Abstract

The first reaction in protein biosynthesis has been presumed to be the interaction of ATP, amino acid, and enzyme (amino acid-activating enzyme, aminoacyl transfer RNA ligase, tRNA synthetase) to form an enzyme-bound aminoacyl adenylic anhydride. Such aminoacyl anhydrides could react forward with hydroxylamine or with tRNA or backward with [32P]-PPi. Experiments, primarily involving inhibitors, cast serious doubt on the existence of such a common intermediate in the enzyme-catalyzed formation of amino acid hydroxamate or [32P]-ATP from amino acid, ATP, and hydroxylamine, or [32P]-PPi, respectively. Studies with several enzymes indicate the probability of a general base-stimulated concerted reaction in which amino acid hydroxamate, AMP, and PPi are formed with no discrete intermediates. The esterification of tRNA resembles hydroxamate formation more than it resembles ATP-PPi exchange, strengthening the argument that the physiologically significant reaction does not involve an enzyme-bound aminoacyl adenylate. When tRNA is esterified in the absence of other bases, it is probable that one of the terminal ribose hydroxyls serves as a general base while the other is being acylated.