Volume‐activated Cl(‐)‐independent and Cl(‐)‐dependent K+ pathways in trout red blood cells.

Guizouarn, Hélène; Harvey, Bill; Borgèse, Franck; Gabillat, Nicole; Garcia-Romeu, F; Motais, R

doi:10.1113/jphysiol.1993.sp019572

Cited by 24 publications

(20 citation statements)

References 15 publications

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“…ID, Table 1). This electroneutral and chloride-dependent K+ extrusion has been shown to be mediated by a KCI co-transporter which is 'switched on' in response to cell swelling (Borgese, Garcia-Romeu & Motais, 1987;Guizouarn et al 1993). When the same experiment was performed in the presence of acetazolamide (Diamox, Theraplix, Paris), the pattern of the response was drastically modified.…”

Section: Resultsmentioning

confidence: 99%

“…6) and certain other inhibitors of the anion exchanger, such as niflumic acid, can strongly inhibit K+ movement and the associated H+ movements. It is of interest to note that, in trout red cells, these compounds were previously shown to interact directly with and to inhibit the volume-sensitive K+ pathway , which was subsequently shown to be a K+-anion co-transport (Guizouarn et al 1993).…”

Section: Discussionmentioning

confidence: 99%

“…The new steady state of cell volume is dynamic in nature since it is maintained by stimulation of a K+ loss which compensates for the Na+ gain induced by catecholamines. The K+ extrusion, which is Cl-dependent (Borgese et al 1987) and electroneutral, is mediated by a KCl cotransporter (Guizouarn et al 1993) which is 'switched on' or 'switched off' according to the cell volume and this tends to restore swollen cells to their original volume. Thus the catecholamine-regulated trout cell volume is delicately balanced by a separate but simultaneous operation of volume increase (VI) and regulatory volume decrease (RVD) processes.…”

Section: Discussionmentioning

confidence: 99%

“…The choice between these two pathways depends on the changes in cellular ionic strength induced by swelling: when the ionic concentration falls, the AMS 1356 cells adopt the Cl--independent pathway and when it rises, they adopt the Cl--dependent pathway (Motais, Guizouarn & Garcia-Romeu, 1991). The present study originated from experiments designed to characterize the nature of these K+ pathways (Guizouarn, Harvey, Borgese, Gabillat, Garcia-Romeu & Motais, 1993). We report here that, in a particular experimental condition which does not involve a significant volume increase, a K+ loss is observed which could be mediated by a K+-H+ exchanger: after Na+-H+ exchange activation by catecholamine, the Cl--OH-exchanges being inhibited by acetazolamide, a K+ loss occurs; in the absence of chloride movements, this K+ loss electrically balances the Na+ uptake occurring through the Na+-H+ antiport.…”

Section: Introductionmentioning

confidence: 99%

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Evidence for a K(+)‐H+ exchange in trout red blood cells.

Fiévet

Guizouarn

Pellissier

et al. 1993

The Journal of Physiology

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SUMMARY1. Exposure of trout red blood cells to ,-adrenergic agonist isoprenaline activates a cAMP-dependent Na+-H+ antiport, the movements of protons being compensated by a Cl--OH-(or HCO3) exchange mediated by band 3 protein. The absorption of water osmotically linked to sodium and chloride induces cell swelling.2. In the presence of acetazolamide, anionic exchange is inhibited and activation of cationic exchange resulted in the first 2 min in a strong external acidification and a large internal alkalinization leading to a reversal of the transmembrane pH gradient. Then, for at least 1 h and despite the inhibition of Cl-entry, a net Na+ uptake occurred which was balanced by an equivalent K+ loss, with the result that cell volume and pH gradient remained unchanged.3. In such conditions, the inactivation of the Na+-H+ exchanger by a /8-antagonist, propanolol, blocked Na+ entry while K+ continued to be lost. This volume-independent K+ efflux, which is thus independent of the Na+-H+ exchanger, was not accompanied by a Cl-efflux but was associated with large internal and external pH changes consistent with K+-H+ exchange.4. The K+ loss and the related pH changes are inhibited by compounds which are known to inhibit the K+-anion co-transporter in trout red cells, i.e. 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid (Dids) and niflumic acid.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Evidence for a K(+)‐H+ exchange in trout red blood cells.

