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Active Ca2+ reabsorption in the proximal tubule of the rat kidney (1976)

Ullrich, K. J. ; Rumrich, G. ; Klöss, S.

Springer

Pflügers Archiv 364 (1976), S. 223-228

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ISSN: 1432-2013

Keywords: Renal calcium transport ; Renal calcium permeability ; Sodium dependence ; H+ transport ; Ouabain

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Using the stop flow microperfusion technique with simultaneous capillary perfusion the rate of active Ca2+ reabsorption was evaluated by measuring the static head electrochemical potential difference as well as the permeability of the tubular wall for Ca2+ ions. Under control conditions the active Ca2+ transport was calculated to be 3.35×10−13 mol/cm·s. It declined toward zero if the ambient Na+ was replaced by choline or lithium. Parallel experiments in the golden hamster showed that active Ca2+ transport, vanished completely if active Na+ transport was blocked by ouabain (1 mM). These data indicate that the active Ca2+ reabsorption from the proximal tubule depends on the active reabsorption of Na2+ presumably via a Na+−Ca2+ countertransport at the contraluminal cell membrane. The static head electrochemical potential difference of Ca2+ is the same in late and early proximal tubules. It is also not affected by the presence of acetazolamide (10−4 M) by the absence of bicarbonate or glycodiazine buffer or by the absence or presence of phosphate (2 mM).

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00581759

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Coupling between proximal tubular transport processes (1977)

Ullrich, K. J. ; Capasso, G. ; Rumrich, G. ; [et al.]

Springer

Pflügers Archiv 368 (1977), S. 245-252

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ISSN: 1432-2013

Keywords: Renal tubule ; H+ ion secretion ; Na+ coupled transport ; Ouabain ; SITS

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The rate of active transport by the proximal renal tubule of amino acid (l-histidine), sugar (α-methyl-d-glycoside), H+ ions (glycodiazine), phosphate and para-aminohippurate was evaluated by measuring the zero net flux concentration difference (Δc) of these substances. In the case of calcium the electrochemical potential differenceΔc +zFci Δϕ/RT) was the criterion employed. The rate of isotonic Na+-absorption (JNa) was measured with the shrinking droplet method. The effect of ouabain on the transport of these substances was tested in the golden hamster and the effect of SITS (4-acetamido-4′isothiocyanatostilbene 2,2′-disulfonic acid) was observed in rats. Ouabain (1 mM) applied peritubularly incompletely inhibited JNa (80%), but in combination with acetazolamide (0.2 mM) the inhibition was almost complete (93%). In addition, ouabain inhibited the sodium coupled (secondary active) transport processes ofl-histidine, α-methyl-d-glycoside, calcium and phosphate by more than 75%. It did not affect H+ (glycodiazine) transport and PAH transport was only slightly affected. When SITS (1 mM) was applied from both sides of the cell it inhibited H+ (glycodiazine) transport by 72% and reduced JNa by 38% when given from only the peritubular cell side. SITS (1 mM), however, had no significant affect on H+ secretion and sodium reabsorption if it was applied from only the luminal side. Furthermore it had no affect on the other transport processes tested, regardless of the cell side to which it was applied. When the HCO 3 − buffer or physically related buffers were omitted from the perfusate the absorption of Na+ was reduced by 66%, phosphate by 44%, andl-histidine by 15%. All the other transport processes tested were not significantly affected. The data are consistent with the hypothesis that the active transport processes of histidine, α-methyl-d-glycoside and phosphate, which are located in the brush border, are driven by a sodium gradient which is abolished by ouabain. This may also apply to the Na+-Ca2+ countertransport located at the contraluminal cell side. The residual Na+ transport remaining in the presence of ouabain is likely to be passively driven by the continuing H+ transport which probably is driven directly by ATP. SITS seems to inhibit the exit step of HCO 3 − from the cell and secondary to that, the luminal H+-Na+ exchange and consequently the Na+ reabsorption. In the absence of HCO 3 − buffer in the perfusates the luminal H+-Na+ exchange seems to be affected and the pattern of inhibition of the other transport processes is almost the same as with SITS. The different effects onP i reabsorption observed under these conditions might be explained by possible variations in intracellular pH.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00585203

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Renal proximal tubular buffer-(glycodiazine) transport (1975)

Ullrich, K. J. ; Rumrich, G. ; Baumann, K. ; [et al.]

