Vanadyl (IV) and vanadate (V) binding to selected endogenous phosphate, carboxyl, and amino ligands; calculations of cellular vanadium species distribution.

Vanadium enters cells as vanadate (V) where it is reduced to vanadyl (IV), VO2+. Vanadate species at plasma pH, H2VO4-, and HVO4(2-) are referred to as VO3-. To gain an insight into the subcellular vanadium distribution we measured the binding of VO3- and VO2+ to extra- and intracellular ligands, and calculated free and bound fractions of these ions for expected in vivo conditions. The association constants (K) were determined by the pH shift caused by an addition of VOSO4 or NaVO3 to individual ligand solutions at 20 degrees C and a pH equal to the pK of the reactive groups. The pk's for binding of VO2+ were ATP, 5.9; ADP, 5.5; AMP, 5.1; Pi 4.3; creatine phosphate (CP), 3.6; glutamic acid, 3.4; aspartic acid, 3.1; human serum albumin, 3.1; glutathione, 2.7; ascorbic acid, 3.3; citric acid, 4.0. The pk of VO3- and human serum albumin was 3.3 and of that VO3- and glutathione was 4.2. VO3- did not bind to ATP, even via Mg2+ or Ca2+ bridges. We calculated that in cells approximately 1% of total VO2+ is unbound, which is 10(-10)-10(-9) M since published values for total vanadium (mainly VO2+) concentrations in tissues are on the order of 10(-8)-10(-7) M. Free VO2+ may be even less because of binding to additional ligands not considered and due to spontaneous hydrolysis to VOOH+ and VO(OH)2(2+) at intracellular pH. The binding of VO2+ to each ligand was corrected for presence of multiple ligands and competition by H+, K+, and Mg2+. In cells with no CP, up to 70% of VO2+ is bound to phosphates and up to 29% to proteins; in cells with 30 mM CP (as in muscle), approximately 95% is bound to phosphates (CP binds up to 61% of total VO2+) and approximately 4% to proteins; in cells with 2 mM ascorbic acid (as in brain), the vitamin binds approximately 3% of total VO2+. These binding values apply for the total VO2+ concentration range of 10(-8)-10(-5) M. The intracellular binding and a reducing environment protect the freshly reduced VO2+ from oxidation to VO3- that would otherwise occur at neutral pH. This strong affinity of VO2+ primarily for phosphates also explains the mechanism for the intracellular accumulation of vanadium which is a factor in previously observed transport of VO3- into cells.(ABSTRACT TRUNCATED AT 400 WORDS)