Regulation of the Cl-/HCO3- exchanger AE2 in rat thick ascending limb of Henle's loop in response to changes in acid-base and sodium balance

The Cl(-)/HCO(3)(-) exchanger AE2 is believed to be involved in transcellular bicarbonate reabsorption that occurs in the thick ascending limb of Henle's loop (TAL). The purpose of this study was to test whether chronic changes in acid-base status and sodium intake regulate AE2 polypeptide abundance in the TAL of the rat. Rats were subjected to 6 d of loading with NaCl, NH(4)Cl, NaHCO(3), KCl, or KHCO(3). AE2 protein abundance was estimated by semiquantitative immunoblotting in renal membrane fractions isolated from the cortex and the outer medulla of treated and control rats. In the renal cortex, AE2 abundance was markedly increased in response to oral loading with NH(4)Cl or with NaCl. In contrast, AE2 abundance was unchanged in response to loading with KCl or with NaHCO(3) and was decreased by loading with KHCO(3). The response of AE2 in the outer medulla differed from that in the cortex in that HCO(3)(-) loading increased AE2 abundance when administered with Na(+) but had no effect when administered with K(+). Immunohistochemistry revealed that NaCl loading increased AE2 abundance in the basolateral membrane of both the cortical and the medullary TAL. In contrast, NH(4)Cl loading increased AE2 abundance only in the cortical TAL but not in the medullary TAL. These results suggest that regulation of the basolateral Cl(-)/HCO(3)(-) exchanger AE2 plays an important role in the adaptation of bicarbonate absorption in the TAL during chronic acid-base disturbances and high sodium intake. The present study also emphasizes the contribution of cortical TAL adaptation in the renal regulation of acid-base status.     

Autosomal recessive distal renal tubular acidosis associated with Southeast Asian ovalocytosis

BACKGROUND: A defect in the anion exchanger 1 (AE1) of the basolateral membrane of type A intercalated cells in the renal collecting duct may result in a failure to maintain a cell-to-lumen H+ gradient, leading to distal renal tubular acidosis (dRTA). Thus, dRTA may occur in Southeast Asian ovalocytosis (SAO), a common AE1 gene abnormality observed in Southeast Asia and Melanesia. Our study investigated whether or not this renal acidification defect exists in individuals with SAO. METHODS: Short and three-day NH4Cl loading tests were performed in 20 individuals with SAO and in two subjects, including their families, with both SAO and dRTA. Mutations of AE1 gene in individuals with SAO and members of the two families were also studied. RESULTS: Renal acidification in the 20 individuals with SAO and in the parents of the two families was normal. However, the two clinically affected individuals with SAO and dRTA had compound heterozygosity of 27 bp deletion in exon 11 and missense mutation G701D resulting from a CGG-->CAG substitution in exon 17 of the AE1 gene. Red cells of the two subjects with dRTA and SAO and the family members with SAO showed an approximate 40% reduction in sulfate influx with normal 4,4'-di-isothiocyanato-stilbene-2,2'-disulfonic acid sensitivity and pH dependence. CONCLUSION: These findings suggest that compound heterozygosity of abnormal AE1 genes causes autosomal recessive dRTA in SAO.     

Incomplete distal renal tubular acidosis coinherited with a mutation in the band 3 (AE1) gene

