Abstract
Early functional studies on the choroid plexus established that the cerebrospinal fluid (CSF) secretion rate was sensitive to inhibitors of acid/base transporters and carbonic anhydrase. In fact, the CO2/HCO3 ā buffer system is required for effective CSF secretion. Unlike blood, the CSF contains very little protein and yet it responds efficiently to changes in pH utilizing primarily the CO2/HCO3 ā buffer system. Besides a central role in CSF secretion, recent studies indicate a central role for the choroid plexus epithelium in CSF pH regulation. The luminal plasma membrane expresses a variety of acid and base transport proteins of which one, the NBCe2, was directly shown to regulate CSF pH. This chapter describes the current knowledge on the molecular mechanisms in choroid plexus acid/base transport and the understanding of their possible involvement in both CSF secretion and pH regulation.
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6.1 Acid/Base Regulation in Brain Extracellular Fluid Compartments
The brain is composed of two extracellular fluid compartments: the brain extracellular fluid (BECF) surrounding cells in the parenchyma as well as the cerebrospinal fluid (CSF) that fills the ventricles and covers the brain and spinal cord (Hladky and Barrand 2016).
The fluid compartments are separated from the blood by two distinct barriers. The blood-brain barrier (BBB) separates the BECF from the blood, and the blood-cerebrospinal fluid barrier (BCSFB) separates blood from cerebrospinal fluid (CSF). These barriers have distinct barrier properties that hinder diffusion of many substances. The BECF and the CSF in the ventricles are only separated by a single layer of ependymal cells which does not constitute a barrier per se. The CSF in the subarachnoid space and the space surrounding the penetrating vessels from the surface of the brain, the Virchow-Robin space, is separated from the BECF by the pia-glial membrane. This membrane consists of a thin layer of connective tissue covering the surface of the brain parenchyma and the glia limitans which is a layer of astrocytic end-feet. This membrane is permeable to diffusion of substances between the CSF and BECF. Both the BBB and the BCSFB are permeable to CO2 that enters the brain freely and if not buffered will lead to a decrease in brain pH. In order to buffer the pH, bases such as HCO3 ā need to be transported from the blood across the barriers. This requires the presence of transporters in the membranes of the barrier.
Neuronal excitability is greatly affected by pH changes in the brain parenchyma (Baron et al. 1985). Firing of action potentials builds up the acid content in the interstitium. These acids are usually buffered and cleared and do not lead to functional damage (Kazemi et al. 1967). In some circumstances, acid production can even protect brain function. The high neuronal activity during seizures builds up an acidic environment. This activates acid sensing ion channels which leads to inhibition of the neuronal activity, and thus to halting the seizure (Ziemann et al. 2008). In febrile seizures, the fever causes the child to hyperventilate and thereby respiratory alkalosis develops in the immature brain (Schuchmann et al. 2006). The seizure is broken by the central pH decrease that follows the increased neuronal activity.
Proteins play a central role in buffering the effects of sudden changes in pH of the blood plasma and other fluid spaces. In contrast, CSF contains only small amounts of protein but brain pH is nevertheless maintained within a quite narrow range. Fluctuations in plasma pH and pCO2 are followed over time by similar changes in CSF pH (Lee et al. 1969). While CO2 crosses all brain barriers rapidly, H+ and HCO3 ā mainly cross the CPE via membrane transporters. One would expect this to result in sizable fluctuations in brain pH during respiratory acidosis because of the lack of protein buffers. However, in respiratory acidosis the decrease in blood pH surpasses that of CSF pH due to the presence of efficient buffers such as the open CO2/HCO3 ā buffer system. In support for such buffering, Hasan and collaborators found that inhalation of 5% CO2 for 4Ā h lead to a threefold higher increase in CSF HCO3 ā compared to plasma HCO3 ā in dogs (Hasan and Kazemi 1976).
CSF pH is known to directly influence BECF pH in the areas close to the ventricle system (Okada et al. 1993). Also, the CSF in the subarachnoid space enters the brain parenchyma via the blood vessels. The composition of CSF thereby greatly affects the composition of the BECF and thereby the pH regulation of the brain parenchyma.
