Abstract
Escherichia coli malate dehydrogenase (EcMDH) and its eukaryotic counterpart, porcine mitochondrial malate dehydrogenase (PmMDH), are highly homologous proteins with significant sequence identity (60%) and virtually identical native structural folds. Despite this homology, EcMDH folds rapidly and efficiently in vitro and does not seem to interact with GroE chaperonins at physiological temperatures (37 degrees C), whereas PmMDH folds much slower than EcMDH and requires these chaperonins to fold to the native state at 37 degrees C. Double jump experiments indicate that the slow folding behavior of PmMDH is not limited by proline isomerization. Although the folding enhancer glycerol (<5 m) does not alter the renaturation kinetics of EcMDH, it dramatically accelerates the spontaneous renaturation of PmMDH at all temperatures tested. Kinetic analysis of PmMDH renaturation with increasing glycerol concentrations suggests that this osmolyte increases the on-pathway kinetics of the monomer folding to assembly-competent forms. Other osmolytes such as trimethylamine N-oxide, sucrose, and betaine also reactivate PmMDH at nonpermissive temperatures (37 degrees C). Glycerol jump experiments with preformed GroEL.PmMDH complexes indicate that the shift between stringent (requires ATP and GroES) and relaxed (only requires ATP) complex conformations is rapid (<3-5 s). The similarity in irreversible misfolding kinetics of PmMDH measured with glycerol or the activated chaperonin complex (GroEL.GroES.ATP) suggests that these folding aids may influence the same step in the PmMDH folding reaction. Moreover, the interactions between glycerol-induced PmMDH folding intermediates and GroEL.GroES.ATP are diminished. Our results support the notion that the protein folding kinetics of sequentially and structurally homologous proteins, rather than the structural fold, dictates the GroE chaperonin requirement.
Highlights
Escherichia coli malate dehydrogenase (EcMDH) and its eukaryotic counterpart, porcine mitochondrial malate dehydrogenase (PmMDH), are highly homologous proteins with significant sequence identity (60%) and virtually identical native structural folds
The similarity in irreversible misfolding kinetics of PmMDH measured with glycerol or the activated chaperonin complex (GroEL1⁄7GroES1⁄7ATP) suggests that these folding aids may influence the same step in the PmMDH folding reaction
PmMDH and EcMDH are highly similar with respect to sequence and structure (ϳ60% sequence identity, ϳ80% sequence similarity), we find no evidence that EcMDH binds to or even interacts with the activated chaperonin complex (GroEL1⁄7GroES1⁄7ATP)
Summary
Escherichia coli malate dehydrogenase (EcMDH) and its eukaryotic counterpart, porcine mitochondrial malate dehydrogenase (PmMDH), are highly homologous proteins with significant sequence identity (60%) and virtually identical native structural folds. In an effort to explain the origins of these differences, Clarke and co-workers [4] have compared the chaperonin requirements for the structurally homologous cytoplasmic and mitochondrial malate dehydrogenases They have found that the increase in chaperonin requirements of the mitochondrial form is correlated with an increase in its global hydrophobicity. Frieden and co-workers [6], on the other hand, have suggested that the differences in the chaperonin interactions for structurally homologous murine and Escherichia coli dihydrofolate reductases (DHFR) may be the result of additional extensions of omega loops present on the murine DHFR These correlations have been proposed to explain the variability in chaperonin requirements for folding isozymes, none of the correlations is generally applicable. The role that specific folding motifs play in dictating interactions between mammalian DHFR and the chaperonin has been questioned recently [8]
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