. Electrolytes in biological systems, incorporating papers presented at a symposium at the Marine Biological Laboratory in Woods Hole, Massachusetts, on September 8, 1954 . 60 uj Fjg. 3. The uptake of Mn^'* by K yeast cells as a function of Mn++ 40 = concentration. 2 4 6 8 10 12 14 EQUILIBRIUM CONCENTRATION OF Mn** IN M/L x 10^ pecially with Mn^"* (54). As with 1702+^, the binding of Ca++ and Mn++ was reversible and reached equilibrium rapidly. Within 2 minutes, the earliest observation, the reaction was essentially complete (fig. 2). Mn++ is not bound by the cell in such a stable configu
. Electrolytes in biological systems, incorporating papers presented at a symposium at the Marine Biological Laboratory in Woods Hole, Massachusetts, on September 8, 1954 . 60 uj Fjg. 3. The uptake of Mn^'* by K yeast cells as a function of Mn++ 40 = concentration. 2 4 6 8 10 12 14 EQUILIBRIUM CONCENTRATION OF Mn** IN M/L x 10^ pecially with Mn^"* (54). As with 1702+^, the binding of Ca++ and Mn++ was reversible and reached equilibrium rapidly. Within 2 minutes, the earliest observation, the reaction was essentially complete (fig. 2). Mn++ is not bound by the cell in such a stable configuration as UOo"*^. For this reason, the curve representing Mn++ uptake as a function of Mn++ concentration does not rise so sharply to an asymptote (fig. 3). As with 1102"^"'', the binding of Mn++ can be expressed by a simple relationship: ^ _ (M)(Y) 0)
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Keywords: ., bookcentury1900, booksubjectelectrolytes, booksubjectphysiologyc
