Na+/HCO3 – Cotransporter NBCn2 Mediates HCO3 − Reclamation in the Apical Membrane of Renal Proximal Tubules

Guo, Yan; Liu, Ying; Liu, Mei; Wang, Jin Lin; Xie, Zhang Dong; Chen, Kang Jing; Wang, Deng Ke; Occhipinti, Rossana; Boron, Walter F.; Chen, Li Ming

doi:10.1681/asn.2016080930

Cited by 27 publications

(39 citation statements)

References 39 publications

(92 reference statements)

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“…The recent discovery that the electroneutral Na/HCO 3 cotransporter NBCn2 is abundantly present in the apical membrane of the PT [90] is consistent with the idea that this transporter may mediate ~20% of total acid–base traffic across the apical membrane—previously unaccounted for. Although the mechanism of NBCn2 may be the simple cotransport of Na + plus HCO 3 − (Figure 8A), evidence that NBCn2 may in fact be an exchanger [91] is consistent with the idea that NBCn2 exchanges Na + plus CO 3 = for HCO 3 − (Figure 8B).…”

Section: Role Of Carbonic Anhydrases In Whole-body Acid–base Homeosupporting

confidence: 57%

Role of Carbonic Anhydrases and Inhibitors in Acid–Base Physiology: Insights from Mathematical Modeling

Occhipinti

Boron

2019

IJMS

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Carbonic anhydrases (CAs) catalyze a reaction fundamental for life: the bidirectional conversion of carbon dioxide (CO2) and water (H2O) into bicarbonate (HCO3−) and protons (H+). These enzymes impact numerous physiological processes that occur within and across the many compartments in the body. Within compartments, CAs promote rapid H+ buffering and thus the stability of pH-sensitive processes. Between compartments, CAs promote movements of H+, CO2, HCO3−, and related species. This traffic is central to respiration, digestion, and whole-body/cellular pH regulation. Here, we focus on the role of mathematical modeling in understanding how CA enhances buffering as well as gradients that drive fluxes of CO2 and other solutes (facilitated diffusion). We also examine urinary acid secretion and the carriage of CO2 by the respiratory system. We propose that the broad physiological impact of CAs stem from three fundamental actions: promoting H+ buffering, enhancing H+ exchange between buffer systems, and facilitating diffusion. Mathematical modeling can be a powerful tool for: (1) clarifying the complex interdependencies among reaction, diffusion, and protein-mediated components of physiological processes; (2) formulating hypotheses and making predictions to be tested in wet-lab experiments; and (3) inferring data that are impossible to measure.

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Section: Role Of Carbonic Anhydrases In Whole-body Acid–base Homeosupporting

confidence: 57%

Role of Carbonic Anhydrases and Inhibitors in Acid–Base Physiology: Insights from Mathematical Modeling

Occhipinti

Boron

2019

IJMS

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“…In mammals, the SLC4 familiy can be categorized into three major clades of HCO 3 - and/or CO 3 2- transporters including Na + -driven Cl - /HCO 3 - exchangers, electrogenic Na + coupled HCO 3 - transporters and electroneutral Na + coupled HCO 3 - transporters ( Romero et al, 2013 ; Romero et al, 2004 ). Our phylogenetic analysis based on deduced amino acid sequences suggest that SpSlc4a10 has highest identity with the mammalian clade of electroneutral Na + coupled HCO 3 - transporters, including Na + /HCO 3 - cotransporters (NBCn) and Na + -driven Cl - /HCO 3 - exchangers (NCBE) that were demonstrated to control pH i in neurons ( Wang et al, 2000 ) and enable the transcellular passage of HCO 3 - across epithelial cells of the pancreatic duct and the renal proximal tubule ( Guo et al, 2017 ; Ko et al, 2002 ). The human NBCn2 encoded by Slc4a10 has absolute requirements for Na + and HCO 3 - and appears to be a Na + -dependent Cl - /HCO 3 - exchanger that is blocked in the presence of 200 µM DIDS ( Parker et al, 2008 ).…”

Section: Discussionmentioning

confidence: 99%

A SLC4 family bicarbonate transporter is critical for intracellular pH regulation and biomineralization in sea urchin embryos

