Nazih L. Nakhoul

Effect of expressing the water channel aquaporin-1 on the CO2 permeability of Xenopus oocytes

It is generally accepted that gases such as CO2 cross cell membranes by dissolving in the membrane lipid. No role for channels or pores in gas transport has ever been demonstrated. Here we ask whether expression of the water channel aquaporin-1 (AQP1) enhances the CO2 permeability of Xenopus oocytes. We expressed AQP1 in Xenopus oocytes by injecting AQP1 cRNA, and we assessed CO2permeability by using microelectrodes to monitor the changes in intracellular pH (pHi) produced by adding 1.5% CO2/10 mM[Formula: see text] to (or removing it from) the extracellular solution. Oocytes normally have an undetectably low level of carbonic anhydrase (CA), which eliminates the CO2 hydration reaction as a rate-limiting step. We found that expressing AQP1 (vs. injecting water) had no measurable effect on the rate of CO2-induced pHi changes in such low-CA oocytes: adding CO2 caused pHi to fall at a mean initial rate of 11.3 × 10-4 pH units/s in control oocytes and 13.3 × 10-4 pH units/s in oocytes expressing AQP1. When we injected oocytes with water, and a few days later with CA, the CO2-induced pHi changes in these water/CA oocytes were more than fourfold faster than in water-injected oocytes (acidification rate, 53 × 10-4 pH units/s). Ethoxzolamide (ETX; 10 μM), a membrane-permeant CA inhibitor, greatly slowed the pHi changes (16.5 × 10-4 pH units/s). When we injected oocytes with AQP1 cRNA and then CA, the CO2-induced pHi changes in these AQP1/CA oocytes were ∼40% faster than in the water/CA oocytes (75 × 10-4 pH units/s), and ETX reduced the rates substantially (14.7 × 10-4 pH units/s). Thus, in the presence of CA, AQP1 expression significantly increases the CO2 permeability of oocyte membranes. Possible explanations include 1) AQP1 expression alters the lipid composition of the cell membrane, 2) AQP1 expression causes overexpression of a native gas channel, and/or 3) AQP1 acts as a channel through which CO2 can permeate. Even if AQP1 should mediate a CO2 flux, it would remain to be determined whether this CO2movement is quantitatively important.

Regulation of sodium transport in M-1 cells

The M-1 cell line, derived from the mouse cortical collecting duct (CCD), is being used as a mammalian model of the CCD to study Na+ transport. The present studies aimed to further define the role of various hormones in affecting Na+ transport in M-1 cells grown in defined media. M-1 cells on permeable support, in serum-free media, developed amiloride-sensitive current 4-5 days after seeding. As expected for the involvement of epithelial Na+ channels, alpha-, beta-, and gamma-subunits of the epithelial Na+ channel were identified by RT-PCR. Either dexamethasone (Dex, 10-100 nM) or aldosterone (Aldo, 10(-6)-10(-7) M) for 24 h stimulated transport. Cells grown in the presence of Aldo and Dex had higher transport than with Dex alone. Spironolactone added to Dex media decreased transport. The acute effects of hormones reported to inhibit Na+ transport in CCD were also examined. Epidermal growth factor, phorbol esters, and increased intracellular Ca2+ with thapsigargin did not alter transport. Arginine vasopressin caused a transient increase in transport (probably Cl- secretion), which was not amiloride sensitive. Also, the protease inhibitor aprotinin decreased Na+ transport; in aprotinin-treated cells, trypsin stimulated transport. This study demonstrates that adrenal steroids (Dex > Aldo) stimulate Na+ transport in M-1 cells. At least part of this response may represent activation of mineralocorticoid receptors based on an additive effect of Dex and Aldo, as well as inhibition by spironolactone. Responses to immediate-acting hormones is limited. However, an endogenous protease activity, which activates Na+ transport, is present in these cells.The M-1 cell line, derived from the mouse cortical collecting duct (CCD), is being used as a mammalian model of the CCD to study Na+ transport. The present studies aimed to further define the role of various hormones in affecting Na+ transport in M-1 cells grown in defined media. M-1 cells on permeable support, in serum-free media, developed amiloride-sensitive current 4-5 days after seeding. As expected for the involvement of epithelial Na+ channels, α-, β-, and γ-subunits of the epithelial Na+ channel were identified by RT-PCR. Either dexamethasone (Dex, 10-100 nM) or aldosterone (Aldo, 10-6-10-7M) for 24 h stimulated transport. Cells grown in the presence of Aldo and Dex had higher transport than with Dex alone. Spironolactone added to Dex media decreased transport. The acute effects of hormones reported to inhibit Na+ transport in CCD were also examined. Epidermal growth factor, phorbol esters, and increased intracellular Ca2+ with thapsigargin did not alter transport. Arginine vasopressin caused a transient increase in transport (probably Cl- secretion), which was not amiloride sensitive. Also, the protease inhibitor aprotinin decreased Na+ transport; in aprotinin-treated cells, trypsin stimulated transport. This study demonstrates that adrenal steroids (Dex > Aldo) stimulate Na+ transport in M-1 cells. At least part of this response may represent activation of mineralocorticoid receptors based on an additive effect of Dex and Aldo, as well as inhibition by spironolactone. Responses to immediate-acting hormones is limited. However, an endogenous protease activity, which activates Na+ transport, is present in these cells.