Springer

Pflügers Archiv 357 (1975), S. 149-163

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ISSN: 1432-2013

Keywords: Renal Tubule ; H+ Transport ; Sodium Dependence ; Carbonic-Anhydrase Inhibitors ; Adaptation (Acid Base Balance)

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Using the stop flow microperfusion technique with simultaneous capillary perfusion the secretory rate of H+ ions in the proximal tubule was evaluated by measuring the level flow reabsorption as well as the static head concentration difference of3H labelled glycodiazine. At ambient glycodiazine concentration of 21 mmol/l the level flow reabsorption is in the same range as that of bicarbonate. In the early proximal loops the reabsorption is 20% greater than in the late proximal loops. The carbonic anhydrase inhibitors acetazolamide and 3,4-methylenedioxyphenyl-sulfonamide (both 10−4 M) as well as furosemide (10−3 M) inhibit the glycodiazine reabsorption 43%, 27% and 22% respectively. Thiocyanate (2 · 10−2 M), however, exerted only an insignificant inhibition (12%). When Na+ in the ambient perfusion solutions was replaced by Li+ or choline+ the glycodiazine transport was strongly reduced. Ouabain (5 · 10−2 M) inhibited too, but amiloride (10−3 M) had no effect on glycodiazine transport. The glycodiazine transport was 28% reduced in metabolic alkalosis and to a smaller although significant extent (17%) in metabolic acidosis; it was unchanged in chronic hypercapnia. In chronic K+ depletion the glycodiazine reabsorption was accelerated by 12% only in the early proximal loops. Chronic parathyroidectomy as well as acute substitution with parathyroid hormone had no effect on the glycodiazine absorption. The main conclusions are: Proximal H+ transport proceeds with suitable buffers. Although independent of HCO3 − and carbonic anhydrase, it could be partially inhibited by CA inhibitors. H+ transport is supposed to proceed as countertransport with Na+ ions. In chronic alkalosis the H+ transport is reduced.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00585971

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Active sulfate reabsorption in the proximal convolution of the rat kidney: Specificity, Na+ and HCO 3 − dependence (1980)

Ullrich, K. J. ; Rumrich, G. ; Klöss, S.

Springer

Pflügers Archiv 383 (1980), S. 159-163

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ISSN: 1432-2013

Keywords: Renal tubule ; Sulfate transport ; Na+ coupled transport ; Thiosulfate ; Molybdate

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Using the standing droplet technique in the proximal convolution and simultaneous microperfusion of the peritubular capillaries, the decrease in luminal sulfate concentration with time and the zero net flux transtubular concentration difference of sulfate ( $$\Delta c_{{\text{SO}}_{\text{4}}^{{\text{2 - }}} } $$ ) at 45 s was determined — the latter being taken as a measure of the rate of active sulfate reabsorption. Starting with 0.5 mmol/l sulfate in both perfusates the $$\Delta c_{{\text{SO}}_{\text{4}}^{{\text{2 - }}} } $$ value of 0.35 mmol/l was approached exponentially with a half value time of 4.3 s. The $$\Delta c_{{\text{SO}}_{\text{4}}^{{\text{2 - }}} } $$ values in the early proximal and late proximal convolution did not deviate from each other. If the Na+ concentration in the perfusates was reduced, the $$\Delta c_{{\text{SO}}_{\text{4}}^{{\text{2 - }}} } $$ approached zero and extrapolated to a slightly negative value (c i〉c o). When 1 mmol/l ouabain was added to the perfusates $$\Delta c_{{\text{SO}}_{\text{4}}^{{\text{2 - }}} } $$ decreased by 66% (the latter experiments were performed in the golden hamster which is more sensitive to ouabain than the rat). 1 mmol/l thiosulfate diminished $$\Delta c_{{\text{SO}}_{\text{4}}^{{\text{2 - }}} } $$ by 68% and 1 mmol/l molybdate by 24%. Omitting or replacing bicarbonate by HEPES or glycodiazine reduced the sulfate reabsorption significantly, while acetazolamide (0.1 mmol/l) and increasing the CO2-pressure from 4.66 to 14.0 kPa (i.e. 5–15% CO2) had no effect. SITS 1 mmol/l had no effect on sulfate reabsorption. The data indicate that the sulfate reabsorption is driven by a Na+ gradient and inhibited by thiosulfate and molybdate, i.e. molecules which have a similar tetrahedral molecule structure. The sulfate reabsorption depends in an undefined manner on the presence of bicarbonate ions.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00581877

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Bidirectional active transport of thiosulfate in the proximal convolution of the rat kidney (1980)

Ullrich, K. J. ; Rumrich, G. ; Klöss, S.

