How synonymous mutations alter enzyme structure and function over long time scales

Abstract: The specific activity of enzymes can be altered over long time scales in cells by synonymous mutations, which change an mRNA molecule's sequence but not the encoded protein's primary structure. How this happens at the molecular level is unknown. Here, we resolve this issue by applying multiscale modeling to three E. coli enzymes - type III chloramphenicol acetyltransferase, D-alanine-D-alanine ligase B, and dihydrofolate reductase. This modeling involves coarse-grained simulations of protein synthesis and post… Show more

“…Relative to their time-scale of protein folding, these entangled states are not long-lived kinetic traps even at 310 K. Based on the previous coarse-grained simulation results, this is to be expected 1 , as ubiquitin and NTD are atypically small (the median protein length in yeast is 379 residues 15 ). In such very small proteins, entanglements compose a large proportion of the total protein structure present – and hence, it is easier to disentangle as most of the protein structure is misfolded and less stable.…”

“…The misfolded states observed in the aforementioned simulations involved either the gain of a non-native entanglement (i.e., the formation of an entanglement that is not present in the native ensemble, Table S1) or the loss of a native entanglement (i.e., an entanglement present in the native state fails to form, Table S1) [1][2][3] . This newly predicted class of misfolding offers an explanation for the decades old observations that non-functional protein molecules can persist for long-time scales in the presence of chaperones and not rapidly aggregate nor be degraded [7][8][9] .…”

“…Only a small number of mechanisms intrinsic to a protein's primary structure are known to cause monomeric protein misfolding (Table 1). Recently, high-throughput, coarse-grained simulations of protein synthesis and folding of the E. coli proteome have suggested there exists an additional widespread mechanism of misfolding [1][2][3] . Proteins can populate off-pathway misfolded states that involve a change in entanglement 1 .…”

“…The radius of gyration of these states are comparable to the native state (within 5.5%, 5.2%, and 2.4%, on average, respectively, of the native state Ubiquitin, λ-repressor, and 4-Diphosphocytidyl-2-C-Methyl-D-Erythritol Kinase values), indicating the entangled and native states are of similar sizes. These entangled states are estimated to have a solubility similar to the native state (Table S2) according to a model that accounts for surface area chemical properties 1 . This indicates these misfolded states are likely to remain as soluble in solution as the native fold.…”

“…Several mechanisms intrinsic to a protein's primary structure are known to cause monomeric protein misfolding (Table 1). Recently, high-throughput, coarse-grained simulations of protein synthesis and folding of the E. coli proteome have suggested there exists an additional widespread mechanism of misfolding [1][2][3] : proteins can populate off-pathway misfolded states that involve a change in non-covalent lasso entanglements 1,2 . This type of entanglement is defined by the presence of two structural components: a loop formed by a protein backbone segment closed by a non-covalent native contact, and another protein segment that is threaded through and around this loop [4][5][6] in some cases multiple times (Figs.…”

A Newly Identified Class of Protein Misfolding in All-atom Folding Simulations Consistent with Limited Proteolysis Mass Spectrometry

“…Relative to their time-scale of protein folding, these entangled states are not long-lived kinetic traps even at 310 K. Based on the previous coarse-grained simulation results, this is to be expected 1 , as ubiquitin and NTD are atypically small (the median protein length in yeast is 379 residues 15 ). In such very small proteins, entanglements compose a large proportion of the total protein structure present – and hence, it is easier to disentangle as most of the protein structure is misfolded and less stable.…”

“…The misfolded states observed in the aforementioned simulations involved either the gain of a non-native entanglement (i.e., the formation of an entanglement that is not present in the native ensemble, Table S1) or the loss of a native entanglement (i.e., an entanglement present in the native state fails to form, Table S1) [1][2][3] . This newly predicted class of misfolding offers an explanation for the decades old observations that non-functional protein molecules can persist for long-time scales in the presence of chaperones and not rapidly aggregate nor be degraded [7][8][9] .…”

“…Only a small number of mechanisms intrinsic to a protein's primary structure are known to cause monomeric protein misfolding (Table 1). Recently, high-throughput, coarse-grained simulations of protein synthesis and folding of the E. coli proteome have suggested there exists an additional widespread mechanism of misfolding [1][2][3] . Proteins can populate off-pathway misfolded states that involve a change in entanglement 1 .…”

“…The radius of gyration of these states are comparable to the native state (within 5.5%, 5.2%, and 2.4%, on average, respectively, of the native state Ubiquitin, λ-repressor, and 4-Diphosphocytidyl-2-C-Methyl-D-Erythritol Kinase values), indicating the entangled and native states are of similar sizes. These entangled states are estimated to have a solubility similar to the native state (Table S2) according to a model that accounts for surface area chemical properties 1 . This indicates these misfolded states are likely to remain as soluble in solution as the native fold.…”

“…Several mechanisms intrinsic to a protein's primary structure are known to cause monomeric protein misfolding (Table 1). Recently, high-throughput, coarse-grained simulations of protein synthesis and folding of the E. coli proteome have suggested there exists an additional widespread mechanism of misfolding [1][2][3] : proteins can populate off-pathway misfolded states that involve a change in non-covalent lasso entanglements 1,2 . This type of entanglement is defined by the presence of two structural components: a loop formed by a protein backbone segment closed by a non-covalent native contact, and another protein segment that is threaded through and around this loop [4][5][6] in some cases multiple times (Figs.…”

A Newly Identified Class of Protein Misfolding in All-atom Folding Simulations Consistent with Limited Proteolysis Mass Spectrometry

Pulse labeling reveals the tail end of protein folding by proteome profiling

Synonymous Mutations Can Alter Protein Dimerization Through Localized Interface Misfolding Involving Self-entanglements