Background. Band 3 (anion exchanger 1, AE1) is one of the most abundant proteins of the erythrocyte membrane. We have previously characterized twenty AE1 gene defects underlying spherocytic haemolytic anaemia with band 3 deficiency. Since AE1 is also expressed in the intercalated cells of renal cortical collecting ducts where it is thought to participate in urine acidification, we asked whether the spherocytogenic AE1 mutations also affect the regulation of urine acidity. Methods. We examined 10 patients from seven unrelated families with hereditary spherocytosis with band 3 deficiency using the short urine acidification test with CaCl2 administration at a dose of 0.2 g/g b.w. To assess the ability of the nephron to secrete protons, 400 mol of NaHCO3 were infused over a period of 2 h. Results. While we detected no significant abnormalities in eight patients, we have diagnosed incomplete distal renal tubular acidosis (dRTA) in two patients from one family whose urinary pH 5 h after a CaCl2 administration were 6.65 and 6.89. Administration of bicarbonate in these two patients resulted in high urinary HCO3^- concentration. The patients carry the previously characterized mutation band 3^PRIBRAM that encodes a C-terminally truncated band 3 containing only the cytoplasmic domain and the first three putative transmembrane segments. Conclusions. This finding shows an association of a band 3 defect with abnormal urinary acidification perhaps secondary to Cl^-/HCO3 exchange in the basolateral membrane of &agr;-intercalated cells of cortical collecting ducts.     

Distal renal tubular acidosis and ovalocytosis: a case report

A 23-year-old man presented with osteoporosis, revealed by femoral fractures, and a history of nephrolithiasis, short stature, metabolic acidosis, hypokalemia and ovalocytosis, a red blood cell abnormality common in malaria endemic regions. Biological investigations led to the diagnosis of type 1 distal renal tubular acidosis (dRTA). Ovalocytosis and dRTA may co-exist in the same patient, since both can originate in mutations of the anion-exchanger 1 (AE1) gene, which codes for band 3, the bicarbonate/chloride exchanger, present in both the red cell membrane and the basolateral membrane of the collecting tubule alpha-intercalated cell.     

Permeability defect with bicarbonate leak as a mechanism of immune-related distal renal tubular acidosis

We present a 15-year-old girl with distal renal tubular acidosis (dRTA) appearing in what is probably a very early stage of primary Sj?gren's syndrome. On the basis of tests evaluating renal handling of H+, we attempt to explain the mechanism of the urine acidification disorder. The inability to decrease urinary pH during systemic acidosis, together with the normal increase of urinary carbon dioxide partial pressure (pCO2) values after sodium bicarbonate and neutral phosphate loading, suggest a gradient-type dRTA. The inability to lower urinary pH in response to furosemide, accompanied by markedly increased urinary excretion of NH4, HCO3, Na, and K, points to a collecting tubule permeability disorder with bicarbonate leak to the tubular lumen. This patient had never been exposed to amphotericin B. To our knowledge, immune-related dRTA as a result of a gradient defect with bicarbonate leak into the tubular lumen has not been described.     

Mutation conferring apical-targeting motif on AE1 exchanger causes autosomal dominant distal RTA

Mutations in SLC4A1 that mislocalize its product, the chloride/bicarbonate exchanger AE1, away from its normal position on the basolateral membrane of the α-intercalated cell cause autosomal dominant distal renal tubular acidosis (dRTA). We studied a family exhibiting dominant inheritance and defined a mutation (AE1-M909T) that affects the C terminus of AE1, a region rich in potential targeting motifs that are incompletely characterized. Expression of AE1-M909T in Xenopus oocytes confirmed preservation of its anion exchange function. Wild-type GFP-tagged AE1 localized to the basolateral membrane of polarized MDCK cells, but AE1-M909T localized to both the apical and basolateral membranes. Wild-type AE1 trafficked directly to the basolateral membrane without apical passage, whereas AE1-M909T trafficked to both cell surfaces, implying the gain of an apical-targeting signal. We found that AE1-M909T acquired class 1 PDZ ligand activity that the wild type did not possess. In summary, the AE1-M909T mutation illustrates the role of abnormal targeting in dRTA and provides insight into C-terminal motifs that govern normal trafficking of AE1.     