Alterations in junctional proteins, inflammatory mediators and extracellular matrix molecules in eosinophilic esophagitis

Eosinophilic esophagitis (EoE), an inflammatory atopic disease of the esophagus, causes massive eosinophil infiltration, basal cell hyperplasia, and sub-epithelial fibrosis. To elucidate cellular and molecular factors involved in esophageal tissue damage and remodeling, we examined pinch biopsies from EoE and normal pediatric patients. An inflammation gene array confirmed that eotaxin-3, its receptor CCR3 and interleukins IL-13 and IL-5 were upregulated. An extracellular matrix (ECM) gene array revealed upregulation of CD44 & CD54, and of ECM proteases (ADAMTS1 & MMP14). A cytokine antibody array showed a marked decrease in IL-1α and IL-1 receptor antagonist and an increase in eotaxin-2 and epidermal growth factor. Western analysis indicated reduced expression of intercellular junction proteins, E-cadherin and claudin-1 and increased expression of occludin and vimentin. We have identified a number of novel genes and proteins whose expression is altered in EoE. These findings provide new insights into the molecular mechanisms of the disease.

Role of proximal tubules in the pathogenesis of kidney disease.

The proximal tubules make up a significant portion of the kidneys; proximal tubule epithelial cells are the most populous cell type in the kidney, and carry out diverse regulatory and endocrine functions where numerous transporters are located. Under normal circumstances, more than two thirds of filtered salt and water, and all filtered bicarbonate is reabsorbed in the proximal tubule. A number of inherited and acquired acid-base and tubule disorders are linked to impaired transporters in the proximal tubule cells. Equally important is the intrinsic immune characteristics of proximal tubule cells that give them the ability to also function as immune responders to a wide range of immunologic, ischemic or toxic injury. It is therefore not surprising that proximal tubule-related phenomena are closely related to the pathogenesis of a vast array of kidney diseases. Many kidney diseases, acute and chronic, first manifest with proximal tubule disorders. Recent insight into molecular characteristics of transport functions in the proximal tubules, and the recognition that proximal tubule cells possess intrinsic immune responses have contributed to an improved understanding of important areas in nephrology, such as Fanconis syndrome, renal tubular acidosis, phosphate wasting syndromes, Dents disease, cystinuria and other amino acid transport disorders, acute kidney injury, and the role of proximal tubules in progressive kidney disease. Megalin/ cubilin-mediated endocytosis by proximal tubule cells of increased quantities of filtered proteins (protein overloading) in glomerular diseases appears to evoke cell stress responses resulting in increased inflammatory cytokines leading to tubulointerstitial inflammation and fibrosis. Finally, the proximal tubule may be the site of both active vitamin D synthesis through the action of 1-α-hydroxylase, and the site where erythropoietin synthesis takes place. Thus, proximal tubule injury also contributes to two distressing consequences of chronic kidney disease: mineral-bone disorder and anemia.

