Lactate and malate dehydrogenases (LDH and MDH) are homologous, core metabolic enzymes common to nearly all living organisms. LDHs have evolved convergently from MDHs at least four times, achieving altered substrate specificity by a different mechanism each time. For instance, the LDH of anaerobic trichomonad parasites recently evolved independently from an ancestral trichomonad MDH by gene duplication. LDH plays a central role in trichomonad metabolism by catalyzing the reduction of pyruvate to lactate, thereby regenerating the NAD+ required for glycolysis. Using ancestral reconstruction methods, we identified the biochemical and evolutionary mechanisms responsible for this convergent event. The last common ancestor of these enzymes was a highly specific MDH, similar to modern trichomonad MDHs. In contrast, the LDH lineage evolved promiscuous activity by relaxing specificity in a gradual process of neofunctionalization involving one highly detrimental substitution at the “specificity residue” (R91L) and many additional mutations of small effect. L91 has different functional consequences in LDHs and in MDHs, indicating a prominent role for epistasis. Crystal structures of modern‐day and ancestral enzymes show that the evolution of substrate specificity paralleled structural changes in dimerization and α‐helix orientation. The relatively small “specificity residue” of the trichomonad LDHs can accommodate a range of substrate sizes and may permit solvent to access the active site, both of which promote substrate promiscuity. The trichomonad LDHs present a multi‐faceted counterpoint to the independent evolution of LDHs in other organisms and illustrate the diverse mechanisms by which protein function, structure, and stability coevolve.
The malarial pathogen Plasmodium falciparum (Pf) is a member of the Apicomplexa, which independently evolved a highly specific lactate dehydrogenase (LDH) from an ancestral malate dehydrogenase (MDH) via a five-residue insertion in a key active site loop. Pf LDH is widely considered an attractive drug target because of its unique active site. The conservation of the apicomplexan loop suggests that a precise insertion sequence was required for the evolution of LDH specificity. Aside from a single critical tryptophan, W107f, the functional and structural roles of residues in the loop are currently unknown. Here we show that the loop is remarkably robust to mutation, as activity is resilient to radical perturbations of both loop identity and length. Thus, alternative insertions could have evolved LDH specificity as long as they contained a tryptophan in the proper location. Pf LDH likely has great potential to develop resistance to drugs designed to target its distinctive active site loop.
The malarial pathogen Plasmodium falciparum (Pf) is a member of the Apicomplexa, which independently evolved a highly specific lactate dehydrogenase (LDH) from an ancestral malate dehydrogenase (MDH) via a five-residue insertion in a key active site loop. PfLDH is widely considered an attractive drug target due to its unique active site. Apicomplexan loop conservation suggests that a particular insertion sequence was required to evolve LDH specificity, and we previously showed (Boucher 2014) that a tryptophan in the insertion, W107f, is essential for activity and specificity. However, the roles of other residues in the loop are currently unknown. Here we show that PfLDH activity is remarkably resilient to radical perturbations of both loop identity and length. Thus, alternative insertions could have evolved LDH specificity as long as they contained a tryptophan in the proper location. PfLDH therefore has high potential to develop resistance to drugs that target its distinctive active site.
The homologous enzymes lactate and malate dehydrogenase (L/MDH) are structurally similar but are specific for different substrates. LDH vs MDH specificity is canonically governed by the identity of a single "specificity residue" at position 102. However, LDH function has convergently evolved from a specific MDH at least four times, and the catalytic role of residue 102 is not conserved between different phyla. The apicomplexa are a phylum of obligate, intracellular eukaryotic parasites responsible for wide-spread disease such as Plasmodium falciparum (malaria), Cryptosporidium parvum (cryptosporidiosis), Toxoplasma gondii (toxoplasmosis), and Eimeria maxima (eimeriosis). The apicomplexan LDH evolved via a five-residue insertion that produced a novel specificity residue, W107f. The commonly accepted mechanism of LDH specificity involves charge balance and steric occlusion, but our data shows that the general mechanism of apicomplexan LDHs does not use W107f as a steric block. Only Plasmodium LDHs evolved substantial steric specificity, making them exceptional among Apicomplexa. Strong protein epistasis constrained this evolution, making it difficult to revert to ancestral phenotypes. Here, we use ancestral sequence reconstruction (ASR), steady-state kinetics, and x-ray crystallography to characterize apicomplexan LDHs which challenge current assumptions about the evolution of L/MDH activity. We demonstrate the unique specificity of Plasmodium LDHs and identify the active site residues controlling their substrate recognition. The extraordinarily high specificity of Plasmodium LDHs presents difficulties for small-molecule inhibitor development, and successful drugs against Plasmodium LDH may not be efficacious against other Apicomplexa LDHs and their diseases.
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