Project description:Density functional theory (DFT) calculations and experiments in tandem led to discoveries of new reactivities and selectivities involving bioorthogonal sydnone cycloadditions. Dibenzocyclooctyne derivatives (DIBAC and BARAC) were identified to be especially reactive dipolarophiles, which undergo the (3 + 2) cycloadditions with N-phenyl sydnone with the rate constant of up to 1.46 M-1 s-1. Most significantly, the sydnone-dibenzocyclooctyne and norbornene-tetrazine cycloadditions were predicted to be mutually orthogonal. This was validated experimentally and used for highly selective fluorescence labeling of two proteins simultaneously.

Project description:Genetically encoding distinct non-canonical amino acids (ncAAs) into proteins synthesized in cells requires mutually orthogonal aminoacyl-tRNA synthetase (aaRS)/tRNA pairs. The pyrrolysyl-tRNA synthetase/PyltRNA pair from Methanosarcina mazei (Mm) has been engineered to incorporate diverse ncAAs and is commonly considered an ideal pair for genetic code expansion. However, finding new aaRS/tRNA pairs that share the advantages of the MmPylRS/MmPyltRNA pair and are orthogonal to both endogenous aaRS/tRNA pairs and the MmPylRS/MmPyltRNA pair has proved challenging. Here we demonstrate that several ?NPylRS/PyltRNACUA pairs, in which PylRS lacks an N-terminal domain, are active, orthogonal and efficiently incorporate ncAAs in Escherichia coli. We create new PylRS/PyltRNA pairs that are mutually orthogonal to the MmPylRS/MmPyltRNA pair and show that transplanting mutations that reprogram the ncAA specificity of MmPylRS into the new PylRS reprograms its substrate specificity. Finally, we show that distinct PylRS/PyltRNA-derived pairs can function in the same cell, decode distinct codons and incorporate distinct ncAAs.

Project description:Sulfonamide derivatives have been used in pharmaceutics for decades. Here we report a new approach to release sulfonamides efficiently using a bioorthogonal reaction of sulfonyl sydnonimines and dibenzoazacyclooctyne (DIBAC). The second-order rate constant of the cycloaddition reaction can be up to 0.62 M-1 s-1, and the reactants are highly stable under physiological conditions. Most significantly, we also discovered the mutual orthogonality between the sydnonimine-DIBAC and benzonorbornadiene-tetrazine cycloaddition pairs, which can be used for selective and simultaneous liberation of sulfonamide and primary amine drugs.

Project description:The ability to site-specifically modify proteins at multiple sites in vivo will enable the study of protein function in its native environment with unprecedented levels of detail. Here, we present a versatile two-step strategy to meet this goal involving site-specific encoding of two distinct noncanonical amino acids bearing bioorthogonal handles into proteins in vivo followed by mutually orthogonal labeling. This general approach, that we call dual encoding and labeling (DEAL), allowed us to efficiently encode tetrazine- and azide-bearing amino acids into a protein and demonstrate for the first time that the bioorthogonal labeling reactions with strained alkene and alkyne labels can function simultaneously and intracellularly with high yields when site-specifically encoded in a single protein. Using our DEAL system, we were able to perform topologically defined protein-protein cross-linking, intramolecular stapling, and site-specific installation of fluorophores all inside living Escherichia coli cells, as well as study the DNA-binding properties of yeast Replication Protein A in vitro. By enabling the efficient dual modification of proteins in vivo, this DEAL approach provides a tool for the characterization and engineering of proteins in vivo.

Project description:The site-specific incorporation of unnatural amino acids (UAAs) into proteins in living cells relies on an engineered tRNA/aminoacyl-tRNA synthetase (tRNA/aaRS) pair, orthogonal to the host cell, to deliver the UAA of choice in response to a unique nonsense or frameshift codon. Here we report the generation of mutually orthogonal prolyl-tRNA/prolyl-tRNA synthase (ProRS) pairs derived from an archaebacterial ancestor for use in Escherichia coli. By reprogramming the anticodon-binding pocket of Pyrococcus horikoshii ProRS (PhProRS), we were able to identify synthetase variants that recognize engineered Archaeoglobus fulgidus prolyl-tRNAs (Af-tRNA(Pro)) with three different anticodons: CUA, AGGG, and CUAG. Several of these evolved PhProRSs show specificity toward a particular anticodon variant of Af-tRNA(Pro), whereas others are promiscuous. Further evolution of the Af-tRNA(Pro) led to a variant exhibiting significantly improved amber suppression efficiency. Availability of a prolyl-tRNA/aaRS pair should enable site-specific incorporation of proline analogs and other N-modified UAAs into proteins in E. coli. The evolution of mutually orthogonal prolyl-tRNA/ProRS pairs demonstrates the plasticity of the tRNA-aaRS interface and should facilitate the incorporation of multiple, distinct UAAs into proteins.

