Abstract
Glyoxalase pathway is the primary route for metabolism of methylglyoxal (MG), a toxic ubiquitous metabolite that affects redox homeostasis. It neutralizes MG using Glyoxalase I and Glyoxalase II (GLYI and GLYII) enzymes in the presence of reduced glutathione. In addition, there also exists a shorter route for the MG detoxification in the form of Glyoxalase III (GLYIII) enzymes, which can convert MG into D-lactate in a single-step without involving glutathione. GLYIII proteins in different systems demonstrate diverse functional capacities and play a vital role in oxidative stress response. To gain insight into their evolutionary patterns, here we studied the evolution of GLYIII enzymes across prokaryotes and eukaryotes, with special emphasis on plants. GLYIII proteins are characterized by the presence of DJ-1_PfpI domains thereby, belonging to the DJ-1_PfpI protein superfamily. Our analysis delineated evolution of double DJ-1_PfpI domains in plant GLYIII. Based on sequence and structural characteristics, plant GLYIII enzymes could be categorized into three different clusters, which followed different evolutionary trajectories. Importantly, GLYIII proteins from monocots and dicots group separately in each cluster and the each of the two domains of these proteins also cluster differentially. Overall, our findings suggested that GLYIII proteins have undergone significant evolutionary changes in plants, which is likely to confer diversity and flexibility in their functions.
Highlights
Glyoxalase (GLY) pathway is well-known for its role in plant stress adaptation as well as in disease conditions in animals
How can the different domain architecture of these proteins be correlated to their diverse functions? These are the few questions that the present study aims to address via an investigation of the evolutionary trajectory of Glyoxalase III (GLYIII) proteins along with deciphering their structural and functional diversity in the plant kingdom
A total of 69 species were selected to cover the entire tree of life, and subsequently, GLYIII proteins from those species were used for further analysis, similar to that done for glyoxalase I (GLYI) proteins [6]
Summary
Glyoxalase (GLY) pathway is well-known for its role in plant stress adaptation as well as in disease conditions in animals. Glyoxalase II (GLYII) act by metabolizing methylglyoxal (MG), an α-ketoaldehyde produced primarily by spontaneous dephosphorylation of triose phosphates [1,2], to a relatively non-toxic compound, D-lactate. The toxicity of MG is attributed to its highly reactive nature towards proteins, lipids, and nucleic acids. Prokaryotes demonstrate the enzyme-catalyzed formation of MG as well, which takes place via the dephosphorylation of dihydroxyacetone phosphate (DHAP) [1,2]. These biomolecular modifications due to reactivity of MG leads to changes in the redox status of the cellular milieu.
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