accurate changes in sulfhydryl (-SH) content induced by reactive oxygen intermediates (ROI). This modification became necessary when we found that the standard technique did not produce time invariant results in the presence of ROI-generating systems. Cysteine (cys; 20-100 microM) in 20 mM imidazole buffer (pH 7.0) containing 1.0 mM EDTA was reacted with excess (0.2 mM) 5,5'-dithiobis(2-nitrobenzoic acid), DTNB. The absorbance of the product (p-nitrothiophenol anion) was recorded at 412 nm (A412). This A412 was stable for 60 min and gave a linear relationship with cys concentrations used. ROI were generated either by 0.01 U xanthine oxidase (XO) + 0.01-1.0 mM hypoxanthine (HX), 0.01-1.0 mM H2O2, or H2O2 + 100 microM FeSO4. In the presence of ROI, A412 decreased with time and its rate of decrease was dependent upon the concentration of components of the ROI-generating system. This time-dependent decrease in A412 was prevented completely by the addition of 100 U of catalase (CAT). Therefore, we modified the DTNB method as follows: -SH groups were reacted with ROI for 30 min; this was followed by the addition of 100 U of CAT to scavenge the excess unreacted ROI before the addition of DTNB to generate the product. Using this modification the ROI-induced decrease in A412 was stable with time and was linearly related to the cys concentration. We further tested the modified procedure using metallothionein (MT) as a substrate for the ROI-induced changes in -SH content. MT, at concentrations of 2.5, 5.0, and 7.5 microM, was treated with XO + 100 microM HX.(ABSTRACT TRUNCATED AT 250 WORDS)

Double-barreled K+-selective microelectrodes based on dibenzo-18-crown-6.

Liquid ion-exchanger microelectrodes based on Corning code 477317 K+ exchanger are known to be much more sensitive to quaternary ammonium ions than to K+. In the presence of such cations, the capability of measuring K+ activities with Corning microelectrodes may be seriously impaired. We have developed a neutral carrier K+-selective microelectrode based on the crown ether dibenzo-18-crown-6. The crown ether cocktail contained (wt/wt) 2.3% dibenzo-18-crown-6, 0.8% Na-tetraphenylborate, 30.1% 2-nitrophenylocylether, and 66.8% O-nitrotoluene. Double-barreled crown ether and Corning microelectrodes were calibrated in KCl solutions with or without choline, acetylcholine, tetramethylammonium, imidazole, Na+, tris(hydroxymethyl)aminomethane (Tris), and N-methyl-D-glucamine. Both kinds of microelectrodes showed similar K+ over Na+, Tris, and N-methyl-D-glucamine selectivities. However, crown ether microelectrodes had immensely greater selectivities of K+ over quaternary ammonium ions and imidazole than Corning microelectrodes. Selectivity factors, defined as log K(ij)K, of crown ether microelectrodes with respect to K+ for tetramethylammonium, choline, acetylcholine, and imidazole were -1.92 +/- 0.13, -2.97 +/- 0.03, -1.75 +/- 0.15, and -1.30 +/- 0.20, respectively. Intracellular K+ activities measured in the same Necturus gallbladders with both kinds of microelectrodes did not differ significantly.

Rheogenic transport of basic and acidic amino acids across the brush border of Necturus small intestine.

In studies with isolated Necturus intestine, glutamate (Glu-) and Na+ each enhanced the mucosal influx of the other. Measurement of apical membrane potential, Va, with microelectrodes revealed a rapid depolarization with addition of 10 mM mucosal Glu-. This depolarization was Na+ dependent. Upon complete removal of Cl- from the bathing medium Va hyperpolarized and the Glu- -induced depolarization increased significantly. However, removal of Cl- did not alter the total Glu- influx. These data suggest that external Cl- attenuates the rheogenicity of Na+/Glu- cotransport in the apical membrane of the absorptive cells. We have presented a model consistent with these observations in which Cl- competes with one -COO- group of Glu- for its binding site on the carrier. The two complexes which may form, carrier/Glu-/2Na+ or carrier/Glu-/2Na+/Cl-, allow for either electrogenic or electroneutral transport of Glu-, depending on the ratio [Glu-]/[Cl-] in the extracellular fluid. In other experiments, addition of mucosal L-lysine (Lys+) induced a rapid depolarization of Va. In the presence of Na+, the depolarization appeared to be saturable with respect to Lys+ concentration. In Na+-free media, however, the depolarization increased with Lys+ concentration up to a maximum at 10 mM and then decreased to near zero at 30 mM. These data are consistent with a model for Lys+ entry in which an anionic site of the carrier can bind either Na+ or the epsilon-NH3+ group of Lys+. In this model transport of either complex, carrier-/Lys+ or carrier-/Lys+/Na+ (and return of the carrier to the extracellular surface) is rheogenic. However, at higher Lys+ concentrations, the epsilon-NH3+ group of a second Lys+ molecule may bind to the carrier forming a complex, carrier-/2Lys+, which is not transported.

Measurement of intracellular chloride activity in mouse liver slices with microelectrodes.

Steady-state membrane potential (Vm) and intracellular Cl- activity (aCli) were measured with double-barreled Cl(-)-selective microelectrodes in mouse liver slices. In bathing solutions (33.8 degrees C) containing pyruvate, glutamate, fumarate, and glucose, Vm and aCli were -27.6 +/- 1.0 mV and 32.6 +/- 1.5 mM, respectively. This apparent value of aCli exceeded the level required for passive distribution of this ion (aCleq = 26.4 +/- 1.3 mM) by 6.2 +/- 1.0 mM. This difference was essentially unchanged in experiments where (i) Na+ was replaced by choline, (ii) HCO3- was removed, and (iii) Cl- was replaced by gluconate. These data argue against the presence of Na+- or HCO3(-)-coupled Cl- transport mechanisms in the plasma membrane of mouse liver cells. This implies that aCli is in fact at equilibrium and interference with the response of Cl(-)-selective microelectrodes by intracellular anions is responsible for the apparent difference between aCli and aCleq. We found that Cl(-)-selective microelectrodes containing Corning 477315 ligand are sensitive to taurocholate, a representative bile salt. Their selectivity to taurocholate is about 60-times their selectivity towards Cl-. This suggests that interference of bile acids at concentrations normally present in hepatocytes with determinations of aCli can account for the apparent difference aCli-aCleq.

Effect of chronic cadmium treatment on the ascorbic acid status of the rat.

In rats chronically treated with varying doses of cadmium (Cd) (0.25, 0.50, 0.75 and 1.0 mg/kg body wt.), i.p., every alternate day for 7 weeks, a decrease in the ascorbic acid (AA) content of adrenals and liver was observed. In the adrenals AA depletion was significant and dose-dependent at all concentrations. In liver the decrease was significant only at a concentration of 0.75 and 1.00 mg/kg but the spleen did not show any change in AA content. Urinary excretion of beta2-microglobulin with increasing doses of Cd indicated progressive renal tubular damage. The decrease in tissue AA status was correlated with the severity of the renal tubular damage resulting in an inhibition of its reabsorption from the kidneys.