Preparation of analogues of ATP, ADP and AMP suitable for binding to matrices and the enzymic interconversion of ATP and ADP in solid phase. |
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Authors: | M Lindberg K Mosbach |
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Abstract: | Alkylation of ATP with iodoacetic acid at pH 6.5 yielded 1-carboxymethyl-ATP which, after alkaline rearrangement, gave N-6-carboxymethyl-ATP. Condensation of this analogue with 1,6-diaminohexane in the presence of a water-soluble carbodiimide generated N-6-[(6-aminohexyl)carbamoylmethyl]-ATP in an overall yield of 40% based on the parent nucleotide ATP. The coenzymic activities of both N-6-adenine-substituted derivatives of ATP were tested with three kinases. Both derivatives showed coenzymic function against hexokinase with the "long" derivative having highest activity (95%) relative to unsubstituted ATP. Their activities towards the other two kinases tested was negligible except with the "long" analogue against glycerokinase (20%). The latter ATP analogue, when bound to Sepharose through its terminal amino group, could be dephosphorylated to the corresponding ADP analogue with soluble hexokinase yielding glucose 6-phosphate in an enzymic "solidphase" fashion. The Sepharose-bound ADP formed could subsequently be phosphorylated back to ATP using soluble acetate kinase. Sepharose-ATP preparations were also used in preliminary affinity chromatography studies using citrate synthase. Alkylation of ADP following the above procedure yielded the corresponding ADP analogue, N-6-[(6-aminohexyl)carbamoylmethyl]-ADP in an overall yield of 40%. Alkylation of AMP yielded the corresponding N-6-[(6-aminohexyl)carbamoylmethyl]-AMP in an overall yield of 45%. |
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