A de novo R589C mutation of<Emphasis Type="Italic"> anion exchanger 1</Emphasis> causing distal renal tubular acidosis

Anion exchanger 1 (AE1 or SLC4A1) mutations have been reported to cause distal renal tubular acidosis (dRTA), a disease characterized by impaired acid excretion in the distal nephron. We have recently demonstrated homozygous AE1 G701D mutation as a common molecular defect of autosomal recessive (AR) dRTA in a group of Thai pediatric patients. In the present work, we discovered a de novo heterozygous AE1 R589C mutation, previously documented in inherited autosomal dominant (AD) dRTA. Arginine at this position is conserved in all vertebrate AE proteins indicating its functional importance. Three different mutations at this position (R589C, R589H, and R589S) were all found in AD dRTA and a de novo R589H mutation has previously been recorded. Our report is the second de novo mutation but with a different substituted amino acid. A high prevalence of AE1 R589 mutations and the presence of at least two de novo mutations at this position lead us to propose that codon 589 (CGC) is a "mutational hotspot" of AE1. The mechanism of recurrent mutations probably involves methylation and deamination altering cytosine (C) to thymine (T) in the CpG dinucleotides.     

Secretory-defect distal renal tubular acidosis is associated with transporter defect in H(+)-ATPase and anion exchanger-1

Recent progress in molecular physiology has permitted us to understand pathophysiology of various channelopathies at a molecular level. The secretion of H(+) from alpha-intercalated cells is mediated by apical plasma membrane H(+)-ATPase and basolateral plasma membrane anion exchanger-1 (AE1). Studies have demonstrated the lack of H(+)-ATPase immunostaining in the intercalated cells in a few patients with distal renal tubular acidosis (dRTA). Mutations in H(+)-ATPase and AE1 gene have recently been reported to cause dRTA. This study extends the investigation of the role of transporter defect in dRTA by using immunohistochemical methods. Eleven patients with hyperchloremic metabolic acidosis were diagnosed functionally to have secretory-defect dRTA: urine pH >5.5 during acidemia, normokalemia or hypokalemia, and urine-to-blood pCO(2) <25 mmHg during bicarbonaturia. Renal biopsy tissue was obtained from each patient, and immunohistochemistry was carried out using antibodies to H(+)-ATPase and AE1. For comparison, renal tissues from the patients who had no evidences of distal acidification defect by functional studies were used: four with glomerulopathy or tubulointerstitial nephritis (disease controls) and three from nephrectomized kidneys for renal cell carcinoma (normal controls). The H(+)-ATPase immunoreactivity in alpha-intercalated cells was almost absent in all of the 11 patients with secretory-defect dRTA. In addition, 7 of 11 patients with secretory-defect dRTA were accompanied by negative AE1 immunoreactivity. In both disease controls and normal controls, the immunoreactivity of H(+)-ATPase and AE1 was strong in alpha-intercalated cells. In conclusion, significant defect in acid-base transporters is the major cause of secretory-defect dRTA.     

Atypical distal renal tubular acidosis confirmed by mutation analysis

In autosomal dominant distal renal tubular acidosis type I (dRTA) impaired hydrogen ion secretion is associated with metabolic acidosis, hyperchloremic hypokalemia, hypercalciuria, nephrocalcinosis, and/or nephrolithiasis. A retardation of growth is commonly observed. In this report we present a family with autosomal dominant dRTA with an atypical and discordant clinical picture. The father presented with severe nephrocalcinosis, nephrolithiasis, and isosthenuria but metabolic acidosis was absent. His 6-year-old daughter, however, suffered from metabolic acidosis, hypokalemia, and hypercalciuria. In addition, sonography revealed multiple bilateral renal cysts but no nephrocalcinosis. Mutation analysis of the AE1 gene coding for the renal Cl^–/HCO₃ ^–- exchanger AE1 displayed a heterozygous Arg589Cys exchange in both patients but not in the healthy family members. This point mutation is frequently associated with autosomal dominant dRTA. Diagnosis of autosomal dominant dRTA is supported in this family by results of AE1 mutation analysis. Received: 13 April 2000 / Revised: 23 June 2000 / Accepted: 26 June 2000     

