Some aspects of the present disclosure provide methods for evolving recombinases to recognize target sequences that differ from the canonical recognition sequences. Some aspects of this disclosure provide evolved recombinases, e.g., recombinases that bind and recombine naturally-occurring target sequences, such as, e.g., target sequences within the human Rosa26 locus. Methods for using such recombinases for genetically engineering nucleic acid molecules in vitro and in vivo are also provided. Some aspects of this disclosure also provide libraries and screening methods for assessing the target site preferences of recombinases, as well as methods for selecting recombinases that bind and recombine a non-canonical target sequence with high specificity.

A composition can include a carbon nanofiber, wherein a precursor for the carbon nanofiber includes an alcohol and an aldehyde crosslinked by a primary amine. In certain embodiments, the carbon nanofiber can be biotemplated. Biotemplating enables precise control of morphology at the nanometer scale, while molecular templating allows control of carbon nanotexture and structure at the sub-nanometer scale.

Strategies, systems, methods, reagents, and kits for phage-assisted continuous evolution are provided herein. These include strategies, systems, methods, reagents, and kits allowing for stringency modulation to evolve weakly active or inactive biomolecule variants, negative selection of undesired properties, and/or positive selection of desired properties.

A construct comprising an M13 phage displaying one or more metal-binding protein sequences on capsid proteins (for example metal binding protein sequences from Lanmodulin) or on the tail protein (pIII) is effective to bind and release rare earth metal (REE) for the extraction, concentration, and/or purification thereof.

The present disclosure relates to a method of in vitro engineering of nucleic acids. This disclosure further relates to in vitro engineering of viral genomes and to the improvement of viral properties by in vitro genomic engineering of viral genomes. Specifically, the disclosure relates to in vitro viral genomic digestion using RNA-guided Cas9, the assembly of a recombinant genome by the insertion of a DNA or RNA fragment into the digested viral genome and transformation of a host cell with the recombinant genome. This method also related to in vitro engineering for error correction of nucleic acids.

Compositions and methods for the storage, organization, access, and retrieval of information encoded by sequence controlled polymers such as data storage nucleic acids are provided. In some embodiments, organization, storage, and/or selective retrieval of the data is facilitated by hybridization of barcode sequence of the sequence controlled polymer to the reverse complementary sequence of an oligonucleotide. The plurality of oligonucleotides can be arrayed using a known organization scheme, and selectively capture and localize the corresponding sequence controlled polymer. In some embodiments, the compositions and methods utilize recombinant bacteriophage, typically featuring a minigenome having a bacteriophage origin of replication and packaging signal separated from a data storage sequence by barcodes.

The present invention addresses to provide a novel membrane permeability-improving agent which can be applied to high molecular drugs. More specifically, the present invention addresses to provide: a drug carrier which can improve the absorption efficiency of a high molecular drug in the small intestine; and a membrane permeation-improving agent containing the carrier. According to the present invention, a cell membrane-permeating peptide can be provided, which comprises an amino acid sequence selected from the group consisting of the following amino acid sequences: DNPGN (SEQ ID NO: 1); SRPAF (SEQ ID NO: 2); NDPRN (SEQ ID NO: 3); and MSVAN (SEQ ID NO: 4). According to the present invention, a cell membrane-permeable composition can also be provided, which comprises the peptide and a biologically active substance.

The present disclosure relates to a phage-based matrix for inducing stem cell differentiation and a method for preparing the same. More specifically, the present disclosure relates to a composition for inducing differentiation of stem cells, which includes a phage-based matrix in which a gradient of stiffness is controlled by crosslinking a recombinant phage with a polymer, and a method for preparing a phage-based matrix for stem cell differentiation. According to the present invention, the method of the present disclosure provides a physical and mechanical niche environment created by the formation of a nanofibrous structure of the phage whose stiffness is controlled, thereby promoting the differentiation of stem cells into target cells. Therefore, it can be applied to a tissue matrix platform as a variety of conventional tissue engineering materials.

Provided are engineered phages populations, which are homogeneous in length, as well as methods of making and methods of using such phages. Also provided are engineered chlorotoxin -phages as well as their methods of making and using. The disclosed homogeneous phage populations and chlorotoxin-phages may be used, for example, for treating and/or imaging tumors, such as central nervous system tumors.

Strategies, systems, methods, reagents, and kits for phage-assisted continuous evolution are provided herein. These include strategies, systems, methods, reagents, and kits allowing for stringency modulation to evolve weakly active or inactive biomolecule variants, negative selection of undesired properties, and/or positive selection of desired properties.