SODIUM, POTASSIUM-REQUIRING ADENOSINETRIPHOSPHATASE ACTIVITY. I. PURIFICATION AND PROPERTIES

Structural organization and energy transduction mechanism of Na+,K+-ATPase studied with transition metal-catalyzed oxidative cleavage

This chapter describes contributions of transition metal-catalyzed oxidative cleavage of Na+,K+-ATPase to our understanding of structure-function relations. In the presence of ascorbate/H2O2, specific cleavages are catalyzed by the bound metal and because more than one peptide bond close to the metal can be cleaved, this technique reveals proximity of the different cleavage positions within the native structure. Specific cleavages are catalyzed by Fe2+ bound at the cytoplasmic surface or by complexes of ATP-Fe2+, which directs the Fe2+ to the normal ATP-Mg2+ site. Fe2+- and ATP-Fe2+-catalyzed cleavages reveal large conformation-dependent changes in interactions between cytoplasmic domains, involving conserved cytoplasmic sequences, and a change of ligation of Mg2+ ions between E1P and E2P, which may be crucial in facilitating hydrolysis of E2P. The pattern of domain interactions in E1 and E2 conformations, and role of Mg2+ ions, may be common to all P-type pumps. Specific cleavages can also be catalyzed by Cu2+ ions, bound at the extracellular surfaces, or a hydrophobic Cu2+-diphenyl phenanthroline (DPP) complex, which directs the Cu2+ to the membrane-water interface. Cu2+ or Cu2+-DPP-catalyzed cleavages are providing information on alpha/beta subunit interactions and spatial organization of transmembrane segments. Transition metal-catalyzed cleavage could be widely used to investigate other P-type pumps and membrane proteins and, especially, ATP binding proteins.

The complex ATP-Fe(2+) serves as a specific affinity cleavage reagent in ATP-Mg(2+) sites of Na,K-ATPase: altered ligation of Fe(2+) (Mg(2+)) ions accompanies the E(1)-->E(2) conformational change

In the presence of ascorbate/H(2)O(2), ATP-Fe(2+) or AMP-PNP-Fe(2+) complexes act as affinity cleavage reagents, mediating selective cleavage of the alpha subunit of Na,K-ATPase at high affinity ATP-Mg(2+) sites. The cleavages reveal contact points of Fe(2+) or Mg(2+) ions. In E(1) and E(1)Na conformations, two major cleavages are detected within the conserved (708)TGDGVNDSPALKK sequence (at V712 and nearby), and one (E(1)Na) or two (E(1)) minor cleavages near V440. In media containing sodium and ATP, Fe(2+) substitutes for Mg(2+) in activating phosphorylation and ATP hydrolysis. In the E(1)P conformation, cleavages are the same as in E(1). Fe(2+) is not bound tightly. By contrast, in the E(2)P conformation, the pattern is different. A major cleavage occurs near the conserved sequence (212)TGES, whereas those in TGDGVNDSPALKK are less prominent. Fe(2+) is bound very tightly. On E(2)P hydrolysis, the Fe(2+) dissociates. The results are consistent with E(1)<-->E(2) conformation-dependent movements of cytoplasmic domains and sites for P(i) and Mg(2+) ions, inferred from previous Fe-cleavage experiments. Furthermore, these concepts fit well with the crystal structure of Ca-ATPase [Toyoshima, C., Nakasako, M., Nomura, H. & Ogawa, H. (2000) Nature (London) 405, 647-655]. Altered ligation of Mg(2+) ions in E(2)P may be crucial in facilitating nucleophilic attack of water on the OP bond. Mg(2+) ions may play a similar role in all P-type pumps. As affinity cleavage reagents, ATP-Fe(2+) or other nucleotide-Fe(2+) complexes could be widely used to investigate nucleotide binding proteins.

Occlusion of cobalt ions within the phosphorylated forms of the Na+-K+ pump isolated from dog kidney

1. Co2+ ions can replace Mg2+ ions as co-factors for the Na+-K+ pump purified from dog kidney outer medulla. The evidence comes from (a) measurement of ouabain-sensitive Na+,K+-ATPase activity, (b) measurement of ATP-dependent 22Na uptake catalysed by the Na+-K+ pump reconstituted into phospholipid vesicles, (c) measurements of phosphorylation of the Na+-K+ pump either in the presence of ATP and sodium ions or in the presence of inorganic phosphate, and (d) measurement of occlusion of rubidium ions through the route involving phosphorylation and dephosphorylation. 2. Purified Na+,K+-ATPase incubated in the presence of ATP, Na+ ions and [60Co]CoCl2, can carry occluded Co2+ ions through a cation-exchange resin. The enzyme fails to occlude the divalent cation (i) if ADP replaces ATP, (ii) if the enzyme is heat-inactivated, (iii) if the enzyme is inactivated by treatment with fluorescein isothiocyanate, (iv) if K+ replaces Na+ in the incubation medium, (v) if Na+ ions are omitted, and (vi) if Mg2+ ions are added in a sufficient concentration. 3. The amount of occluded Co2+ ions is unaffected by pre-treatment of the Na+,K+-ATPase with oligomycin, which stabilizes the phosphoenzyme in the E1P form. 4. The addition of K+ ions to Na+,K+-ATPase that has been phosphorylated in the presence of ATP, Na+ ions and [60Co]CoCl2 releases the occluded Co2+ ions from the enzyme. Under those conditions, K+ ions accelerate the hydrolysis of the phosphoenzyme, and become occluded in the resulting dephosphoenzyme. 5. The stoichiometry of Co2+ ion occlusion is about one occluded Co2+ ion per phosphorylation site. 6. These results support the hypothesis that, in the normal working of the Na+-K+ pump, Mg2+ ions are trapped in the phosphorylated forms of the enzyme, and are released by a K+-dependent dephosphorylation reaction.

