Abstract
The first cells probably possessed rudimentary metabolic networks, built using a handful of multifunctional enzymes. The promiscuous activities of modern enzymes are often assumed to be relics of this primordial era; however, by definition these activities are no longer physiological. There are many fewer examples of enzymes using a single active site to catalyze multiple physiologically-relevant reactions. Previously, we characterized the promiscuous alanine racemase (ALR) activity of Escherichia coli cystathionine β-lyase (CBL). Now we have discovered that several bacteria with reduced genomes lack alr, but contain metC (encoding CBL). We characterized the CBL enzymes from three of these: Pelagibacter ubique, the Wolbachia endosymbiont of Drosophila melanogaster (wMel) and Thermotoga maritima. Each is a multifunctional CBL/ALR. However, we also show that CBL activity is no longer required in these bacteria. Instead, the wMel and T. maritima enzymes are physiologically bi-functional alanine/glutamate racemases. They are not highly active, but they are clearly sufficient. Given the abundance of the microorganisms using them, we suggest that much of the planet's biochemistry is carried out by enzymes that are quite different from the highly-active exemplars usually found in textbooks. Instead, primordial-like enzymes may be an essential part of the adaptive strategy associated with streamlining.
Highlights
Over 40 years ago, Ycas and Jensen independently proposed similar scenarios for the evolution of metabolic pathways (Ycas, 1974; Jensen, 1976)
The presence or absence of alr (COG0787) and metC/metB (COG0626) in each genome was visualized on a tree that was based on taxonomy, in which the branches of taxa sharing the same pattern were collapsed (Fig. 2)
We discovered that the extant bacteria P. ubique, T. maritima and the Wolbachia endosymbiont of D. melanogaster have multifunctional cystathionine b-lyase (CBL) enzymes
Summary
Over 40 years ago, Ycas and Jensen independently proposed similar scenarios for the evolution of metabolic pathways (Ycas, 1974; Jensen, 1976) They envisaged primordial organisms with small genomes and, small numbers of protein-encoding genes. Each author reached the conclusion that primordial enzymes were likely to have exhibited broad substrate specificities and/ or to have catalyzed classes of related reactions. From this starting point, gene duplication and divergence could give rise to the larger genomes and highly specific enzymes that epitomize modern organisms. They suffer from either studying an activity that is no longer physiologically relevant (i.e., promiscuity), or studying a single enzyme outside of its metabolic context
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