Recessive distal renal tubular acidosis in Sarawak caused by AE1 mutations

Mutations of the AE1 (SLC4A1, Anion-Exchanger 1) gene that codes for band 3, the renal and red cell anion exchanger, are responsible for many cases of familial distal renal tubular acidosis (dRTA). In Southeast Asia this disease is usually recessive, caused either by homozygosity of a single AE1 mutation or by compound heterozygosity of two different AE1 mutations. We describe two unrelated boys in Sarawak with dRTA associated with compound heterozygosity of AE1 mutations. Both had Southeast Asian ovalocytosis (SAO), a morphological abnormality of red cells caused by a deletion of band 3 residues 400–408. In addition, one boy had a DNA sequence abnormality of band 3 residue (G701D), which has been reported from elsewhere in Southeast Asia. The other boy had the novel sequence abnormality of band 3 (Q759H) and profound hemolytic anemia.     

Inherited renal tubular acidosis

The past few years have witnessed great progress in elucidating the molecular basis of inherited renal tubular acidosis. Consistent with the physiologically defined importance of multiple gene products in urinary acidification, heritable renal tubular acidosis is genetically heterogeneous. Autosomal dominant distal renal tubular acidosis has been associated with a small number of mutations in the AE1 Cl-/HCO3- exchanger although the pathophysiologic mechanisms behind these mutations remain unclear. Rarely, autosomal recessive distal RTA is caused by homozygosity or compound heterozygosity for the loss-of-function mutation AE1 G701D. A larger proportion, often accompanied by hearing loss, is associated with mutations in the ATP6B1 gene encoding the 58 kDa B1 subunit of the vacuolar H+-ATPase. Mutations in the gene encoding the Na+/HCO3- cotransporter, NBC1, have recently been identified in proximal renal tubular acidosis with corneal calcification.     

Familial pure proximal renal tubular acidosis--a clinical and genetic study.

BACKGROUND: Inherited proximal renal tubular acidosis (pRTA) is commonly associated with more generalized proximal tubular dysfunctions and occasionally with other organ system defects. Inherited combined pRTA and distal RTA with osteopetrosis and pure pRTA associated with ocular abnormalities, a rare disease which has been recently described. Only one family with pure isolated pRTA has been reported so far and the genetic cause for this disease is unknown. Objectives. We report a unique family with isolated pRTA. The aim of the project was to define the phenotype and to try to find the gene defect causing the disease. METHODS: Clinical and metabolic evaluation of all family members was performed and a family pedigree was constructed. DNA was extracted from blood samples of affected and unaffected family members. We amplified by PCR and sequenced the coding areas and splice-sites of the genes that contribute to HCO(-)(3) reclamation in the proximal tubule. The genes studied were as follows: CA II, CA IV, CA XIV, NCB1, Na(+)/H(+) exchanger (NHE)-3, NHE-8, the regulatory proteins of NHE3, NHRF1 and NHRF2 and the Cl(-)/HCO(-)(3) exchanger, SLC26A6. RESULTS: The father and all four children had RTA with blood HCO(-)(3) levels of 11-14 meq/l and urine pH of 5.3-5.4. Increased HCO(-)(3) fractional excretion after bicarbonate loading to 40-60% confirmed the diagnosis pRTA. No other tubular dysfunction was found, and no organ system dysfunction was detected, besides short stature. No mutation was found in all candidate genes studied. CONCLUSIONS: We presented a second family in the literature with familial isolated pure pRTA. The mode of inheritance is compatible with an autosomal dominant disease. Because of the small size of the family, wide genome search was not applicable and the gene candidate approach was chosen. Nine important candidate genes were extensively studied but the molecular basis of the disease was not yet found and genotyping nine important gene candidates were negative.     