6.2 Choroid Plexus Acid-Base Transport
The production of CSF amounts to approximately 500Ā ml CSF daily in humans, of which the major proportion is secreted by the epithelial cells of the choroid plexus (Cserr 1971). The CSF formation by the choroid plexus depends primarily on the transepithelial movement of Na+, Clā, HCO3 ā and H2O (Pollay and Curl 1967; Welch 1963; Davson and Segal 1970; Wright 1972). Apart from the central involvement of typical transport proteins such as e.g. the Na+, K+-ATPase (Welch 1963; Davson and Segal 1970; Wright 1972) in CSF production by the choroid plexus, the CO2/HCO3 ā buffering system and acid-base transporters seem to be of pivotal importance for the process of secretion. Firstly, the carbonic anhydrase inhibitor acetazolamide inhibits CSF secretion significantly (Welch 1963; Tschirgi et al. 1954; Kister 1956; Davson and Luck 1957; Ames et al. 1965; Segal and Burgess 1974; Pollay and Davson 1963; Vogh et al. 1987; Murphy and Johanson 1989a) (Fig. 6.1). Secondly, CSF secretion is sensitive to manipulations of basolateral pH and HCO3 ā concentration (Saito and Wright 1983), and basolateral application of the stilbene-type HCO3 ā transport inhibitor DIDS reduces the secretion rate by choroid plexus epithelial cells (Deng and Johanson 1989). Finally, the NHE inhibitor amiloride inhibits Na+ import into the choroid plexus from the blood side as well as the CSF secretion (Davson and Segal 1970; Murphy and Johanson 1989a, b; Johanson and Murphy 1990), suggesting a dependence of CSF secretion on basolateral Na+/H+ exchange. Nevertheless, injection of amiloride into the ventricles had a similar effect on CSF secretion (Segal and Burgess 1974). In the following, we summarize the current knowledge on choroid plexus carbonic anhydrases and acid-base transport proteins.
6.2.1 Carbonic Anhydrases
In many biological systems, the hydration of CO2 to form H2CO3 is catalyzed by carbonic anhydrases (Boron and Boulpaep 2012), and H2CO3 then dissociates spontaneously to HCO3 ā and H+. Carbonic anhydrases are among the fastest enzymes studied and are blocked by acetazolamide (Maren 1962). Carbonic anhydrase activity is important for CSF production by the choroid plexus, as acetazolamide reduces secretion in the range of 50ā100% depending on the experimental setup (Welch 1963; Davson and Segal 1970; Ames et al. 1965). In the early experiments, carbonic anhydrase activity was mainly considered in relation to the cytosol where HCO3 ā would be produced within the cell by intracellular carbonic anhydrase such as CAII (Fig. 6.2). This led to the hypothesis that HCO3 ā secretion by the CPE depended on intracellular formation from CO2 and H2O (Vogh and Maren 1975; Maren 1972). However, this reaction would also produce intracellular H+, and the choroid plexus cell would therefore require an efficient basolateral H+ extrusion mechanism such as a Na+/H+ exchanger (NHE) in order to sustain CSF secretion. There is, indeed, an apparent lack of such transport mechanism in the basolateral membrane of choroid plexus epithelial cells, i.e. there is no basolateral membrane expression of NHEās and only minimal acid extrusion capacity in the absence of Na+ or CO2/HCO3 ā [see below Bouzinova et al. (2005), Damkier et al. (2009), Christensen et al. (2017)]. The only known basolateral āacid-extrudersā are actually two HCO3 ā import proteins (Ncbe and NBCn1, see below).