Acid-Base Homeostasis

Acid-base homeostasis and pH regulation are critical for both normal physiology and cell metabolism and function. The importance of this regulation is evidenced by a variety of physiologic derangements that occur when plasma pH is either high or low. The kidneys have the predominant role in regulating the systemic bicarbonate concentration and hence, the metabolic component of acid-base balance. This function of the kidneys has two components: reabsorption of virtually all of the filtered HCO3(-) and production of new bicarbonate to replace that consumed by normal or pathologic acids. This production or generation of new HCO3(-) is done by net acid excretion. Under normal conditions, approximately one-third to one-half of net acid excretion by the kidneys is in the form of titratable acid. The other one-half to two-thirds is the excretion of ammonium. The capacity to excrete ammonium under conditions of acid loads is quantitatively much greater than the capacity to increase titratable acid. Multiple, often redundant pathways and processes exist to regulate these renal functions. Derangements in acid-base homeostasis, however, are common in clinical medicine and can often be related to the systems involved in acid-base transport in the kidneys.

Acid-base and potassium homeostasis.

Acid-base balance and potassium disorders are often clinically linked. Importantly, acid-base disorders alter potassium transport. In general, acidosis causes decreased K(+) secretion and increased reabsorption in the collecting duct. Alkalosis has the opposite effects, often leading to hypokalemia. Potassium disorders also influence acid-base homeostasis. Potassium depletion causes increased H(+) secretion, ammoniagenesis and H-K-ATPase activity. Hyperkalemia decreases ammoniagenesis and NH4(+) transport in the thick ascending limb. Some combined potassium and acid-base disorders involve indirect factors such as aldosterone, impaired renal function, volume depletion, and diarrhea. In summary, disorders of potassium and acid-base homeostasis are mechanistically linked and clinically important.

Substrate specificity of Rhbg: ammonium and methyl ammonium transport

Rhbg is a nonerythroid membrane glycoprotein belonging to the Rh antigen family. In the kidney, Rhbg is expressed at the basolateral membrane of intercalated cells of the distal nephron and is involved in NH4+ transport. We investigated the substrate specificity of Rhbg by comparing transport of NH3/NH4+ with that of methyl amine (hydrochloride) (MA/MA+), often used to replace NH3/NH4+, in oocytes expressing Rhbg. Methyl amine (HCl) in solution exists as neutral methyl amine (MA) in equilibrium with the protonated methyl ammonium (MA+). To assess transport, we used ion-selective microelectrodes and voltage-clamp experiments to measure NH3/NH4+- and MA/MA+-induced intracellular pH (pH(i)) changes and whole cell currents. Our data showed that in Rhbg oocytes, NH3/NH4+ caused an inward current and decrease in pH(i) consistent with electrogenic NH4+ transport. These changes were significantly larger than in H2O-injected oocytes. The NH3/NH4+-induced current was not inhibited in the presence of barium or in the absence of Na+. In Rhbg oocytes, MA/MA+ caused an inward current but an increase (rather than a decrease) in pH(i). MA/MA+ did not cause any changes in H2O-injected oocytes. The MA/MA+-induced current and pH(i) increase were saturated at higher concentrations of MA/MA+. Amiloride inhibited MA/MA+-induced current and the increase in pH(i) in oocytes expressing Rhbg but had no effect on control oocytes. These results indicate that MA/MA+ is transported by Rhbg but differently than NH3/NH4+. The protonated MA+ is likely a direct substrate whose transport resembles that of NH4+. Transport of electroneutral MA is also enhanced by expression of Rhbg.

Characterization of esophageal submucosal glands in pig tissue and cultures.