Springer

Pflügers Archiv 387 (1980), S. 127-132

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ISSN: 1432-2013

Keywords: Renal tubule ; Thiosulfate transport ; Na+ coupled transport ; Sulfate transport ; Paraaminohippurate transport

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Using the standing droplet method in the late proximal convolution and simultaneous microperfusion of the peritubular capillaries, the zero net flux transtubular concentration difference of thiosulfate at 45 s was determined, the latter being taken as a measure of active thiosulfate transport. Under control conditions, in the presence of Na+, near zero Δc values were observed. When 1 mmol/l carinamide or paraaminohippurate (PAH) were added to the perfusates significant reabsorptive Δc arose. However, when 7.5 mmol/l sulfate was added to the Na+-free secretory Δc values were observed. Tested under Na+-free conditions, the secretory Δc was not influenced by simultaneously present 5 mmol/l of SO 4 2− but was diminished by 50 mmol/l SO 4 2− . PAH (1 mmol/l), carinamide (0.2 mmol/l) and probenecid (1 mmol/l) decreased the secretory Δc by 48, 65 and 48%, respectively. The PAH secretion was not influenced, when thiosulfate or sulfate up to 50 mmol/l was added to both perfusates. Under Na+-free conditions the Δc of thiosulfate in early loops of the proximal convolution is higher than in late loops, while for PAH this pattern is reversed. Taken together with the previously published inhibition of sulfate reabsorption by thiosulfate the data indicate 1. thiosulfate is reabsorved by the Na+-dependent sulfate transport system and 2. thiosulfate is simultaneously secreted by a carinamide-, probenecid-and PAH-sensitive secretory system. The secretory system might also be shared by sulfate. The thiosulfate net flux is the result of the difference in the activity of the counteracting transporters, located at the luminal and contraluminal cell side. Is is possible that the higher activity of the transporter at one cell side leads to a reversal of the flux through the transporter at the other cell side.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00584263

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Contraluminal sulfate transport in the proximal tubule of the rat kidney (1985)

Ullrich, K. J. ; Rumrich, G. ; Klöss, S.

Springer

Pflügers Archiv 404 (1985), S. 307-310

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ISSN: 1432-2013

Keywords: Epithelial transport ; Contraluminal cell membrane

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract In order to study the specificity of the contraluminal sulfate transport system the inhibitory potency of salicylate analogs (5 mmol/l each) on the35SO 4 2− influx from the interstitium into cortical tubular cells in situ has been determined. The following was found: 2-hydroxybenzoate (salicylate), per se, did not inhibit contraluminal35SO 4 2− influx. The same holds when an additional NH2-group was introduced in position 4 or 5, or when an additional Cl-group was introduced in position 4. When an additional Cl- or NO2-group was introduced in position 5 a moderate inhibition was seen (app.K i≈4 mmol/l). However, introduction of 2 Cl- or 2 NO2-groups in position 3 and 5 creates compounds with strong inhibitory potency (app.K i≈0.5 mmol/l). 2-hydroxy-3,5-iodobenzoate inhibited too, but with a smaller inhibitory potency (app.K i≈2.3 mmol/l). 2-hydroxybenzoate analogs, which have a carboxy- or sulfo-group in position 5, exerted strong inhibition, those with a acetyl- or butyryl-group exerted moderate inhibition. 1-Naphthol-2-carboxylate did not inhibit, while 1-naphthol-4-sulfamoyl-2-carboxylate did. Amongst the dihydroxybenzoates, 2,3- and 2,5-dihydroxybenzoate did not inhibit contraluminal35SO 4 2− influx, while 2,4- and 2,6-dihydroxybenzoate did. The data indicate that a hydroxy-group in ortho-position and an electro-negative group in the meta-position to the carboxyl group and paraposition to the hydroxy-group are essential for interaction with the contraluminal sulfate transport system. The ability of 2,6-dihydroxybenzoate to inhibit might be explained by its ability to undergo mesomeric conformation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00585340

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7

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Contraluminal sulfate transport in the proximal tubule of the rat kidney (1985)

Ullrich, K. J. ; Rumrich, G. ; Klöss, S.