Fiévet

Guizouarn

Pellissier

et al. 1993

The Journal of Physiology

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“…Following development of a blood acidosis, adrenaline and noradrenaline are released, activating the RBC bNHE which extrudes protons to protect RBC intracellular pH (pH i ), Hb-O 2 affinity, O 2 uptake at the gill, and therefore O 2 supply to the tissues (Borgese et al, 1987;Cossins and Kilbey, 1991;Nikinmaa et al, 1984;Primmett et al, 1986;Salama and Nikinmaa, 1988) (reviewed by Berenbrink and Bridges, 1994;Fievet and Motais, 1991;Jensen, 2004;Thomas and Perry, 1992). During this cascade of events, not only is pH i protected, sometimes elevated, but also H + extrusion and Na + influx initiate a further chain of events requiring anion exchange to remove HCO 3 -from the RBC in exchange for Cl -, Na + /K + -ATPase activation, as well as influx of osmotically obliged water, resulting in a RBC regulatory volume increase (RVI) and associated increase in haematocrit (Hct) (Borgese et al, 1987;Cossins and Gibson, 1997;Cossins and Kilbey, 1991;Guizouarn et al, 1993;Nikinmaa et al, 1990). Species possessing a RBC bNHE generally possess a pronounced Root effect, and therefore extremely pH-sensitive Hbs (Berenbrink et al, 2005); however, the bNHE has been secondarily lost in four groups of derived teleosts (Berenbrink et al, 2005), a loss that is also associated with a substantial decrease in the magnitude of the Root effect.…”

Section: Introductionmentioning

confidence: 99%

Use it or lose it? Sablefish,Anoplopoma fimbria, a species representing a fifth teleostean group where the βNHE associated with the red blood cell adrenergic stress response has been secondarily lost

Rummer

Roshan-Moniri

Balfry

et al. 2010

Journal of Experimental Biology

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SUMMARYLike most teleosts, sablefish (Anoplopoma fimbria Pallas 1814) blood exhibits a moderate Root effect (~35% maximal desaturation), where a reduction in blood pH dramatically reduces O 2 carrying capacity, a mechanism important for oxygenating the eye and filling the swim bladder (SB) in teleosts. Although sablefish lack a SB, we observed a well-defined choroid rete at the eye. The adrenergically mediated cell swelling typically associated with a functional red blood cell (RBC) b-adrenergic Na + /H + exchanger (bNHE), which would normally protect RBC pH, and thus O 2 transport, during a generalized acidosis, was not observed in sablefish blood. Neither isoproterenol (a b-agonist) nor 8-bromo cAMP could elicit this response. Furthermore, RBC osmotic shrinkage, known to stimulate NHEs in general and bNHE in other teleosts such as trout and flounder, resulted in no significant regulatory volume increase (RVI), further supporting the absence of a functional RBC bNHE. The onset of the Root effect occurs at a much lower RBC pH (6.83-6.92) than in other teleosts, and thus RBC bNHE may not be required to protect O 2 transport during a generalized acidosis in vivo. Phylogenetically, sablefish may represent a fifth group of teleosts exhibiting a secondary reduction or loss of bNHE activity. However, sablefish have not lost the choroid rete at the eye (unlike in the other four groups), which may still function with the Root effect to oxygenate the retina, but the low pH onset of the Root effect may ensure haemoglobin (Hb)-O 2 binding is not compromised at the respiratory surface during a general acidosis in the absence of RBC bNHE. The sablefish may represent an anomaly within the framework of Root effect evolution, in that they possess a moderate Root effect and a choroid rete at the eye, but lack the RBC bNHE and the SB system.

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