Interaction between the basolateral K+ and apical Na+ conductances in Necturus urinary bladder

Experimental modulation of the apical membrane Na+ conductance or basolateral membrane Na+-K+ pump activity has been shown to result in parallel changes in the basolateral K+ conductance in a number of epithelia. To determine whether modulation of the basolateral K+ conductance would result in parallel changes in apical Na+ conductance and basolateral pump activity, Necturus urinary bladders stripped of serosal muscle and connective tissue were impaled through their basolateral membranes with microelectrodes in experiments that allowed rapid serosal solution changes. Exposure of the basolateral membrane to the K+ channel blockers Ba2+ (0.5 mM/liter), Cs+ (10 mM/liter), or Rb+ (10 mM/liter) increased the basolateral resistance (Rb) by greater than 75% in each case. The increases in Rb were accompanied simultaneously by significant increases in apical resistance (Ra) of greater than 20% and decreases in transepithelial Na+ transport. The increases in Ra, measured as slope resistances, cannot be attributed to nonlinearity of the I-V relationship of the apical membrane, since the measured cell membrane potentials with the K+ channel blockers present were not significantly different from those resulting from increasing serosal K+, a maneuver that did not affect Ra. Thus, blocking the K+ conductance causes a reduction in net Na+ transport by reducing K+ exit from the cell and simultaneously reducing Na+ entry into the cell. Close correlations between the calculated short-circuit current and the apical and basolateral conductances were preserved after the basolateral K+ conductance pathways had been blocked. Thus, the interaction between the basolateral and apical conductances revealed by blocking the basolateral K+ channels is part of a network of feedback relationships that normally serves to maintain cellular homeostasis during changes in the rate of transepithelial Na+ transport.

The mechanism of acetylcholine release from parasympathetic nerves

1. The output of acetylcholine from the plexus of the guinea-pig ileum longitudinal strip has been used to study the mechanism of acetylcholine release. From the effects of hexamethonium and tetrodotoxin, it was inferred that 60% of the normal resting output is due to propagated activity in the plexus, and 40% to spontaneous release. Tetrodotoxin virtually abolishes the increase in output in response to electrical stimulation.2. Resting acetylcholine output is increased when the bathing medium is changed in the following ways:(a) sodium replacement by sucrose, trometamol or lithium;(b) addition of ouabain or p-hydroxymercuribenzoate (PHMB), or withdrawal of potassium;(c) the combination of PHMB and partial sodium replacement;(d) addition of potassium; this increase in output becomes greater in the absence of sodium.3. The resting output is virtually abolished by calcium withdrawal, and is restored by barium substitution for calcium. It is also reduced by raising the magnesium concentration.4. The enhanced resting output in response to sodium withdrawal also occurs in the absence of calcium.5. Cooling to 5 degrees C greatly reduces both the resting output and the output in response to raised potassium concentration or to electrical stimulation.6. The increase in resting output due to potassium excess is slight up to 25 mM [K(+)](o), but increases thereafter with about the fourth power of the potassium concentration; it is resistant to tetrodotoxin.7. Synthesis of acetylcholine by the longitudinal strip is increased when output is enhanced by electrical stimulation, by potassium excess or by addition of barium, so that the acetylcholine content of the strip is maintained approximately normal. Synthesis is reduced, in relation to output, by potassium lack or by treatment with ouabain, and is virtually abolished by sodium withdrawal.8. The theory is discussed that acetylcholine release depends on inhibition of the activity of a (Na(+) + K(+) + Mg(2+))-activated ATPase at the axonal membrane.

Active calcium and strontium transport in human erythrocyte ghosts

Both calcium and strontium could be transported actively from erythrocytes if adenosine triphosphate, guanosine triphosphate, or inosine triphosphate were included in the hypotonic medium used to infuse calcium or strontium into the cells. Acetyl phosphate and pyrophosphate were not energy sources for the transport of either ion. Neither calcium nor strontium transport was accompanied by magnesium exchange, and the addition of Mg(++) to the reaction medium in a final concentration of 3.0 mmoles/liter did not promote the transport of either ion. In the absence of nucleotide triphosphates, the addition of 1.5 mmoles/liter of Sr(++) to the reaction solution did not bring about active calcium transport and similarly 1.5 mmoles/liter of Ca(++) did not bring about active strontium transport. The inclusion of 1.5 mmoles/liter of Ca(++) or Sr(++) in the reaction medium did not interfere with the transport of the other ion when the erythrocytes were infused with adenosine triphosphate.