Confirmation of the ATP6B1 gene as responsible for distal renal tubular acidosis

Primary distal renal tubular acidosis (dRTA) type I is a hereditary renal tubular disorder, which is characterized by impaired renal acid secretion resulting in metabolic acidosis. Clinical symptoms are nephrocalcinosis, nephrolithiasis, osteomalacia, and growth retardation. Biochemical alterations consist of hyperchloremic metabolic acidosis, hypokalemia with muscle weakness, hypercalciuria, and inappropriately raised urinary pH. Autosomal dominant and rare forms of recessive dRTA are known to be caused by mutations in the gene for the anion exchanger AE1. In order to identify a gene responsible for recessive dRTA, we performed a total genome scan with 303 polymorphic microsatellite markers in six consanguineous families with recessive dRTA from Turkey. In four of these there was an association with sensorineural deafness. The total genome scan yielded regions of homozygosity by descent in all six families on chromosomes 1, 2, and 10 as positional candidate region. In one of these regions the gene ATP6B1for the ss1 subunit of the vacuolar H(+)-ATPase is localized, which has recently been identified as causative for recessive dRTA with sensorineural deafness. Therefore, we conducted mutational analysis in 15 families and identified potential loss-of-function mutations in ATP6B1in 8. We thus confirmed that defects in this gene are responsible for recessive dRTA with sensorineural deafness.     

Pseudohypoaldosteronism type II: proximal renal tubular acidosis and dDAVP-sensitive renal hyperkalemia

The mechanisms of metabolic acidosis and hyperkalemia were investigated in a patient with chronic mineralocorticoid-resistant renal hyperkalemia (5.3-6.9 mmol/l), metabolic acidosis (arterial blood pH 7.27, total CO2 17 mmol/l), arterial hypertension, undetectable plasma renin activity (less than 0.10 ng/ml/h), high plasma aldosterone level (32-100 ng/dl), and normal glomerular filtration rate (131 ml/min/1.73 m2). During the hyperkalemic period, urine was highly acidic (pH 4.6-5.0), urinary NH4 excretion (10-13 microEq/min) and urinary net acid excretion (19-24 microEq/min) were not supernormal as expected from a chronic acid load. During NaHCO3 infusion, the maximal tubular HCO3 reabsorption was markedly diminished (19.8 mmol/l glomerular filtrate), and the fractional excretion of HCO3 (FE HCO3) when plasma HCO3 was normalized was 20%. Urine minus blood PCO2 increased normally during NaHCO3 infusion (31 mm Hg), and the urinary pH remained maximally low (less than 5.3) when the buffer urinary excretion sharply increased after NH4Cl load. When serum K was returned toward normal limits, metabolic acidosis disappeared, urinary NH4 excretion rose normally after short NH4Cl loading while the urinary pH remained maximally low (4.9-5.2), the maximal tubular HCO3 reabsorption returned to normal values (24.8 mmol/l glomerular filtrate), and FE HCO3 at normal plasma HCO3 was 1%. Nasal insufflation of 1-desamino-8-D-Arginine Vasopressin (dDAVP) resulted in an acute normalization of the renal handling of K and in an increase in net urinary acid excretion. We conclude that: the effect of dDAVP on renal handling of K may be explained by the reversal of the distal chloride shunt and/or an increase in luminal membrane conductance to K; the distal acidification seems to be normal which in the event of distal chloride shunt impairing distal hydrogen secretion might be explained by the presence of systemic acidosis which is a potent stimulus of hydrogen secretion, and metabolic acidosis in the steady state was accounted for by the diminution of bicarbonate reabsorption and ammonia production in the proximal tubule secondary to chronic hyperkalemia.     

