Published in:
European Journal of Biochemistry, 25 (1972) 3, Seite 447-454
Language:
English
DOI:
10.1111/j.1432-1033.1972.tb01714.x
ISSN:
0014-2956;
1432-1033
Origination:
Footnote:
Description:
A method was developed which allowed the measurement of sugar uptake into red cells after only 4 sec.The uptake of [14C]glucose from a saline‐glucose medium was followed at two temperatures (0° and 20°C) and at three different trans‐concentrations of non labelled glucose inside the cells: at equilibrium distribution with [Str] = [Scis], for non‐exchange with [Str] = zero at time zero, and for exchange with [Str] = 34 to 35 mM at time zero.For these conditions, we found linear plots against time, which enabled us to determine the initial velocity for the uptake of label, i.e. the unidirectional influx.Influx depended on the widely varying cis‐concentration of glucose in the medium in the manner of a simple saturation‐relationship. The parameters Jmax and Km, determined from a reciprocal plot, were different for the three chosen [Str]‐conditions. Some of these parameters were comparable to values of other papers, determined by measuring the efflux of glucose from red cells.The results were compared with predictions derived from two models of a mobile carrier: the symmetrical model of Levine, Oxender and Stein [1] and the asymmetrical, but passive model of Geck [2]. The relationship between glucose uptake plotted against time and influx plotted against cis‐concentration corresponded to both models. Some, but not all, ratios between the measured parameters matched the predictions of the symmetrical model, whereas all ratios were compatible with the asymmetrical model.From both models, the translocation resistance comes out to be much greater for the free carrier than for the glucose‐carrier complex: 10 to 30 fold at 20°C and circa 200 fold at 0°C. Hence, the mobility of the free carrier appears to be very much reduced in the cold.