The present experiments have employed microelectrode techniques (pH and PCO2) and microcalorimetry (total CO2 concentration) to define parameters of acidification in specific structures of the rat testis and epididymis during control conditions and after administration of the carbonic anhydrase inhibitor acetazolamide (20 or 50 mg/kg). Values for in situ pH during control conditions in seminiferous tubules (ST; 6.96 +/- 0.01), proximal caput (PCP; 6.62 +/- 0.01), middle caput (MCP; 6.59 +/- 0.01), middle corpus (MCR; 7.10 +/- 0.02), and proximal cauda epididymidis (PCD; 6.85 +/- 0.01) were significantly more acidic than in testicular artery (TA; 7.36 +/- 0.01) or systemic arterial blood (SAB; 7.40 +/- 0.01) and did not change significantly after acetazolamide. In situ partial pressure of CO2 (PCO2) in TA (52.2 +/- 0.6 mmHg), ST (52.3 +/- 0.4 mmHg), PCP (52.9 +/- 0.4 mmHg), MCP (53.0 +/- 0.7 mmHg), MCR (53.4 +/- 0.4 mmHg), and PCD (52.4 +/- 0.4 mmHg) were indistinguishable from each other, but all values were significantly higher than SAB PCO2 (39.2 +/- 0.5 mmHg). Acetazolamide increased in situ PCO2 significantly in all structures except the MCR. The total CO2 concentration in normal ST fluid (10.7 +/- 0.5 mM) was significantly higher than in "primary" fluid (6.9 +/- 0.3 mM), and both values were well below TA (26.9 +/- 1.3 mM) or SAB (24.6 +/- 0.4 mM) total CO2 concentrations. In the epididymis, total CO2 concentrations were indistinguishable and not different from the value in primary fluid.(ABSTRACT TRUNCATED AT 250 WORDS)
These results demonstrate that HMC bind mIgA1 and AIgA1 with similar affinity. However, activation of HMC requires an aggregated form of IgA1. These processes are independent of FcalphaR1, suggesting the presence of a new IgA receptor on mesangial cells.
Recent classifications of the several pathophysiologic types of distal renal tubular acidosis (secretory, voltage dependent, and gradient) have been based on the response of acidification parameters to a series of provocative maneuvers in vivo and in vitro. A reduction in the difference in urine and blood CO2 tension during bicarbonate loading (U-B pCO2 gradient), a widely applied parameter, has been employed as an index of reduced distal nephron proton secretion. This study was designed to test the validity of the U-B pCO2 gradient in a variety of experimental models of distal renal tubular acidosis by measuring and comparing disequilibrium pH (a direct technique to detect H' secretion in situ) with the pCO2 in the papillary collecting duct of the rat in vivo during bicarbonate loading. Chronic amiloride, lithium chloride, and amphotericin-B administration, and the post-obstructed kidney models were employed. Amiloride resulted in an acidification defect which did not respond to sulfate infusion (urine pH = 6.15±0.08), and was associated with an obliteration of the acid disequilibrium pH (-0.26±0.05--0.08±0.03) and reduction in papillary pCO2 (116.9±3.2-66.9±2.5 mmHg). The defect induced by lithium administration responded to Na2SO4 (urine pH = 5.21±0.06) but was similar to amiloride with respect to the observed reduction in disequilibrium pH (-0.04±0.02) and pCO2 (90.3±3.0 mmHg). The post-obstructed kidney model was characterized by an abnormally alkaline urine pH unresponsive to sulfate (6.59±0.06) and a reduction in disequilibrium pH (+0.02±0.06) and pCO2 (77.6±3.6 mmHg). Amphotericin
Transport of NH3 from loops of Henle to medullary collecting ducts has been proposed to play an important role in renal ammonia excretion. To determine whether transepithelial ammonia concentration gradients capable of driving this transport are present in the inner medulla, micropuncture experiments were performed in control rats and in rats with chronic metabolic acidosis. In situ pH and total ammonia concentrations were measured to calculate NH3 concentrations ([NH3]) for base and tip collecting duct, loop of Henle, and vasa recta. In control and acidotic rats, [NH3] in the loop of Henle was significantly greater than [NH3] in the collecting ducts. [NH3] did not differ in loop of Henle and adjacent vasa recta in either group of rats, indicating that NH3 concentration gradients between loop and collecting duct represent NH3 gradients that are present between medullary interstitium and collecting duct. During acidosis, an increase in collecting duct ammonia secretion was associated with an increase in the NH3 concentration difference between loop of Henle and collecting duct but occurred in the absence of a fall in collecting duct pH. The NH3 concentration gradient favoring diffusion of NH3 into the collecting ducts increased during acidosis because [NH3] in the loop of Henle and medullary interstitium increased more than [NH3] in the collecting duct. These findings indicate that transport processes involved in medullary ammonia accumulation play an important role in regulating ammonia secretion into the inner medullary collecting duct in vivo and that a fall in inner medullary collecting duct pH is not necessarily required for ammonia secretion by this segment to increase during chronic metabolic acidosis.
A new technique for manufacturing single-barreled and double-barreled antimony pH microelectrodes is described. The results of investigations into the accuracy of antimony as a pH sensor disclosed that the pH-voltage response is: 1) within the physiologic range, principally the result of the hydrogen ion activity of the solution in which the voltage is being developed, 2) in part, qualitatively anion-dependent, 3) modified by the presence of significant amounts of at least carbon dioxide, oxygen, and nitrogen gases, and 4) markedly offset by fluctuations in temperature. Our results further indicate that the accuracy of antimony as a pH sensor is determined by the quality of the calibration procedure. We conclude that if the antimony electrode is to accurately determine the pH of a biological fluid, the pH calibration solutions must closely resemble the unknown biological fluid with respect to temperature, PO2, PN2, and types of buffering anions. A calibration procedure is described which can minimize errors with antimony pH estimations when measuring the pH of proximal tubular fluid of the mammalian kidney.
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