Pendrin modulates ENaC function by changing luminal HCO3-

The epithelial Na(+) channel, ENaC, and the Cl(-)/HCO(3)(-) exchanger, pendrin, mediate NaCl absorption within the cortical collecting duct and the connecting tubule. Although pendrin and ENaC localize to different cell types, ENaC subunit abundance and activity are lower in aldosterone-treated pendrin-null mice relative to wild-type mice. Because pendrin mediates HCO(3)(-) secretion, we asked if increasing distal delivery of HCO(3)(-) through a pendrin-independent mechanism "rescues" ENaC function in pendrin-null mice. We gave aldosterone and NaHCO(3) to increase pendrin-dependent HCO(3)(-) secretion within the connecting tubule and cortical collecting duct, or gave aldosterone and NaHCO(3) plus acetazolamide to increase luminal HCO(3)(-) concentration, [HCO(3)(-)], independent of pendrin. Following treatment with aldosterone and NaHCO(3), pendrin-null mice had lower urinary pH and [HCO(3)(-)] as well as lower renal ENaC abundance and function than wild-type mice. With the addition of acetazolamide, however, acid-base balance as well as ENaC subunit abundance and function was similar in pendrin-null and wild-type mice. We explored whether [HCO(3)(-)] directly alters ENaC abundance and function in cultured mouse principal cells (mpkCCD). Amiloride-sensitive current and ENaC abundance rose with increased [HCO(3)(-)] on the apical or the basolateral side, independent of the substituting anion. However, ENaC was more sensitive to changes in [HCO(3)(-)] on the basolateral side of the monolayer. Moreover, increasing [HCO(3)(-)] on the apical and basolateral side of Xenopus kidney cells increased both ENaC channel density and channel activity. We conclude that pendrin modulates ENaC abundance and function, at least in part by increasing luminal [HCO(3)(-)] and/or pH.     

Glomerular function and urine acidification in chronic renal diseases

Intravenous sodium bicarbonate (NaHCO3) infusion test was performed in 26 patients with chronic glomerulonephritis (CGN) and 16 with distal renal tubular acidosis (dRTA) in order to evaluate urinary acidifying capacity in chronic renal diseases. Comparative studies with glomerular filtration were planned, so that the patients with CGN were divided by creatinine clearance (Ccr) into 3 groups (G-I greater than or equal to 70, 30 less than or equal to G-II less than 70, G-III less than 30 ml/min). Proximal tubular bicarbonate (HCO3) reabsorption rate increased in CGN as Ccr decreased. Urine to blood carbon dioxide tension gradient (U-B PCO2) was above 30 mmHg in controls and below 20 mmHg in dRTA. In patients with CGN, urine HCO3 concentration (UHCO3) did not increase during NaHCO3 loading as Ccr decreased. However, U-B PCO2 rose above 20 mmHg, when UHCO3 was above 50 ml/min. Fishberg concentrating test was also performed in 15 patients with CGN and 6 with dRTA so that the relationship between urinary concentrating ability and urine acidification might be evaluated. While both functions were decreased in dRTA, U-B PCO2 in alkaline urine remained above 20 mmHg in CGN associated with moderate renal dysfunction (Ccr greater than or equal to 30 ml/min) despite decreased maximal urine osmolality. Intravenous furosemide (FM) injection test was carried out in 8 patients with chronic renal failure (CRF) and 3 with dRTA. Minimal urine pH fell below 5.5 and net acid excretion (NAE) increased in controls, whereas these responses were not seen in dRTA. In CRF, urine pH generally decreased below 5.5 and those who had a similar response to FM as dRTA, seemed to have more severe disturbance of the distal acidification. In conclusion, U-B PCO2 in alkaline urine and lowered urine pH in FM loading appeared to be a useful index of distal tubular acid excretion in patients with renal dysfunction. In CGN with moderate renal dysfunction (Ccr greater than or equal to 30 ml/min), urinary acidifying capacity remained normal in comparison with decreased urine concentrating ability.     

The urine-blood PCO gradient as a diagnostic index of H(+)-ATPase defect distal renal tubular acidosis