Thus, the model of intracellular formation of HCO3 ā for secretion and basolateral H+ extrusion is difficult to sustain despite Marenās pioneering work. One indication for a transcellular route for secreted HCO3 ā came from the clear enzyme histochemical demonstration that choroid plexus epithelial carbonic anhydrase activity was almost entirely restricted to the microvilli and the basal infoldings (Masuzawa et al. 1981). This is consistent with the detection of plasma membrane carbonic anhydrases CAIX and CAXII in the choroid plexus (Christensen et al. 2017; Kallio et al. 2006), where CAXII is localized to the basolateral membrane and CAIX may be enriched in the luminal domain (Fig. 6.2). Both CAIX and CAXII are single-pass transmembrane proteins with extracellular catalytic domains (Tureci et al. 1998; Opavsky et al. 1996). We are not aware of any other normal epithelium expressing both of these CA forms. The close proximity between these enzymes and the plasma membrane HCO3 ā transporters may increase transport rates by supplying sufficient substrate (HCO3 ā or even CO3 2ā) for the transport (McMurtrie et al. 2004). The putative direct physical and functional associations of external membrane-bound and/or cytosolic carbonic anhydrases with HCO3 ā transporters such as AE2 and NBCe1 is compelling although still debated (McMurtrie et al. 2004; Boron 2010). Nevertheless, it remains possible that membrane bound CAs with extracellular enzyme activity are the actual targets of acetazolamide in the choroid plexus, and that a reduced HCO3 ā transport rate results in the observed decline in CSF secretion. The primary target for acetazolamide in the choroid plexus needs to be investigated in order to establish to what extent secreted HCO3 ā arise from cytosolic production and from transcellular carrier mediated movement.
6.2.2 Base Transporters
As mentioned above, the presence of the CO2/HCO3 ā buffering system is necessary for efficient CSF secretion thereby indirectly implicating the participation of HCO3 ā transporters in the process of CSF secretion (Haselbach et al. 2001). Indeed, DIDS reduces HCO3 ā and Na+ transport rates to the luminal side of the epithelium both after basolateral and luminal application (Deng and Johanson 1989; Nattie and Adams 1988; Mayer and Sanders-Bush 1993). Bicarbonate transporters arise from two gene families: the solute carrier (Slc) 4 and 26 families (Romero et al. 2013; Cordat and Reithmeier 2014). The Slc4 derived polypeptides include the classical Clā/HCO3 ā exchangers of which Ae2 and, the electrogenic sodium bicarbonate exchanger NBCe2, the electroneutral NBCn1, and Ncbe/NBCn2 expressed in the choroid plexus (Damkier et al. 2013). Apart from epithelial NBCn1, these transporters are DIDS sensitive and candidate targets mediating the inhibitory effect of stilbene derivatives on CSF secretion.
6.2.2.1 The Anion Exchanger Ae2, Slc4a2
Ae2 mediates electroneutral exchange of extracellular Clā for intracellular HCO3 ā, and thus extrudes base from the cell (Alper 2009),is more active at alkaline pH, and is inhibited by DIDS (4). The import of Clā into the choroid plexus epithelial cell from the interstitium is necessary for continuous CSF secretion, and most likely involves classical anion exchangers as judged from the sensitivity towards basolateral DIDS application (Deng and Johanson 1989; Frankel and Kazemi 1983) and the requirement for CO2/HCO3 ā (Hughes et al. 2010). Ae2 is expressed at the basolateral membrane domain of choroid plexus epithelial cells with the highest signal at the basal labyrinth (Lindsey et al. 1990; Alper et al. 1994; Praetorius and Nielsen 2006) (Fig. 6.3). The localization and direction of transport suggests that Ae2 is involved in transcellular Clā transport and is in fact the only known basolateral Clā entry mechanism for sustaining CSF secretion. Ae2 may also be indirectly involved in CSF pH regulation, as it could facilitate continued H+ excretion across the luminal membrane as e.g. in CSF pH regulation during alkalosis.
6.2.2.2 The Electroneutral Na+ and HCO3 ā Transporter Ncbe, NBCn2, Slc4a10
Polypeptides derived from slc4a10 have all been characterized as DIDS sensitive electroneutral Na+ driven and HCO3 ā importers (Giffard et al. 2003; Wang et al. 2000; Damkier et al. 2010; Parker et al. 2008). First, the HCO3 ā transport was shown to depend on intracellular Clā in mammalian expression systems transfected with slc4a10 (Giffard et al. 2003; Wang et al. 2000). In one study, the stoichiometry for Na+ to acid-base equivalents was estimated to 1:2 and a net Clā efflux was DIDS-sensitive (Damkier et al. 2010). Thus, the transporter was characterized as a Na+-dependent Clā/HCO3 ā exchanger and named Ncbe. However, convincing results from a study using the human SLC4A10 gene product expressed in Xenopus laevis oocytes did not support the dependence of transport on intracellular Clā nor was a net Clā extrusion detected by Parker et al. (2008). The protein was therefore renamed NBCn2 as an electroneutral Na+:HCO3 ā cotransporter. We prefer to apply the transporter names Ncbe in rodents and NBCn2 in humans as long as this controversy is not resolved.
