An immunocytochemical study of H+ ATPase in kidney transplant rejection

Hypokalemic Distal Renal Tubular Acidosis

Distal renal tubular acidosis (DRTA) is defined as hyperchloremic, non-anion gap metabolic acidosis with impaired urinary acid excretion in the presence of a normal or moderately reduced glomerular filtration rate. Failure in urinary acid excretion results from reduced H⁺ secretion by intercalated cells in the distal nephron. This results in decreased excretion of NH₄⁺ and other acids collectively referred as titratable acids while urine pH is typically above 5.5 in the face of systemic acidosis. The clinical phenotype in patients with DRTA is characterized by stunted growth with bone abnormalities in children as well as nephrocalcinosis and nephrolithiasis that develop as the consequence of hypercalciuria, hypocitraturia, and relatively alkaline urine. Hypokalemia is a striking finding that accounts for muscle weakness and requires continued treatment together with alkali-based therapies. This review will focus on the mechanisms responsible for impaired acid excretion and urinary potassium wastage, the clinical features, and diagnostic approaches of hypokalemic DRTA, both inherited and acquired.

Changes in V-ATPase subunits of human urinary exosomes reflect the renal response to acute acid/alkali loading and the defects in distal renal tubular acidosis

In the kidney, final urinary acidification is achieved by V-ATPases expressed in type A intercalated cells. The B1 subunit of the V-ATPase is required for maximal urinary acidification, while the role of the homologous B2 subunit is less clear. Here we examined the effect of acute acid/alkali loading in humans on B1 and B2 subunit abundance in urinary exosomes in normal individuals and of acid loading in patients with distal renal tubular acidosis (dRTA). Specificities of B1 and B2 subunit antibodies were verified by yeast heterologously expressing human B1 and B2 subunits, and murine wild-type and B1-deleted kidney lysates. Acute ammonium chloride loading elicited systemic acidemia, a drop in urinary pH, and increased urinary ammonium excretion. Nadir urinary pH was achieved at four to five hours, and exosomal B1 abundance was significantly increased at two through six hours after ammonium chloride loading. After acute equimolar sodium bicarbonate loading, blood and urinary pH rose rapidly, with a concomitant reduction of exosomal B1 abundance within two hours, which remained lower throughout the test. In contrast, no change in exosomal B2 abundance was found following acid or alkali loading. In patients with inherited or acquired distal RTA, the urinary B1 subunit was extremely low or undetectable and did not respond to acid loading in urine, whereas no change in B2 subunit was found. Thus, both B1 and B2 subunits of the V-ATPase are detectable in human urinary exosomes, and acid and alkali loading or distal RTA cause changes in the B1 but not B2 subunit abundance in urinary exosomes.

The effect of kidney transplantation on distal tubular vacuolar H+-ATPase

BACKGROUND

The presence of vacuolar (v)H+-ATPase in distal tubule alpha-intercalated cells is essential for hydrogen excretion and maintenance of acid-base homeostasis. Loss of vH+-ATPase after kidney transplantation could cause posttransplant distal renal tubular acidosis (dRTA).

METHOD

Immunostaining of the kidney specific vH+-ATPase of cortical collecting duct cells (CCT) was performed in 37 kidney biopsies taken immediately prior to transplantation and after engraftment (median [range]: 10 [1-181] months). Apical or intracytoplasmatic staining intensity was classified as grade 0 (absent), grade 1 (weak), or grade 2 (strong), and positive cells expressed as percentage of all CCT cells. In addition, kidney biopsies were scored for damage by the Banff schema. Serum and urinary pH, anion gap, and serum potassium were obtained for the diagnoses of dRTA.

RESULTS

Fourteen transplant recipients had dRTA type I, 5 had rate-limited RTA, six had type IV dRTA, and 12 had no RTA. In pretransplant biopsies, 40% [3-77%] of CCT cells were positive for vH+-ATPase but only 17% [0-39%] after transplantation (P<0.0001). The loss of vH+-ATPase expression was similar in patients with dRTA type I (-21%), type IV (-25%), rate limited RTA (-21%), or no RTA (-29%). The decrease affected predominantly the apical proton pump expression. The individual loss of vH+-ATPase expression was not related to the time elapsed since transplantation, immunosuppressive drugs, acute transplant rejection, or tubulointerstitial changes.

CONCLUSION

Kidney transplantation leads to a general decrease of distal tubular vH+-ATPase expression. Loss of proton pump activity occurs unrelated to immunosuppressive therapy or transplant related histologic changes.

