Facilitated synthesis of proteins containing modified dipeptides

Biological Regulation Studied in Vitro and in Cellulo with Modified Proteins

ConspectusProteins and peptides occur ubiquitously in organisms and play key functional roles, as structural elements and catalysts. Their major natural source is ribosomal synthesis, which produces polypeptides from 20 amino acid building blocks. Peptides containing noncanonical amino acids have long been prepared by chemical synthesis, which has provided a wealth of physiologically active compounds. Comparatively, preparing modified proteins has been more challenging. Site-directed mutagenesis provided an important advance but was initially limited to canonical amino acids. New techniques for tRNA activation with noncanonical amino acids subsequently increased the scope of site-directed mutagenesis.Our report in 2012 demonstrated that modification of bacterial ribosomes at key positions enabled the selection of ribosomes capable of introducing β-amino acids into proteins in vitro. The generality of the selection procedure was tested further. Ribosomes capable of incorporating dipeptides, conformationally constrained dipeptides, dipeptidometics with embedded fluorophores, contiguous nucleobase amino acids, and phosphorylated amino acids were successfully identified.In this Account, we focus on the application of the new technology to dramatically alter protein structure in ways that enable new strategies for understanding and altering protein function. To illustrate the robustness of the technology we have provided examples studied in vitro and in cellulo. The first category involves the introduction of nucleobase amino acids into proteins in support of specific interactions with RNA and DNA. The energetic differences between potential protein-nucleic acid complexes formed from two binding partners are often quite small. It seems logical to think that selective binding can be achieved by using a nucleobase moiety in each of the binding partners by utilizing known interactions between nucleic acid bases (located in the protein and nucleic acid) to achieve energetically favorable interactions. We do so both in vitro and in cellulo. A second focus has involved the design of small fluorescent probes not much larger than amino acids that are genetically encodable and which can be incorporated during protein biosynthesis, serving as detectable probes of protein trafficking and interaction with other macromolecules. We provide an in vitro example of strongly fluorescent tryptophan analogues positioned at single sites within dihydrofolate reductase, permitting selective communication with a FRET acceptor at a known position, even in the presence of several tryptophans. An oxazole amino acid, weakly fluorescent in aqueous solution, fluoresced more strongly following incorporation into MreB, a scaffold protein produced in cellulo. Finally, we describe the introduction of a single phosphorylated tyrosine into the p50 subunit of NF-κB. When present at either of two key positions, the resulting NF-κB significantly enhanced binding in vitro to the promoter DNA as well as subsequent mRNA transcription of its client protein CD40 in cellulo. In a separate expression in activated Jurkat cells, an increased production of CD40 protein was observed.

Enhancement of N-Methyl Amino Acid Incorporation into Proteins and Peptides Using Modified Bacterial Ribosomes and Elongation Factor P

N-Methylated amino acids are constituents of natural bioactive peptides and proteins. Nα-methylated amino acids appear abundantly in natural cyclic peptides, likely due to their constraint of peptide conformation and contribution to peptide stability. Peptides containing Nα-methylated amino acids have long been prepared by chemical synthesis. While such natural peptides are not produced ribosomally, recent ribosomal strategies have afforded Nα-methylated peptides. Presently, we define new strategies for the ribosomal incorporation of Nα-methylated amino acids into peptides and proteins. First, we identify modified ribosomes capable of facilitating the incorporation of six N-methylated amino acids into antibacterial scorpion peptide IsCT. Also synthesized analogously was a protein domain (RRM1) from hnRNP LL; improved yields were observed for nearly all tested N-methylated amino acids. Computational modeling of the ribosomal assembly illustrated how the distortion imposed by N-methylation could be compensated by altering the nucleotides in key 23S rRNA positions. Finally, it is known that incorporation of multiple prolines (an N-alkylated amino acid) ribosomally can be facilitated by bacterial elongation factor P. We report that supplementing endogenous EF-P during IsCT peptide and RRM1 protein synthesis gave improved yields for most of the N-methylated amino acids studied.

