Abstract: Engineered, electrically conductive fimbrial polypeptides, pilus, and bundled pili are provided. The polypeptides typically include one or more mutations (e.g., substitution or addition) with an aromatic amino acid relative to the corresponding wildtype fimbrial protein. In some embodiments, the amino acid is a substrate for a “click” chemistry reaction such as Copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC), which can be used to conjugate a functional moiety to the non-standard aromatic amino acid residues. Preferred functional moieties include conductive materials such as metal (e.g., gold) particles, optionally nanoparticles, and heme groups. Also provided are pilus formed of a plurality of the engineered fimbrial polypeptides, and bundles of pili formed of a plurality of the pili. Electrical circuits, devices, and systems including the engineered materials, wherein the engineered material serves as the conductive element, and method of use thereof are also provided.

Abstract: Compositions, systems, and methods for preparation of polypeptides having multiple iterations of non-standard amino acids are provided. The compositions and method can be used to produce recombinant proteins at a greater yield than the same or similar polypeptides made using conventional compositions, systems, and methods. Accordingly, in some embodiments, the polypeptides are ones that could not be made using conventional methods and reagents, or could not be made a sufficient yield or purity to serve a practical purpose using conventional methods and reagents. Polypeptides made using the disclosed compositions, systems, and methods are also provided.

Abstract: Compositions and methods for gene editing are provided. The methods employ an oligo-based annealing mechanism that is rooted in the process of DNA replication rather than homologous recombination (HR). Oligo incorporation efficiencies are comparable and often exceed those of CRISPR/cas9 editing without the need for double strand breaks (DSBs). By relying on the multiplex annealing of oligos rather than DSBs the process is highly scalable across a genomic region of interest and can generate many scarless modifications of a chromosome simultaneously. Combinatorial genomic diversity can be generated across a population of cells in a single transformation event; genomic landscapes can be traversed through successive iterations of the process, and genome-wide changes can be massively parallelized and amplified through systematic strain mating.

Abstract: Compositions and methods for gene editing are provided. The methods employ an oligo-based annealing mechanism that is rooted in the process of DNA replication rather than homologous recombination (HR). Oligo incorporation efficiencies are comparable and often exceed those of CRISPR/cas9 editing without the need for double strand breaks (DSBs). By relying on the multiplex annealing of oligos rather than DSBs the process is highly scalable across a genomic region of interest and can generate many scarless modifications of a chromosome simultaneously. Combinatorial genomic diversity can be generated across a population of cells in a single transformation event; genomic landscapes can be traversed through successive iterations of the process, and genome-wide changes can be massively parallelized and amplified through systematic strain mating.

Abstract: The present invention relates to libraries of phosphopeptide-encoding oligonucleotides and methods of preparing such libraries. The present invention also relates to methods of detecting, visualizing, or screening for phosphorylation-dependent protein-protein interactions using recombinant phosphopeptides and/or phosphopeptide-encoding oligonucleotides. The present invention also relates to sets or kits of oligonucleotides having regions that encode phosphopeptides.

Abstract: Compositions, systems, and methods for preparation of polypeptides having multiple iterations of non-standard amino acids are provided. The compositions and method can be used to produce recombinant proteins at a greater yield than the same or similar polypeptides made using conventional compositions, systems, and methods. Accordingly, in some embodiments, the polypeptides are ones that could not be made using conventional methods and reagents, or could not be made a sufficient yield or purity to serve a practical purpose using conventional methods and reagents. Polypeptides made using the disclosed compositions, systems, and methods are also provided.

Abstract: Organisms resistant to horizontal gene transfer (HGT), and compositions and methods of use thereof are provided. The organisms are typically genomically recoded organisms (GRO), typically cells, having a genome in which at least one endogenous codon has been eliminated by reassignment of the codon to a synonymous or non-synonymous codon. The GRO typically include a recombinant expression construct for expression of at least one element of a ribosomal rescue pathway, typically lacking the eliminated codon. Typically, the disclosed cells are resistant to completed transfer and/or expression of a horizontally transferred genetic element (HTGE) from another organism compared a corresponding cell having a genome wherein the eliminated codon has not been eliminated. In some embodiments, the organism from which the HTGE is being transferred is a bacterium or a virus.

Abstract: Compositions and methods for gene editing are provided. The methods employ an oligo-based annealing mechanism that is rooted in the process of DNA replication rather than homologous recombination (HR). Oligo incorporation efficiencies are comparable and often exceed those of CRISPR/cas9 editing without the need for double strand breaks (DSBs). By relying on the multiplex annealing of oligos rather than DSBs the process is highly scalable across a genomic region of interest and can generate many scarless modifications of a chromosome simultaneously. Combinatorial genomic diversity can be generated across a population of cells in a single transformation event; genomic landscapes can be traversed through successive iterations of the process, and genome-wide changes can be massively parallelized and amplified through systematic strain mating.

Abstract: Organisms resistant to horizontal gene transfer (HGT), and compositions and methods of use thereof are provided. The organisms are typically genomically recoded organisms (GRO), typically cells, having a genome in which at least one endogenous codon has been eliminated by reassignment of the codon to a synonymous or non-synonymous codon. The GRO typically include a recombinant expression construct for expression of at least one element of a ribosomal rescue pathway, typically lacking the eliminated codon. Typically, the disclosed cells are resistant to completed transfer and/or expression of a horizontally transferred genetic element (HTGE) from another organism compared a corresponding cell having a genome wherein the eliminated codon has not been eliminated. In some embodiments, the organism from which the HTGE is being transferred is a bacterium or a virus.

Abstract: Compositions, systems, and methods for preparation of polypeptides having multiple iterations of non-standard amino acids are provided. The compositions and method can be used to produce recombinant proteins at a greater yield than the same or similar polypeptides made using conventional compositions, systems, and methods. Accordingly, in some embodiments, the polypeptides are ones that could not be made using conventional methods and reagents, or could not be made a sufficient yield or purity to serve a practical purpose using conventional methods and reagents. Polypeptides made using the disclosed compositions, systems, and methods are also provided.

Abstract: The present invention relates to libraries of phosphopeptide-encoding oligonucleotides and methods of preparing such libraries. The present invention also relates to methods of detecting, visualizing, or screening for phosphorylation-dependent protein-protein interactions using recombinant phosphopeptides and/or phosphopeptide-encoding oligonucleotides. The present invention also relates to sets or kits of oligonucleotides having regions that encode phosphopeptides.

Abstract: The present invention provides nucleic acid molecules, DNA constructs, plasmids, and methods for post-transcriptional regulation of gene expression using RNA molecules to both repress and activate translation of an open reading frame. Repression of gene expression is achieved through the presence of a regulatory nucleic acid element (the cis-repressive RNA or crRNA) within the 5? untranslated region (5? UTR) of an mRNA molecule. The nucleic acid element forms a hairpin (stem/loop) structure through complementary base pairing. The hairpin blocks access to the mRNA transcript by the ribosome, thereby preventing translation. In particular, in embodiments of the invention designed to operate in prokaryotic cells, the stem of the hairpin secondary structure sequesters the ribosome binding site (RBS). In embodiments of the invention designed to operate in eukaryotic cells, the stem of the hairpin is positioned upstream of the start codon, anywhere within the 5? UTR of an mRNA.