Springer

Pflügers Archiv 404 (1985), S. 300-306

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ISSN: 1432-2013

Keywords: Epithelial transport ; Contraluminal cell membrane

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract In order to study the specificity for the contraluminal sulfate transport system the inhibitory potency of disulfonates, di-, tricarboxylates and sulfocarboxylates on the35SO 4 2− influx from the interstitium into cortical tubular cells in situ has been determined. The following was found: 1) Methane- and ethane-disulfonate as well as benzene-1,3-disulfonate inhibit contraluminal35SO 4 2− influx (with an (app.K i of 〈6 mmol/l), while benzene-1,2- and 1,4-disulfonate do not. 2) The inhibitory potency of 1,3-benzene disulfonate is slightly augmented by an additional NH2 − or OH-group in position 4. However, OH-groups at position 4 and 5 or 4 and 6 abolish the inhibitory potency. 3) The naphthalene disulfonates tested inhibit only if they have an OH-group in ortho-position to one SO3H group. 4) The stilbene disulfonates H2DIDS and DNDS inhibit the contraluminal35SO 4 2− influx with high (app.K i≈0.8 mmol/l), DADS with lower potency (app.K i≈6 mmol/l). 5) Amongst the tested aliphatic di- and tricarboxylates inhibition was exerted by oxalate (app.K i 1.1 mmol/l) and maleate (app.K i 3.8 mmol/l), but not by malonate, hydroxymalonate and citrate. 6) Out of the tested benzenedicarboxylates only those inhibit which have the COO−-groups directly on the ring in 1,2 and 1,3 position (app.K i 4.0 and 2.7 mmol/l), but not in the 1,4 position. An additional OH-group in position 4 augments the inhibitory potency of 1,3 benzene-dicarboxylates (app.K i 0.8 mmol/l), while an OH group on position 5 abolishes it. 7) The benzene tricarboxylates (BTC) inhibit in the sequence 1,2,3-BTC〉1,3,5-BTC〉1,2,4-BTC (app.K i 0.9, 1.5 and 4.2 mmol/l, respectively). 8) The carboxy-benzene-sulfonates inhibit also in the 1,2 and 1,3 position only (app.K i 6.7 and 5 mmol/l), but not in the 1,4 position. Addition of an −OH-group to the 3-carboxy-1-benzene-sulfonate forming 4-hydroxy-3-carboxy-1-benzene-sulfate augments the inhibitory potency drastically (app.K i 0.32 mmol/l), while a NH2 substitution at the same position leaves it unchanged (app.K i 4.7 mmol/l). If, however, ethylamine instead of NH2 is used as substituent, the inhibitory potency is almost as high as of 4-hydroxy-3-carboxy-1-benzene-sulfonate (app.K i≈0.6 mmol/l). Amongst the dicarboxy-benzene-sulfonates, 3,4-carboxy-benzene-1-sulfonate inhibits (app.K i ca. 2 mmol/l), while 3,5-carboxy-benzene-1-sulfonate does not. The data indicate that a strong interaction of substrate with the sulfate transporter is given, when two charged groups (COO− and/or SO 3 − ) are present in a distance equivalent to the meta-position on the benzene ring and an additional hydrogen bond forming OH- or −NH-group. Hydrogen bond forming groups and charged groups in other positions usually abolish the inhibitory potency.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00585339

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Contraluminal sulfate transport in the proximal tubule of the rat kidney (1985)

Ullrich, K. J. ; Rumrich, G. ; Klöss, S. ; [et al.]