Distal renal tubular acidosis and the potassium enigma

Severe hypokalemia is a central feature of the classic type of distal renal tubular acidosis (RTA), both in hereditary and acquired forms. In the past decade, many of the genetic defects associated with the hereditary types of distal RTA have been identified and have been the subject of a number of reviews. These genetic advances have expanded our understanding of the molecular mechanisms that lead to distal RTA. In this article, we review data published in the literature on plasma potassium from patients with inherited forms of distal RTA. The degree of hypokalemia varies depending on whether the disease is autosomal autosomal-recessive or dominant, but, interestingly, it occurs in defects caused by mutations in genes encoding the AE-1 exchanger, the carbonic anhydrase II gene, and genes encoding different subunits of the H+ adenosine triphosphatase. This shows that a unique defect involving the H+/K+-adenosine triphosphatase leading to renal potassium wastage cannot explain the hypokalemia seen in virtually all types of classic distal RTA.

Complete renal tubular acidosis late after kidney transplantation

BACKGROUND

Neither the prevalence nor the associated risk factors of late post-transplant renal tubular acidosis (RTA) are known.

METHODS

We conducted a cross-sectional study with 576 patients for more than 12 months after kidney transplantation, and a glomerular filtration rate (GFR) >40 ml/min. RTA was diagnosed by measurement of the urine anionic gap, urine pH and plasma potassium during acidosis, and fractional bicarbonate excretion after bicarbonate loading. Uni- and multi-variable analysis were used to isolate factors associated with post-transplant RTA, and with the different RTA subtypes.

RESULTS

All patients (n = 76) had distal post-transplant RTA. A significant association with the presence of RTA was found for the intake of tacrolimus or renin-angiotensin-aldosterone blockers, the Parathyroid hormone level and the GFR. Type Ia (classic, distal), type Ib (hyperkalaemic, voltage-dependent), rate-limited and type IV RTA were present in 37, 14, 21 and 28% of the patients. Acute transplant rejection was the only significant different parameter between the RTA subtypes and more often present in patients with type Ia or Ib RTA.

CONCLUSIONS

We conclude that a significant fraction of stable long-term renal transplant recipients with adequate graft function develop post-transplant RTA, with a preponderance for type Ia and type IV, and absence of type II. In addition, acute transplant rejection seems to have an influence on the subtype of RTA present post-transplantation.

H+-ATPase activity in selective disruption of H+-K+-ATPase alpha 1 gene of mice under normal and K-depleted conditions

The outer medullary collecting duct (OMCD) plays an important role in acid-base homeostasis by two luminal proton ATPases, H(+)-ATPase and H(+)-K(+)-ATPase (HKA), both of which are in the intercalated cells (ICs) of OMCD. We showed previously that HKAalpha1 (gastric H(+)-K(+)-ATPase) activity is the essential H(+)-K(+)-ATPase activity under normal conditions, and that HKAalpha2 (colonic H(+)-K(+)-ATPase) is induced and mediates increased proton-secretion under K-depleted conditions. To better understand the role of H(+)-ATPase (potassium-independent) in acid secretion and the relationship between H(+)-ATPase and a specific HKA isoform, we examined H(+)-ATPase activity in the H(+)-K(+)-ATPasealpha1 knockout (KO) mice under normal and K-depleted conditions. Mice were fed a potassium-free diet and studied after 7 days. Segments of the OMCD were perfused in vitro, and intracellular pH (pH(i)) was measured by ratiometric fluorescence microscopy using the pH-sensitive indicator BCECF-AM. The isolated OMCD tubules obtained from mice fed a potassium-free diet were examined by fluorescent immunocytochemistry with an antibody to the 31-kDa subunit of H(+)-ATPase (E-11) and were compared with those obtained from a normal diet. In the absence of Na(+) and K(+), the H(+)-ATPase-mediate pH(i) recovery rates were 6.7 +/- 1.1 x 10(-4) units/s (n = 7 ICs) in wild-type (WT) mice and increased to 8.7 +/- 1.8 x 10(-4) (P < 0.05; n = 6) in HKAalpha1 KO mice. K-independent proton transport activity was significantly inhibited by the H(+)-ATPase inhibitor bafilomycin A(1) (BAF, 10 nM) with luminal applied in both WT and KO mice. Comparison of the results indicated upregulation of BAF-sensitive H(+)-ATPase activity in KO mice. To determine the intracellular localization of H(+)-ATPase in the intercalated cells of OMCD, we dissected the OMCD and performed fluorescent immunocytochemistry with the H(+)-ATPase antibody in the WT and KO mice. In the WT mice, on normal diet, H(+)-ATPase staining distributed diffusely throughout the intercalated cells and was slightly polarized to the apical plasma membrane in the KO mice, consistent with increase in the H(+)-ATPase-mediate pH(i) recovery in the KO mice. One week of a potassium-free diet resulted in a significant increase in the degree of H(+)-ATPase polarization at the apical plasma membrane in both WT and KO mice. Hypokalemia stimulates H(+)-ATPase in the intercalated cells of OMCD of both WT and KO mice. The enhanced activity of H(+)-ATPase plays an important role in compensatory proton secretion in the HKAalpha1 KO mice under normal conditions.

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.