A cycle of deprotonation and reprotonation energizing amino-acid transport?

Christensen, Halvor N.; Handlogten, Mary E.

doi:10.1073/pnas.72.1.23

Cited by 20 publications

(1 citation statement)

References 22 publications

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“…Some diamino acids with pK~ < 8.5 show paradoxical intensity of transport by two neutral systems [5,6]. 2,4-Diaminobutyric acid and thialysine show extreme positions for their rate responses to Na + (Figs.…”

Section: Structural Effects That Allow Both Na + and LI + To Be Highlmentioning

confidence: 99%

Na+/L+ selectivity in transport systemA: Effects of substrate structure

Christensen

Handlogten

1977

J. Membrain Biol.

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Summary. The effect of amino acid structure on the selectivity between Na and Li as co-substrates for transport System A in the Ehrlich cell has been explored to localize relative binding positions. By various tests the relative effectiveness of the two cations varies over fivefold. Changes in structure of the amino acid that lower its response to Na tend to decrease its selectivity for Na over Li, but with many exceptions. The higher the Li level required to half-maximize amino acid entry, the slower tends to be the entry attainable for both Li and amino acid. Our attention fell on strong departures from these trends. An atypically fast uptake is produced by Li in the presence of a second amino group pK~ <8.5, in exceptional association with the known fast uptake in Na. The hydroxyl group of serine yields exceptionally strong uptake, whereas hydroxyl groups in restrained orientation (as in threonine and hydroxyprolines) sharply limit co-substrate interaction. Despite the absence of a sidechain, glycine shows unexceptional relative co-substrate responses. A sidechain in the a 2 position, as in D-alanine, lowers tolerance for both ions, an aberration largely corrected by the insertion of a second (a~) methyl group, and surprisingly, even by an N-methyl group. For L-alanine, an N-methyl group has in contrast unfavorable effects on co-substrate interaction. These factors point to disturbance by the a 2 methyl group of the position taken by the amino acid at the site, largely rectifiable by balancing effects of a second methyl group. They also point to a position of the alkali ion quite close to the a-carbon and far from the position taken in System ASC.Addition of an ethylene bridge between the a-methyl groups of a(methylamino)-isobutyric acid leads to the strongest discrimination seen against Li § relative to Na § suggesting through crowding of the area that the alkali ion adjoins the three methyl groups of this analog.Only one of the Na +-dependent transport systems has so far revealed the spatial position taken by the sodium ion with respect to the substrate molecule at the receptor site. That system, ASC, differs from System A in its intolerance for an N-methyl group on the substrate, for branching of the sidechain, and for Li + as a substitute for Na + as co-substrate, It functions-in all the nucleated or reticulated red blood cells studied so far, as well as in the Ehrlich cell [2,9,11,15,18,19,20], in both erythroblastic and myeloblastic leukemia cells [Wise, personal communica-

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Section: Structural Effects That Allow Both Na + and LI + To Be Highlmentioning

confidence: 99%

Na+/L+ selectivity in transport systemA: Effects of substrate structure

Christensen

Handlogten

1977

J. Membrain Biol.

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Exploiting Amino acid Structure to Learn About Membrane Transport

Christensen¹

1979

Advances in Enzymology - And Related Areas of Molecular Biology

109

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Effect of H⁺ on the kinetics of Na⁺‐dependent amino acid transport in ehrlich ascites tumor cells: Evidence for H⁺ as an alternative substrate

Smith

Robinson

1981

Journal Cellular Physiology

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The effects of H+ on the kinetics of alpha-aminoisobutyric acid (AIB) influx in Ehrlich ascites tumor cells have been investigated at different external Na+ concentrations. Elevation of [H+] in the presence of both high (154 mEq/l) and low (10 mEq/l) external Na+ leads to decreases in the maximum influx (Jmax) and increases in the apparent Michaelis-Menten constant (Km) for influx of AIB. In the virtual absence of external Na+ (0.96 +/- 0.04 mEq/l), alterations in [H+] are without measurable effect on AIB flux. Furthermore, addition of AIB (10 mM) to cell suspensions (pH 5.90) stimulates H+ uptake by the cells in either the presence or absence of Na+. The data are consistent with two kinetic models for Na+-dependent amino acid transport: an order bireactant (Na+-binding necessary before AIB binding) system or a random bireactant system. Both models require that H+ serve as an alternative substrate for Na+. The consistency of the models was tested by fit to data from the present study (not used to evaluate the kinetic parameters) and by prediction of the pH dependence of Na+-dependent amino acid transport compared to earlier studies.

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A cycle of deprotonation and reprotonation energizing amino-acid transport?

Cited by 20 publications

References 22 publications

Na+/L+ selectivity in transport systemA: Effects of substrate structure

Na+/L+ selectivity in transport systemA: Effects of substrate structure

Exploiting Amino acid Structure to Learn About Membrane Transport

Effect of H⁺ on the kinetics of Na⁺‐dependent amino acid transport in ehrlich ascites tumor cells: Evidence for H⁺ as an alternative substrate

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A cycle of deprotonation and reprotonation energizing amino-acid transport?

Cited by 20 publications

References 22 publications

Na+/L+ selectivity in transport systemA: Effects of substrate structure

Na+/L+ selectivity in transport systemA: Effects of substrate structure

Exploiting Amino acid Structure to Learn About Membrane Transport

Effect of H+ on the kinetics of Na+‐dependent amino acid transport in ehrlich ascites tumor cells: Evidence for H+ as an alternative substrate

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Product

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Effect of H⁺ on the kinetics of Na⁺‐dependent amino acid transport in ehrlich ascites tumor cells: Evidence for H⁺ as an alternative substrate