In the choroid plexus, the Ncbe/NBCn2 transporter is localized on the basolateral membrane (Praetorius and Nielsen 2006; Praetorius et al. 2004a), and is therefore proposed to supply the CPE with both Na+ and HCO3 ā from the blood side of the epithelium (Fig. 6.4). Consistent with this idea, the Na+ and CO2/HCO3 ādependent base uptake (or acid extrusion) in the choroid plexus epithelium is partly DIDS sensitive, probably reflecting Ncbe activity (Bouzinova et al. 2005). Direct involvement of Ncbe in the pHi regulation of choroid plexus epithelial cells was demonstrated in studies of Ncbe knockout mice. The choroid plexus from Ncbe knockout mice showed a severely diminished Na+-dependent acid extrusion compared to normal littermates (Jacobs et al. 2008), and up to 70% of the DIDS-sensitive pHi recovery from acid load depends on this transporter (Damkier et al. 2009). Besides regulating pHi of the choroid plexus epithelial cells, Ncbe mediated HCO3 ā loading may well facilitate the luminal bicarbonate extrusion. In this way, Ncbe could sustain luminal HCO3 ā secretion and indirectly participate in CSF pH regulation.
As one of a very few Na+ transporters in the basolateral membrane, the Ncbe/NBCn2 probably constitutes the bottleneck for Na+ in CSF secretion, although this has not yet been demonstrated directly. Nevertheless, the genetic disruption of Ncbe resulted in a reduction in brain ventricle size to almost the same degree as the Na+:HCO3 ā cotransport (Jacobs et al. 2008). This may suggest that Ncbe knockout also greatly diminished the rate of CSF secretion. One should take caution suggesting a central role for Ncbe in CSF secretion, although the studies in Ncbe knockout mice are compelling in that regard. Large changes in abundance of other transport proteins of interest may also explain the decreased ventricular volume and the feasibly diminished CSF secretion in Ncbe knockout mice. Ncbe knockout critically affected the expression levels of the Na+, K+-ATPase, AQP1, Ae2, and e.g. membrane protein anchoring proteins (Damkier et al. 2009; Christensen et al. 2013; Damkier and Praetorius 2012). The luminal Na+/H+ exchanger NHE1 of the normal choroid plexus was demonstrated in the basolateral membrane domain of the epithelial cells from Ncbe knockout mice (Damkier et al. 2009). Thus, studies directly demonstrating the involvement of Ncbe in CSF secretion are highly warranted.
6.2.2.3 The Electrogenic Na+:HCO3 ā Cotransporter NBCe2, Slc4a5
The electrogenic cotransporter NBCe2 transports 1 Na+ with 2 or 3 HCO3 ā in or out of cells across the plasma membrane depending on tissue-specific factors (Sassani et al. 2002; Virkki et al. 2002). Typical electrochemical gradients for Na+ and HCO3 ā favor outward transport in the 1:3 transport mode and inward transport in the 1:2 transport mode. Electrogenic HCO3 ā transport in the luminal membrane of choroid plexus epithelial cells was established in bull frog (Saito and Wright 1984), and the Na+ dependence of transport indicated an outwardly directed Na+:HCO3 ā cotransport mechanism was shown in mouse and rat (Banizs et al. 2007; Johanson et al. 1992). These observations could be explained by the expression of NBCe2 in the luminal plasma membrane domain of rat (Bouzinova et al. 2005) and mouse (Christensen et al. 2018) choroid plexus (Fig. 6.5). NBCe2 mRNA was detected in human choroid plexus as well (Praetorius and Nielsen 2006; Damkier et al. 2007), but the protein was not immunolocalized to the epithelium, probably reflecting amino acid sequence differences compared to the rodent immunogenic epitope applied thus far. NBCe2 exports Na+ and HCO3 ā across the luminal membrane of mouse CPE in an apparent 1:3 stoichiometry (Millar and Brown 2008). Thus, NBCe2 is believed to take part in the Na+ secretion of the choroid plexus epithelium as well as the regulation of intracellular pH and even extracellular pH.
