Interactions between multiple functional groups are key to catalysis. Previously, we reported synergistic interactions in catalytic amyloids formed by mixtures of heptameric peptides that lead to significant improvements in esterase activity. Herein, we describe the in‐depth investigation of synergistic interactions within a family of amyloid fibrils, exploring the results of functional group interactions, the effects of chirality and the use of mixed enantiomers within fibrils. Remarkably, we find that synergistic interactions (either positive or negative) are found in the vast majority of binary mixtures of catalytic amyloid‐forming peptides. The productive arrangements of functionalities rapidly identified by mixing different peptides will undoubtedly lead to the development of more active catalysts for a variety of different transformations.
Ribonucleotide reductase (RNR) is an essential enzyme found in all organisms. The function of RNR is to catalyze the conversion of nucleotides to deoxynucleotides. RNRs rely on metallocofactors to oxidize a conserved cysteine in the active site of the enzyme into a thiyl radical, which then initiates nucleotide reduction. The proteins required for MnIII2–Y• cluster formation in class Ib RNRs are NrdF (β-subunit) and NrdI (flavodoxin). An oxidant is channeled from the FMN cofactor in NrdI to the dimanganese center in NrdF, where it oxidizes the dimanganese center and a tyrosyl radical (Y•) is formed. Both Streptococcus sanguinis and Escherichia coli MnII2–NrdF structures have a constriction in the channel immediately above the metal site. In E. coli, the constriction is formed by the side chain of S159, whereas in the S. sanguinis system it involves T158. This serine-to-threonine substitution was investigated using S. sanguinis and Streptococcus pneumoniae class Ib RNRs but it is also present in other pathogenic streptococci. Using stopped-flow kinetics, we investigate the role of this substitution in the mechanism of MnIII2–Y• cluster formation. In addition to different kinetics observed in the studied streptococci, we found that affinity constants of NrdF for MnII and FeII are about 1 µM and the previously reported preference for MnII could not be explained by affinity only.
A computationally designed, allosterically regulated catalyst (CaM M144H) produced by substituting a single residue in calmodulin, a non-enzymatic protein, is capable of efficient and site selective post-translational acylation of lysines in peptides with highly diverse sequences. Calmodulin's binding partners are involved in regulating a large number of cellular processes; this new chemical-biology tool will help to identify them and provide structural insight into their interactions with calmodulin.
The self‐assembly of short peptides into catalytic amyloid‐like nanomaterials has proven to be a powerful tool in both understanding the evolution of early proteins and identifying new catalysts for practically useful chemical reactions. Here we demonstrate that both parallel and antiparallel arrangements of β‐sheets can accommodate metal ions in catalytically productive coordination environments. Moreover, synergistic relationships, identified in catalytic amyloid mixtures, can be captured in macrocyclic and sheet‐loop‐sheet species, that offer faster rates of assembly and provide more complex asymmetric arrangements of functional groups, thus paving the way for future designs of amyloid‐like catalytic proteins. Our findings show how initial catalytic activity in amyloid assemblies can be propagated and improved in more‐complex molecules, providing another link in a complex evolutionary chain between short, potentially abiotically produced peptides and modern‐day enzymes.
Just like a limited set of playing cards can provide many combinations, mixtures of peptides with different amino acids can form various functional materials. Even simple binary mixtures of heptapeptides can synergistically form catalytic amyloids with high (using arginine and glutamine), moderate (using lysine and glutamate), or low (using histidine and tyrosine) hydrolytic activities. More information can be found in the communication by I. V. Korendovych et al.
The cover feature picture shows how a computationally designed allosterically regulated esterase CaM M144H, a derivative of AlleyCatE, can recognize and specifically post‐translationally modify helical domains (highlighted in green) in calmodulin‐binding proteins with an unnatural tag providing structural and functional insight into protein–protein interactions. More information can be found in the communication by O. V. Makhlynets, I. V. Korendovych, et al. on page 1605 in Issue 15, 2018 (DOI: 10.1002/cbic.201800196).
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