The submucosal glands (SMGs) of the pig esophagus, like the human, secrete mucin and bicarbonate, which help in luminal acid clearance and epithelial protection. The aim of this study was to characterize histochemically the esophageal SMGs and a primary culture obtained from these glands. Tissues and cultures were stained with hematoxylin and eosin, periodic acid Schiff, Alcian blue, lectins, or cytokeratins. In the perfused esophagus, addition of carbachol increased mucin secretion by approximately 2-fold. The results indicate that [1] a method for culturing SMG cells was developed; [2] conventional staining indicates the presence of sulfated, acidic, and neutral mucopolysaccharides in glands and cultures; [3] lectin binding indicates the presence of N-acetyl glucosamine, N-acetyl neuraminic acid, N-acetyl galactosamine, and α-l-fucose in mucous cells and cultures; [4] cytokeratin and lectin staining indicated similarities with Barrett epithelium (columnar metaplasia of the esophagus); and [5] cholinergic agonists enhance mucin secretion and this could play a significant role in esophageal protection.

Mechanisms of ammonia and ammonium transport by rhesus-associated glycoproteins.

In this study we characterized ammonia and ammonium (NH3/NH4(+)) transport by the rhesus-associated (Rh) glycoproteins RhAG, Rhbg, and Rhcg expressed in Xenopus oocytes. We used ion-selective microelectrodes and two-electrode voltage clamp to measure changes in intracellular pH, surface pH, and whole cell currents induced by NH3/NH4(+) and methyl amine/ammonium (MA/MA(+)). These measurements allowed us to define signal-specific signatures to distinguish NH3 from NH4(+) transport and to determine how transport of NH3 and NH4(+) differs among RhAG, Rhbg, and Rhcg. Our data indicate that expression of Rh glycoproteins in oocytes generally enhanced NH3/NH4(+) transport and that cellular changes induced by transport of MA/MA(+) by Rh proteins were different from those induced by transport of NH3/NH4(+). Our results support the following conclusions: 1) RhAG and Rhbg transport both the ionic NH4(+) and neutral NH3 species; 2) transport of NH4(+) is electrogenic; 3) like Rhbg, RhAG transport of NH4(+) masks NH3 transport; and 4) Rhcg is likely to be a predominantly NH3 transporter, with no evidence of enhanced NH4(+) transport by this transporter. The dual role of Rh proteins as NH3 and NH4(+) transporters is a unique property and may be critical in understanding how transepithelial secretion of NH3/NH4(+) occurs in the renal collecting duct.

pH sensitivity of ammonium transport by Rhbg

Rhbg is a membrane glycoprotein that is involved in NH(3)/NH(4)(+) transport. Several models have been proposed to describe Rhbg, including an electroneutral NH(4)(+)/H(+) exchanger, a uniporter, an NH(4)(+) channel, or even a gas channel. In this study, we characterized the pH sensitivity of Rhbg expressed in Xenopus oocytes. We used two-electrode voltage clamp and ion-selective microelectrodes to measure NH(4)(+)-induced [and methyl ammonium (MA(+))] currents and changes in intracellular pH (pH(i)), respectively. In oocytes expressing Rhbg, 5 mM NH(4)Cl (NH(3)/NH(4)(+)) at extracellular pH (pH(o)) of 7.5 induced an inward current, decreased pH(i), and depolarized the cell. Raising pH(o) to 8.2 significantly enhanced the NH(4)(+)-induced current and pH(i) changes, whereas decreasing bath pH to 6.5 inhibited these changes. Lowering pH(i) (decreased by butyrate) also inhibited the NH(4)(+)-induced current and pH(i) decrease. In oocytes expressing Rhbg, 5 mM methyl amine hydrochloride (MA/MA(+)), often used as an NH(4)Cl substitute, induced an inward current, a pH(i) increase (not a decrease), and depolarization of the cell. Exposing the oocyte to MA/MA(+) at alkaline bath pH (8.2) enhanced the MA(+)-induced current, whereas lowering bath pH to 6.5 inhibited the MA(+) current completely. Exposing the oocyte to MA/MA(+) at low pH(i) abolished the MA(+)-induced current and depolarization; however, pH(i) still increased. These data indicate that 1) transport of NH(4)(+) and MA/MA(+) by Rhbg is pH sensitive; 2) electrogenic NH(4)(+) and MA(+) transport are stimulated by alkaline pH(o) but inhibited by acidic pH(i) or pH(o); and 3) electroneutral transport of MA by Rhbg is likely but is less sensitive to pH changes.