Inhalation of 11% CO2 causes a significant increase in the Na+ content in rodent CSF (Nattie 1980). This effect may represent indirect evidence for NBCe2 function in the choroid plexus. More recently, the physiological significance of NBCe2 has been studied more directly in three different NBCe2 knockout mouse strains. The first study reported that NBCe2 deficiency resulted in decreased ventricular volume and intracranial pressure, changes in CSF electrolyte composition, and resistance to seizure induction (Kao et al. 2011). Taken together, the study suggested NBCe2 to be involved in both the regulation of CSF [HCO3 ā] and in CSF secretion. However, the interpretation of the findings was compromised by the changes in expression profiles of other transporter proteins in choroid plexus. For example, the changes in expression and localization of Ncbe and Na,K-ATPase units in this gene trap NBCe2 knockout would most likely contribute considerably to the observed phenotype. The second study focused on the renal consequences of NBCe2 knockout in the kidney. It was, however, noted that the ventricle volume did not seem to be greatly affected by the gene disruption (Groger et al. 2012) and therefore this study seems to contradict a central role for NBCe2 in CSF secretion. In the latest study of NBCe2 ko mice, caution was again taken to validate the model by describing the expression profiles of various transporters in the choroid plexus epithelium (Christensen et al. 2018). This model did not reveal any changes in abundance or subcellular distribution of other transport proteins or gross changes in ventricle dimensions in the knockouts. However, NBCe2 was directly involved in base extrusion after intracellular alkalization ex vivo, and critically implicated in CSF pH recovery during hypercapnia-induced acidosis in vivo (Christensen et al. 2018). Thus, this study provided direct mechanistic evidence of the implication of the choroid plexus epithelium in CSF pH regulation, and established NBCe2 as the central mediators of this physiological process.
6.2.2.4 The Electroneutral Na+:HCO3 ā Cotransporter NBCn1, Slc4a7
NBCn1 is an electroneutral sodium bicarbonate cotransporter that mediates Na+ and HCO3 ā uptake into cells (Romero et al. 2013). The epithelial NBCn1 form is relatively DIDS insensitive, and in the rat choroid plexus the Na-dependent HCO3 ā influx was partly ascribed to this transporter (Bouzinova et al. 2005). Experiments in Ncbe and NBCn1 knockout mice indicate that NBCn1 may contribute less to pH recovery from acidosis in this species (Jacobs et al. 2008; Damkier, unpublished observation). The polarized plasma membrane distribution of NBCn1 in the choroid plexus varies among species and even among stains (Fig. 6.6). NBCn1 was localized to basolateral membrane domain in rats and humans (Praetorius and Nielsen 2006; Praetorius et al. 2004a), but can also be detected in the luminal membrane domain within the same human choroid plexus (Praetorius and Nielsen 2006). In the mouse, the luminal or basolateral NBCn1 expression seems to depend on the strain (Damkier et al. 2009; Praetorius et al. 2004a; Kao et al. 2011).
It is unlikely that NBCn1 takes part significantly in the vectorial HCO3 ā transport across the choroid plexus epithelium during correction of CSF pH, as it is not always expressed in the same membrane domain. As a HCO3 ā loader, NBCn1 could be involved in regulating pH within the choroid plexus epithelium, which may require separate acid-base transporters than those involved in the secretory process. It is unknown whether choroid plexus NBCn1 abundance and function is regulated in acid-base disturbances as elsewhere (Praetorius et al. 2004b). In neurons, NBCn1 is upregulated during metabolic acidosis (Park et al. 2010), thus this transporter could possibly have a similar role in the choroid plexus. Further studies are warranted to elucidate the roles of NBCn1 in this tissue.