Springer

Pflügers Archiv 404 (1985), S. 311-318

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ISSN: 1432-2013

Keywords: Epithelial transport ; Contraluminal cell membrane

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract In order to evaluate the specificity for the contraluminal sulfate transport system the inhibitory potency of phenol- and sulfonphthaleins, of sulfamoyl-compounds (diuretics) as well as diphenylamine-2-carboxylates (Cl− channel blockers) on the35SO 4 2− influx from the interstitium into cortical tubular cells in situ has been determined. The following was found: 1) Phenolsulfonphthalein (phenol-red) inhibited with an app.K i-value of 1.7 mmol/l, while analogs which had additional Br-atoms in position 3 and/or 5, i.e. bromphenol-blue, bromcresol-purple and bromcresol-green, inhibited with an apparentK i of 0.1 and 0.5 mmol/l respectively. 2) Phenolphthalein and tetrabromphenolphthalein did not inhibit, while the disulfonate dyes bromsulfalein, fuchsin acid and indigocarmine inhibited with aK i between ≈1 and 3 mmol/l. The highest inhibitory potency in this class of compounds was seen with orange G (app.K i 0.07 mmol/l). The monosulfonate dyes tested, fluoresceinsulfonate and orange I inhibited moderately with an app.K i of ≈5 mmol/l. 3) The 3-sulfamoyl compounds inhibited to a varying degree, when they had a neighbouring −NH-group (furylmethylamino-group), i.e. in position 6 to the COOH or SO3H-group, or when they had a phenoxy-group in position 4. 4) 4-sulfamoylbenzoate and the related compounds probenecid, acetazolamide and hydrochlorothiazide inhibited with an app.K i between 4 and 7 mmol/l. 5) All diphenylamine-2-carboxylate analogs inhibited with an app.K i between 3 and 5 mmol/l, even when the −NH-group was replaced by an =O-group or the benzene ring was replaced by a pyrimidine ring, but not when it was replaced by a thiophen ring. In contrast, 4-phenylaminepyridine-3-sulfonate was ineffective, while diphenylamine-2-amino sulfonate exerted the highest inhibition of this group with an app.K i of 1.4 mmol/l. When, however, the aminosulfonate group was replaced by a methylsulfonamide, the inhibitory potency disappeared. The data can be explained by inhibitory patterns found in previous papers for disulfonates [29], sulfonates with a hydrophobic moiety [28] or neighbouring OH-group [28, 29], carboxylates with a neighbouring −NH- or OH-group in position 2- and an electron-attracting group in position 5 [30].

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URL: http://dx.doi.org/10.1007/BF00585341

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Contraluminal para-aminohippurate (PAH) transport in the proximal tubule of the rat kidney (1987)

Ullrich, K. J. ; Rumrich, G. ; Fritzsch, G. ; [et al.]