Yan

Petersen

et al. 2018

eLife

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Efficient pH regulation is a fundamental requisite of all calcifying systems in animals and plants but with the underlying pH regulatory mechanisms remaining largely unknown. Using the sea urchin larva, this work identified the SLC4 HCO3- transporter family member SpSlc4a10 to be critically involved in the formation of an elaborate calcitic endoskeleton. SpSlc4a10 is specifically expressed by calcifying primary mesenchyme cells with peak expression during de novo formation of the skeleton. Knock-down of SpSlc4a10 led to pH regulatory defects accompanied by decreased calcification rates and skeleton deformations. Reductions in seawater pH, resembling ocean acidification scenarios, led to an increase in SpSlc4a10 expression suggesting a compensatory mechanism in place to maintain calcification rates. We propose a first pH regulatory and HCO3- concentrating mechanism that is fundamentally linked to the biological precipitation of CaCO3. This knowledge will help understanding biomineralization strategies in animals and their interaction with a changing environment.

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“…Interestingly, previous studies have shown that the epithelia in the submandibular salivary gland and pancreatic duct also express NBCn1 (termed as “NBC3”) and NHEs at the apical membrane contributing to reabsorb the luminal

under resting condition (Lee et al, 1998 , 2000 ; Luo et al, 2001 ; Park et al, 2002 ). In a more recent study, it is shown that the

reabsorption in the proximal tubule epithelium involves the apical Na + /

cotransporter NBCn2 and NHE3 (Guo et al, 2017 ). Thus, the

reabsorption (and therefore luminal acidification) in these tissues involves direct

-uptake via the apical NBCn1 and indirect

-reabsorption dependent on proton secretion via the apical NHEs.…”

Section: Discussionmentioning

confidence: 99%

The Balance of HCO3- Secretion vs. Reabsorption in the Endometrial Epithelium Regulates Uterine Fluid pH

et al. 2018

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Uterine fluid contains a high concentration of HCO3- which plays an essential role in sperm capacitation and fertilization. In addition, the HCO3- concentration in uterine fluid changes periodically during the estrous cycle. It is well-known that the endometrial epithelium contains machineries involving the apical SLC26 family anion exchangers for secreting HCO3- into the uterine fluid. In the present study, we find for the first time that the electroneutral Na+/HCO3- cotransporter NBCn1 is expressed at the apical membrane of the endometrial epithelium. The protein abundance of the apical NBCn1 and that of the apical SLC26A4 and SLC26A6 are reciprocally regulated during the estrous cycle in the uterus. NBCn1 is most abundant at diestrus, whereas SLC26A4/A6 are most abundant at proestrus/estrus. In the ovariectomized mice, the expression of uterine NBCn1 is inhibited by β-estradiol, but stimulated by progesterone, whereas that of uterine SLC26A4/A6 is stimulated by β-estradiol. In vivo perfusion studies show that the endometrial epithelium is capable of both secreting and reabsorbing HCO3-. Moreover, the activity for HCO3- secretion by the endometrial epithelium is significantly higher at estrus than it is at diestrus. The opposite is true for HCO3- reabsorption. We conclude that the endometrial epithelium simultaneously contains the activity for HCO3- secretion involving the apical SLC26A4/A6 and the activity for HCO3- reabsorption involving the apical NBCn1, and that the acid-base homeostasis in the uterine fluid is regulated by the finely-tuned balance of the two activities.

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Na+/HCO3 – Cotransporter NBCn2 Mediates HCO3 − Reclamation in the Apical Membrane of Renal Proximal Tubules

Cited by 27 publications

References 39 publications

Role of Carbonic Anhydrases and Inhibitors in Acid–Base Physiology: Insights from Mathematical Modeling

Role of Carbonic Anhydrases and Inhibitors in Acid–Base Physiology: Insights from Mathematical Modeling

A SLC4 family bicarbonate transporter is critical for intracellular pH regulation and biomineralization in sea urchin embryos

The Balance of HCO3- Secretion vs. Reabsorption in the Endometrial Epithelium Regulates Uterine Fluid pH

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