6.2.2.5 The slc4a11 Gene Product
The transport function of SLC4A11 gene products is much debated, and consensus has not yet been reached regarding a unifying name for the transporter. The controversy probably results from the application of varying experimental techniques and species differences among genes and expression systems in these studies. In bovine corneal endothelial cells, the Na+-coupled OHā transport depended on the expression of SLC4A11 (Jalimarada et al. 2013). The human SLC4A11 forms seem to transport H+ in both Na+-dependent and -independent modes. In the presence of ammonia, SLC4A11 generated inward currents that were comparable in magnitude (Kao et al. 2016). In another study, however, human SLC4A11 seems to mediate electroneutral NH3 transport in a Na+ independent manner (Loganathan et al. 2016). By contrast, mouse slc4a11 mediates a OHā (or H+) selective conductance without cotransport characteristics (Myers et al. 2016). Both the rat and the human choroid plexus epithelia express SLC4A11 derived proteins in the luminal membrane domains (58), but slc4a11 was not detected in the mouse choroid plexus (Damkier et al. 2018). Thus, the significance of NaBC1 in relation to choroid plexus function is unknown.
6.2.2.6 Anion Conductances
As mentioned above, HCO3 ā is secreted across the luminal membrane by electrogenic processes and can be stimulated by cAMP. This transport could be mediated by NBCe2 alone or in concert with HCO3 ā conductive anion channels. Indeed, protein kinase A stimulates inward-rectifying anion conductances in mammalian choroid plexus epithelial cells (Kibble et al. 1996, 1997). In the amphibian choroid plexus, a HCO3 ā conductive and cAMP-regulated ion channel was proposed as the major HCO3 ā efflux mechanism of the luminal membrane (Saito and Wright 1983, 1984). It seems that the inward-rectifying anion channels in the mammalian choroid plexus possess such high HCO3 ā permeability (Kibble et al. 1996). The molecular identities of the anion channels have not been fully established yet, but CFTR and Clc-2 have been ruled out as mediators of the inward-rectifying anion channels (Kibble et al. 1996, 1997; Speake et al. 2002). Recent mass spectrometry analysis of mouse choroid plexus epithelial cells indicated the expression of voltage-dependent anion channels (Vdac1ā3) (Damkier et al. 2018).
6.2.2.7 Slc26-Derived HCO3 ā Transporters
It is possible that membrane proteins belonging to the slc26 gene family could serve as HCO3 ā transporters in the choroid plexus epithelium. The mRNA for slc26a2 (Kant et al. 2018), slc26a4 (Saunders et al. 2015), slc26a7, slc26a10, and slc26a11 (own unpublished observations) have all been detected at the mRNA level in the choroid plexus, but the corresponding proteins have not been detected in isolated epithelial cells by mass spectrometry (Damkier et al. 2018). Thus, it remains to be established to what extent these transporters contribute to base transport in the choroid plexus epithelium.
6.2.3 Acid Transporters
6.2.3.1 The Na+/H+ Exchangers, NHE1, slc9a1 and NHE6, slc9a6
The Na+/H+ exchanger NHE1 is almost ubiquitously expressed and mediates the electroneutral exchange of Na+ and H+, driven by the inward Na+ gradient. It is inhibited by amiloride derivatives, such as EIPA (233). Na+/H+ exchange has been suggested as basolateral entry pathway for Na+ and therefore centrally involved in CSF secretion, as amiloride applied from the blood side of the CPE inhibits Na+ accumulation and CSF secretion (Davson and Segal 1970; Murphy and Johanson 1989a, b). This type of transporter would at the same time provide a basolateral H+ extrusion mechanism to support luminal HCO3 ā secretion. NHE1 mRNA was demonstrated by RT-PCR analysis (Kalaria et al. 1998) and EIPA-sensitive Na/H exchange was detected in isolated epithelial cells (Bouzinova et al. 2005; Damkier et al. 2009). Thus, for some time NHE1 was thought as the primary Na+ loader in the choroid plexus epithelium.