BACKGROUND: Urine pH during acidemia and urine PCO2 upon alkalization both may be useful to indicate H+ secretion from collecting ducts. The urine anion gap has been used to detect urinary NH4+ for differential diagnosis of hyperchloremic metabolic acidosis. We have previously demonstrated that the lack of normal H(+)-ATPase may underlie secretory defect distal renal tubular acidosis (dRTA). In this study we evaluated the diagnostic value of the urine-blood (U-B) PCO2 in H(+)-ATPase defect dRTA, and compared it with that of urine pH and urine anion gap during acidemia. METHODS: In H(+)-ATPase defect dRTA, the diagnostic values of three urinary parameters were evaluated: (1) urine pH measured after acid (NH4Cl) loading; (2) urine-to-blood carbon dioxide tension gradient (U-B PCO2) during alkali (NaHCO3) loading; and (3) urine anion gap during acidemia. Seventeen patients were diagnosed as having H(+)-ATPase defect dRTA based on reduced urinary NH4+ and an absolute decrease in H(+)-ATPase immunostaining in intercalated cells on renal biopsy. Eight patients with non-dRTA renal disease served as control patients. RESULTS: Upon NaHCO3 loading, U-B PCO2 was < or =30 mm Hg in all 17 dRTA patients and >30 mm Hg in all 8 control patients. With NH4Cl loading, urine pH was >5.4 in 15 of 17 dRTA patients and < or =5.4 in 7 of 8 control patients, and the urine anion gap was >5 mmol/L in 13 of 17 dRTA patients and< or =5 mmol/L in 6 of 8 control patients. Therefore, the sensitivity and specificity of U-B PCO2 < or =30 mm Hg during NaHCO3 loading were both 100%, whereas those of urine pH >5.4 or urine anion gap >5 mmol/L during NH4Cl loading were below 90%. In control patients, the U-B PCO2 was found to be well correlated with the urinary NH4+ (r= 0.79, P < 0.05). CONCLUSION: The U-B PCO2 during NaHCO3 loading is an excellent diagnostic index of H(+)-ATPase defect dRTA.     

Disequilibrium pH and bicarbonate reabsorption: relevance to the pathogenesis of distal renal tubular acidosis.

An augmented renal capacity to reabsorb bicarbonate (RHCO3) has been noted in patients with distal renal tubular acidosis (dRTA), and construed as evidence that the basic defect in dRTA is abnormal distal tubular permeability. According to this interpretation, the absence of a disequilibrium pH due to a back-leak of H2C03 permits increased distal H+ secretion and results in an increased RHCO3. To test this assumption, we have evaluated the effect of acute elimination of the disequilibrium pH by carbonic anhydrase infusion. The results establish that this maneuver doses not cause a rise in RHCO3. Thus, the elevated value of RHC3 described in dRTA cannot be the consequence of increased back-diffusion of H2CO3 and is more likely due to coexisting extracellular volume depletion and/or postassium deficiency.     

Molecular pathophysiology of SLC4 bicarbonate transporters

PURPOSE OF REVIEW: Acid-base (H and HCO3) transport in the kidney is crucial for maintaining blood pH, cellular pH and excreting metabolic acid. HCO3 transport in the kidney is mediated by HCO3 transporter proteins which occur in two gene families in humans, vertebrates and invertebrates (SLC4 and SLC26). Since SLC26 transporters have other, non-HCO3 transport functions, this review highlights the history and recent advances in the SLC4 transporters in the kidney. The SLC4 gene and protein family (10 genes) contains three types of HCO3 transporters: Cl-HCO3 exchangers, Na/HCO3 cotransporters and Na-driven Cl-HCO3 exchangers. Function and human chromosomal location have been determined for most members. RECENT FINDINGS: Human mutations in AE1 (SLC4A1) and NBCe1 (SLC4A4) are associated with distal and proximal renal tubular acidosis, respectively. Recent advances include the cellular and biophysical mechanisms by which AE1 and NBCe1 mutations lead to renal disease. Mutational and cellular trafficking studies have begun to elucidate the membrane topology and functional domains of AE1 and NBCe1. Knockout mice for AE2 and NBCn1 do not have obvious renal phenotypes. Recently, SLC4A11 (bicarbonate transporter 1) was shown to function as an electrogenic Na/borate cotransporter unable to transport HCO3 but involved in cell cycle control. SUMMARY: SLC4 HCO3 transporters play critical roles in systemic and cellular pH homeostasis. Most of the SLC4 members are present at some level in the kidney. Future studies will likely continue to make use of knockout animals, for example mice and zebrafish, human mutations or polymorphisms to elucidate the normal and pathophysiologic roles of these proteins.