Springer

Pflügers Archiv 408 (1987), S. 38-45

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ISSN: 1432-2013

Keywords: Oxalate ; Succinate ; Glutarate ; 2-Oxoglutarate ; Citrate ; Sulfate

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract In order to study the specificity for contraluminal para-aminohippurate (PAH) transport, the inhibitory potency of aliphatic dicarboxylates on3H-PAH influx, as well as the inhibitory effect on35SO 4 2− - and3H-succinate influx, from the interstitium into cortical tubular cells in situ has been determined. The following was found: 1. Testing a homologous series of dicarboxylates-ranging from the 2 C oxalate to the 10 C sebacate — PAH transport was inhibited by succinate (app.K i 1.35 mmol/l), and all longer dicarboxylates, with high potency (app.K i 0.05–0.35 mmol/l). Sulfate transport was inhibited only by oxalate (app.K i 1.1 mmol/l), while dicarboxylate transport was inhibited by succinate, glutarate, adipate and pimelate with decreasing potency (app.K i 0.04, 0.24, 0.91, 4.0 mmol/l, respectively). 2. PAH transport was inhibited by succinate and glutarate with high potency (app.K i 1.35 and 0.05 mmol/l), by the correspondent monomethylester to a lesser extent (app.K i 1.7 and 0.74 mmol/l), but not by the dimethylester. On the other hand, the semialdehyde of succinate with aK i-value of 1.2 mmol/l, had the same inhibitory potency as succinate itself, while the dialdehyde of glutarate (app.K i 1.4 mmol/l) was much less potent as glutarate. 3. Introduction of an oxo-, methyl- or sulfhydroxylgroup onto the 2-position of succinate, or of an oxo-group onto the 2-position of glutarate moderately augmented the inhibitory potency against PAH-uptake. However, introduction of a 2-hydroxy group onto succinate or glutarate in thel-position reduced the inhibitory potency more than in thed-position. Introduction of two methyl-, sulfhydryl- or hydroxyl-groups in the 2–3-position of succinate reduced or abolished its inhibitory potency. The introduction of a 2-amino group onto succinate or glutarate abolished its effect on PAH transport. However, N-acetylation or N-benzoylation led to a restitution in inhibitory potency. 4. The trans-isomers fumarate and mesaconate inhibited PAH- and methylsuccinate transport, while the cis-isomers maleate and citraconate did so to a lesser extent or not at all. The effect was reversed with the tricarboxylic aconitates, because cis-aconitate bears a CH2-extended COOH-group in trans-position and trans-aconitate in cis-position. The data indicate that there exist three different anion transport systems at the contraluminal cell side of the proximal renal tubule: 1. a sulfate-oxalate transporter, 2. a sodium-dependent dicarboxylate transporter, and 3. a paraaminohippurate transporter. The PAH transport system accepts dicarboxylates with chain length higher than 7.5 Å (=distance between the terminal oxygen atoms), while the dicarboxylate transport interacts with dicarboxylates with a chain length between 6.5 and 10 Å. Both transport systems prefer the transconfiguration. The effect of side groups on the interaction of dicarboxylates with the PAH-transport system is due mainly to hydrophobicity and electron configuration.

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URL: http://dx.doi.org/10.1007/BF00581838

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Phosphate transport in the proximal convolution of the rat kidney (1978)

Ullrich, K. J. ; Rumrich, G. ; Klöss, S.

Springer

Pflügers Archiv 377 (1978), S. 33-42

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ISSN: 1432-2013

Keywords: Renal tubule ; Phosphate transport ; Extracellular pH ; Intracellular pH ; Acetazolamide

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Inorganic phosphate (Pi) transport was evaluated using the standing droplet method with simultaneous microperfusion of the peritubular capillaries. To evaluate rather small differences in Pi transport and to eliminate the influence of tubular heterogeneity, the technique of crossed paired samples was applied. 1. In chronic PTX rat changing the luminal or both luminal and peritubular pH by varying the HCO 3 − -concentration between 4 and 50 mmol/l at constant 5% CO2 had no influence on Pi transport. 2. If, however, bicarbonate was omitted from the perfusate and 2 mmol/l phosphate (pH 7.4) was the only buffer, Pi transport was decreased from the control. It was, however, further reduced when the perfusates were gased with 5% CO2 i. e. the starting pH was 5.6. 3. When the solutions contained HEPES buffer (25 mmol/l), Pi transport at pH 8 was much larger than at pH 6.0. 4. Raising the CO2 pressure from 35 to 70 mm Hg did not change the Pi transport when both perfusates had a HCO 3 − -concentration of 25 mmol/l. It reduced, however, the Pi transport, when the luminal perfusate had only 4 mmol/l bicarbonate. 5. Lowering the CO2 pressure from 38 to 7.6 mm Hg did hardly change the Pi transport when the luminal perfusate contained 4 mmol/l bicarbonate. It lowered, however, the Pi transport significantly when the luminal perfusate had 25 mmol/l bicarbonate. 6. Acetazolamide, 10−4 M, lowered the Pi transport when the luminal perfusate contained 4 or 25 mmol/l bicarbonate. At 4 mmol/l luminal HCO 3 − , raising thepCO2 to 228 mmol/l depressed Pi transport even more. At 25 mmol/l luminal bicarbonate, raising thepCO2 from 38 to 114 mm Hg reversed the acetazolamide inhibition of the Pi transport almost completely. The data indicate that luminal acidosis and intracellular alkalosis inhibits the transtubular Pi transport. A shift of the intracellular pH to a more alkaline value seems to be responsible for the inhibition of Pi transport by acetazolamide, while omission of buffer from the perfusate inhibits Pi transport by effecting an acidic luminal pH.

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URL: http://dx.doi.org/10.1007/BF00584371

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