Some evidence seems to contradict a central role of basolateral NHE activity in choroid plexus function. Firstly, amiloride applied form the luminal side was as efficient as basolateral amiloride in inhibiting CSF secretion (Segal and Burgess 1974). Secondly, amiloride failed to inhibit the Na+-dependent pH recovery in the choroid plexus cultures in the presence of the CO2/HCO3 ā buffer system (Mayer and Sanders-Bush 1993). Finally, NHE1 was immunolocalized to the luminal membrane domain of the choroid plexus epithelium in both mice and humans (Damkier et al. 2009; Praetorius and Nielsen 2006; Kao et al. 2011) (Fig. 6.7). NHE1 expression was required for detection of any Na+-dependent pHi recovery from acid load in choroid plexus, as judged from experiments on NHE1 knockout mice (Damkier et al. 2009). At first glance, this is indicative of NHE1 being the only NHE in the choroid plexus. However, the abundance of NHE1 is low in the choroid plexus as judged from the immunoreactivity in the referred studies and from mass spectrometry (Damkier et al. 2018). Another Na+/H+ exchanger detected in the CPE is NHE6. Although this transporter is usually found in the endosomes, it has been immunolocalized partly in the luminal membrane domain in mouse CPE (Damkier et al. 2018) (Fig. 6.8a). No mRNA for NHE2ā5 and NHE7ā9 have been detected in the CPE in the same study. NHEs are usually considered as regulators of intracellular pHi, but since NHE1 and NHE6 transport H+ out of the cell into the CSF, they could partake in CSF pH regulation. Future studies of the respective roles of NHE1 and NHE6 in intracellular pH and/or CSF pH regulation are warranted.
6.2.3.2 H+-ATPases
Transmembrane ATPases catalyze the āuphillā movement of H+ across membranes utilizing the energy generated by the hydrolysis of ATP into ADP and free phosphate. The vacuolar H+-ATPase (V-ATPase) lowers the pH of vesicles in the endo-lysosomal system, but can also be plasma membrane acid extruders in epithelia. The B2 isoform of the V-ATPase is usually restricted to the lysosomes and endosomes (Puopolo et al. 1992), yet a small population of the polypeptide was immunolocalized to the luminal membrane domain in the mouse choroid plexus epithelium (Christensen et al. 2017) (Fig. 6.8b). However, the contribution of luminal V-ATPase to acid-extrusion in the choroid plexus of mice seems to be insignificant compared to NHE activity (Christensen et al. 2017). H+/K+-ATPases comprise a separate group of cellular acid extruders, that might contribute to choroid plexus acid-base transport. In rabbits, application of omeprazole, an inhibitor of gastric H+/K+-ATPase from the luminal side reduced CSF secretion rate (Lindvall-Axelsson et al. 1992). Thus far, only the non-gastric isoform of H+/K+-ATPase has been detected in the rabbit and mouse choroid plexus (Damkier et al. 2018; Pestov et al. 1998). In the unstimulated mouse choroid plexus the Na+-independent acid extrusion is negligible (Christensen et al. 2017), leaving little room for H+/K+-ATPase to have a significant role in this tissue.
6.2.3.3 Acid Transporters Related to Clā Channel
Several polypeptides belonging to the ClC group of Clā channels have been characterized as Clā/H+ exchangers. Among these, ClC3, ClC4, ClC5 and ClC7 were detected by mass spectroscopy in isolated epithelial cells from the mouse choroid plexus (Damkier et al. 2018). A fraction of the ClC7 immunoreactivity was detected in the luminal CPE membrane domain in the same study, where the expected vesicular ClC7 was also described (Fig. 6.8c). Clā/H+ exchange activity was demonstrated in isolated mouse CPE clusters, as removal and reintroduction of extracellular Clā in the absence of Na+ and HCO3 ā caused the relevant changes in pHi. Whether ClC7 is the main Clā/H+ exchanger, or other ClC isoforms also contribute to pH regulation in the CPE in vivo requires further investigations. It is peculiar that, like osteoclasts, choroid plexus epithelial cells seems to express a fraction of endo-lysosomal acid transport proteins in the luminal membrane (Fig. 6.9).
6.3 Choroid Plexus Acid-Base Transporters and Cerebrospinal Fluid Secretion
Some evidence supports the central involvement of choroid plexus acid-base transporters in the secretion of CSF. Firstly, the concentrations of Na+ and HCO3 ā in CSF are higher than expected from an ultrafiltrate (Hughes et al. 2010). Secondly, the CSF secretion and the choroid plexus transport rates are highly affected by acetazolamide, amiloride, and DIDS (Welch 1963; Davson and Segal 1970; Tschirgi et al. 1954; Davson and Luck 1957; Ames et al. 1965; Murphy and Johanson 1989a; Johanson and Murphy 1990; Johanson et al. 1992; McCarthy and Reed 1974; Vogh and Godman 1985). Thirdly, the ventricle volume is affected by genetic disruption of Ncbe and in one report of NBCe2 (Jacobs et al. 2008; Kao et al. 2011). AE2 and Ncbe are most likely mediating the major fraction of Na+, Clā and HCO3 ā import to the epithelial cells from the blood side that is necessary for secretion across the luminal membrane. These proteins are expressed in high abundance in the basal labyrinth of the choroid plexus across species and very few alternative absorptive pathways exist in the basolateral membrane. Thus, there are indications for a dependence of fluid secretion by the CPE on acid-base transporters.