Elongation Factor P Modulates the Incorporation of Structurally Diverse Noncanonical Amino Acids into Escherichia coli Dihydrofolate Reductase

The introduction of noncanonical amino acids into proteins and peptides has been of great interest for many years and has facilitated the detailed study of peptide/protein structure and mechanism. In addition to numerous nonproteinogenic α-l-amino acids, bacterial ribosome modification has provided the wherewithal to enable the synthesis of peptides and proteins with a much greater range of structural diversity, as has the use of endogenous bacterial proteins in reconstituted protein synthesizing systems. In a recent report, elongation factor P (EF-P), putatively essential for enabling the incorporation of contiguous proline residues into proteins, was shown to facilitate the introduction of an N-methylated amino acid in addition to proline. This finding prompted us to investigate the properties of this protein factor with a broad variety of structurally diverse amino acid analogues using an optimized suppressor tRNAPro that we designed. While these analogues can generally be incorporated into proteins only in systems containing modified ribosomes specifically selected for their incorporation, we found that EF-P could significantly enhance their incorporation into model protein dihydrofolate reductase using wild-type ribosomes. Plausibly, the increased yields observed in the presence of structurally diverse amino acid analogues may result from the formation of a stabilized ribosomal complex in the presence of EF-P that provides more favorable conditions for peptide bond formation. This finding should enable the facile incorporation of a much broader structural variety of amino acid analogues into proteins and peptides using native ribosomes.

Expansion of the Genetic Code Through the Use of Modified Bacterial Ribosomes

Biological protein synthesis is mediated by the ribosome, and employs ~20 proteinogenic amino acids as building blocks. Through the use of misacylated tRNAs, presently accessible by any of several strategies, it is now possible to employ in vitro and in vivo protein biosynthesis to elaborate proteins containing a much larger variety of amino acid building blocks. However, the incorporation of this broader variety of amino acids is limited to those species utilized by the ribosome. As a consequence, virtually all of the substrates utilized over time have been L-α-amino acids. In recent years, a variety of structural and biochemical studies have provided important insights into those regions of the 23S ribosomal RNA that are involved in peptide bond formation. Subsequent experiments, involving the randomization of key regions of 23S rRNA required for peptide bond formation, have afforded libraries of E. coli harboring plasmids with the rrnB gene modified in the key regions. Selections based on the use of modified puromycin derivatives with altered amino acids then identified clones uniquely sensitive to individual puromycin derivatives. These clones often recognized misacylated tRNAs containing altered amino acids similar to those in the modified puromycins, and incorporated the amino acid analogues into proteins. In this fashion, it has been possible to realize the synthesis of proteins containing D-amino acids, β-amino acids, phosphorylated amino acids, as well as long chain and cyclic amino acids in which the nucleophilic amino group is not in the α-position. Of special interest have been dipeptides and dipeptidomimetics of diverse utility.

Genome Expansion by tRNA +1 Frameshifting at Quadruplet Codons

Inducing tRNA +1 frameshifting to read a quadruplet codon has the potential to incorporate a non-canonical amino acid (ncAA) into the polypeptide chain. While this strategy is attractive for genome expansion in biotechnology and bioengineering endeavors, improving the yield is hampered by a lack of understanding of where the shift can occur in an elongation cycle of protein synthesis. Lacking a clear answer to this question, current efforts have focused on designing +1-frameshifting tRNAs with an extra nucleotide inserted to the anticodon loop for pairing with a quadruplet codon in the aminoacyl-tRNA binding (A) site of the ribosome. However, the designed and evolved +1-frameshifting tRNAs vary broadly in achieving successful genome expansion. Here we summarize recent work on +1-frameshifting tRNAs. We suggest that, rather than engineering the quadruplet anticodon-codon pairing scheme at the ribosome A site, efforts should be made to engineer the pairing scheme at steps after the A site, including the step of the subsequent translocation and the step that stabilizes the pairing scheme in the +1-frame in the peptidyl-tRNA binding (P) site.