Project description:The yeast cytoplasmically localized pGKL1/TP-DNAP1 plasmid/DNA polymerase pair forms an orthogonal DNA replication system whose mutation rate can be drastically increased without influencing genomic replication, thereby supporting in vivo continuous evolution. Here, we report that the pGKL2/TP-DNAP2 plasmid/DNA polymerase pair forms a second orthogonal replication system. We show that custom genes can be encoded and expressed from pGKL2, that error-prone TP-DNAP2s can be engineered, and that pGKL2 replication by TP-DNAP2 is both orthogonal to genomic replication in Saccharomyces cerevisiae and mutually orthogonal with pGKL1 replication by TP-DNAP1. This demonstration of two mutually orthogonal DNA replication systems with tunable error rates and properties should enable new applications in cell-based continuous evolution, genetic recording, and synthetic biology at large.

Project description:Site-specific incorporation of distinct non-canonical amino acids (ncAAs) into proteins via genetic code expansion requires mutually orthogonal aminoacyl-tRNA synthetase (aaRS)/tRNA pairs. Pyrrolysyl–tRNA synthetase (PylRS)/tRNAPyl pairs are ideal for genetic code expansion and have been extensively engineered for developing mutually orthogonal pairs. Here, we identify two novel PylRS/tRNAPyl pairs from extremely halophilic methyl-reducing euryarchaeal HMET1. In order to demonstrate that HMET1 PylRS/tRNAPyl pairs are functional and orthogonal in H. volcanii, we transformed plasmids encoding HMET1 PylRS/tRNAPyl pair and reporter protein SAMP1(G24amb), and cultured the cells in the presence and absence of 1 mM ncAA. Amber suppression ability of HMET1 PylRS/tRNAPyl pairs were assayed by monitoring the production of the full-length SAMP1(G24amb) and the SAMP1(G24amb)-MoaE conjugate via anti-Flag immunoblotting. LC-MS/MS confirmed that BocK (ncAA) was incorporated into the reporter protein at site-directed position. Thus, these two distinct PylRS/tRNAPyl pairs are functional in Haloferax volcanii, a model halophilic archaeon. Furthermore, by swapping these two PylRS/tRNAPyl pairs in the expression vector followed by anti-Flag immunoblotting, we found these two PylRS/tRNAPyl pairs are mutually orthogonal. Finally, we demonstrate HMET1 PylRS/tRNAPyl-derived pairs can decode two stop codons and incorporate distinct ncAAs. LC-MS/MS analysis of the purified reporter protein confirmed that BocK and 3-I-phe were incorporated at the TAA and TAG-directed positions respectively.

Project description:The attention system can be divided into alerting, orienting, and executive control networks. The efficiency and independence of attention networks have been widely tested with the attention network test (ANT) and its revised versions. However, many studies have failed to find effects of attention network scores (ANSs) and inter-network relationships (INRs). Moreover, the low reliability of ANSs can not meet the demands of theoretical and empirical investigations. Two methodological factors (the inter-trial influence in the event-related design and the inter-network interference in orthogonal contrast) may be responsible for the unreliability of ANT. In this study, we combined the mixed design and non-orthogonal method to explore ANSs and directional INRs. With a small number of trials, we obtained reliable and independent ANSs (split-half reliability of alerting: 0.684; orienting: 0.588; and executive control: 0.616), suggesting an individual and specific attention system. Furthermore, mutual inhibition was observed when two networks were operated simultaneously, indicating a differentiated but integrated attention system. Overall, the reliable and individual specific ANSs and mutually inhibited INRs provide novel insight into the understanding of the developmental, physiological and pathological mechanisms of attention networks, and can benefit future experimental and clinical investigations of attention using ANT.

Project description:An asymmetric mechanism for correlated motion occurring in noninteracting pairs of adjacent orthogonal 1,4-bis(carboxyethynyl)bicyclo[1.1.1]pentane (BCP) rotators 1 in the solid state is unraveled and shown to play an important role in understanding the dynamics in the crystalline rotor, Bu4N+[1-]·H2O. Single crystal X-ray diffraction and calculation of rotor-rotor interaction energies combined with variable-temperature, variable-field 1H spin-lattice relaxation experiments led to the identification and microscopic rationalization of two distinct relaxation processes.

Project description:Bioluminescence imaging with luciferase-luciferin pairs is widely used in biomedical research. Several luciferases have been identified in nature, and many have been adapted for tracking cells in whole animals. Unfortunately, the optimal luciferases for imaging in vivo utilize the same substrate and therefore cannot easily differentiate multiple cell types in a single subject. To develop a broader set of distinguishable probes, we crafted custom luciferins that can be selectively processed by engineered luciferases. Libraries of mutant enzymes were iteratively screened with sterically modified luciferins, and orthogonal enzyme-substrate "hits" were identified. These tools produced light when complementary enzyme-substrate partners interacted both in vitro and in cultured cell models. Based on their selectivity, these designer pairs will bolster multicomponent imaging and enable the direct interrogation of cell networks not currently possible with existing tools. Our screening platform is also general and will expedite the identification of more unique luciferases and luciferins, further expanding the bioluminescence toolkit.