6.4 Choroid Plexus and Cerebrospinal Fluid pH Regulation
The acute CSF pH greatly depends on the breathing rate, yet over time CSF pH is maintained within narrow limits (Lee et al. 1969). Upon changes in respiration frequency or tidal volume, pCO2 in the blood changes accordingly. Since CO2 can easily cross the blood-brain and blood-CSF barriers, increased pCO2 in the blood results in increased pCO2 in the CSF and brain ECF, and thus low pH (Johnson et al. 1983). Changes in metabolic acid-base balance are not reflected in CSF pH, as HCO3 ā and H+ have to be actively transported over these barriers. As mentioned previously, contrary to the blood plasma, CSF contains very little protein and phosphate buffers, thus should be subjected to a great level of pH variation during respiratory acidosis. However, several studies have demonstrated that increased CSF pCO2 is compensated by an increase in CSF HCO3 ā, independently of blood acid-base balance. The robust expression of a HCO3 ā export protein NBCe2 in the luminal plasma membrane of the CPE spurred the idea that this tissue could serve a CSF pH regulatory function (Bouzinova et al. 2005) (Fig. 6.5).
NBCe2 transports Na+ and HCO3 ā out of the CPE cells, most likely with a 1:3 stoichiometry (Millar and Brown 2008), and with its membrane localization it constitutes an ideal candidate for the HCO3 ā secretion into the CSF. As discussed above, two sources of HCO3 ā for the secretion has been proposed. The classic view is an origin from the hydration of intracellular CO2. The high levels of carbonic anhydrase II in the CPE would efficiently convert CO2 to HCO3 ā to supply the luminal transporter with HCO3 ā (Johanson et al. 1992). The problem with this explanation is the apparent lack of NHE proteins in the basolateral membrane. The alternative view is transcellular passage of HCO3 ā, where e.g. Ncbe mediates the import of HCO3 ā across the basolateral membrane (Praetorius et al. 2004c).
CSF pH seems to respond more efficiently to respiratory acidosis than to alkalosis, indicating that the acid extrusion by the CPE is less effective than the alkaline export (Kazemi et al. 1967). Nevertheless, the CPE cells express several proteins that could be involved in acid extrusion to the CSF. In the luminal membrane, Na+/H+ exchangers NHE1 (and NHE6) export H+ in exchange for Na+ (Damkier et al. 2009) and thereby candidate as mechanisms to lower CSF pH. NHE1 is involved in the regulation of intracellular pH in the CPE cells (Damkier et al. 2009), but its putative role in CSF pH regulation has not been investigated. Recently, we demonstrated that a fraction of the vacuolar H+-ATPase (V-ATPase) is expressed in the luminal membrane of CPE cells (Christensen et al. 2017). Although this pump is involved in extracellular acidification elsewhere, our study rejects the V-ATPase as a significant contributor to CSF pH regulation (Christensen et al. 2017). The 2Clā/H+ antiporter ClC-7 was also immunolocalized to the luminal membrane of CPE cells in the same study. However, the highly electrogenic nature of the transport by this protein makes ClC7 highly unlikely as an efficient acid extruder. It is unknown whether AE2 plays a role on CSF pH regulation, but the basolateral expression and the export HCO3 ā in exchange for Clā (Alper et al. 1994) could be required sustain luminal H+ secretion.
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Barbuskaite, D., Damkier, H., Praetorius, J. (2020). Acid/Base Transporters in CSF Secretion and pH Regulation. In: Praetorius, J., Blazer-Yost, B., Damkier, H. (eds) Role of the Choroid Plexus in Health and Disease. Physiology in Health and Disease. Springer, New York, NY. https://doi.org/10.1007/978-1-0716-0536-3_6
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