A visual continuous spatial directed evolution method is disclosed. The host grows and moves in a solid culture space, the host carrying a foreign target gene to be evolved and containing a gene element that assists the evolution of the target gene, the target gene being correlated with the growth and movement of the host. Depending on different spatial distribution patterns formed in the solid culture space during the growth and movement of the host, screening is performed to obtain an evolved product. This method is carried out directly in the solid culture space. Depending on images of different spatial distribution morphologies visible to the naked eye that are locally formed, selection of evolved products is performed without the need for liquid fed-batch culture equipment. In addition, the evolution effect is visually observed through the infection spots formed during evolution, so that no real-time monitoring equipment is required.

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.

A bacteriophage structure, a method of making the structure, and uses of the structure are described. The structure is a substrate with a surface having an ordered arrangement of parallel microridges thereon. Each microridge is composed of a plurality of nanoridges and has a longitudinal axis. Each nanoridge contains a bundle of phage nano fibers having longitudinal axes. The phage nanofibers in each nanoridge bundle are arranged in a substantially smectic alignment. The longitudinal axis of each microridge is perpendicular to the longitudinal axes of the phage nanofibers which make up the nanoridges of the microridge. The structure may be used as a growth surface for inducing differentiation of stem cells such as neural progenitor cells.

Disclosed herein, inter alia, are compositions and methods useful for improving detection of analytes. The compositions and methods provided include polymer-wrapped viral particles useful, inter alia, for the detection of PSMA.

The present disclosure provides systems and methods that can provide portable, real-time accessible DNA memories. An example DNA-based data storage system includes a loading region configured to receive a plurality of DNA-based data storage elements in a suspension fluid and a plurality of microtubes disposed in a capture/release region. The microtubes are configured to capture and release the DNA-based data storage elements. The DNA-based data storage system also includes a linearization region configured to linearize the DNA-based data storage elements and a readout region with a readout device configured to provide information indicative of the respective DNA-based data storage elements.

Provided is a chemically modified phage display platform and method of use thereof. More specifically, the present disclosure provides a chemically modified phage display library that incorporates 2-acetylphenylboronic acid (APBA) moieties to elicit dynamic covalent binding to the bacterial cell surface. The APBA-modified phage display libraries described herein are applicable to a wide array of bacterial strains and/or mammalian cells, paving the way to facile diagnosis and development of strain-specific antibiotics, and/or peptide-antibiotic conjugates for effective and targeted treatment. Also provided are therapeutic peptides, and pharmaceutical compositions thereof, that are identified by screening the phage display library of the present disclosure, and method of use of such therapeutic peptides for effective and targeted treatment.

Novel chimeric proteins may be used to inhibit transcriptional A activities that are mediated by transcription factor interactions with P-TEFb. The chimeras contain elements that recruit the target transcription factor, maintain CDK9 in an inactive state, and competitively inhibit P-TEFb binding to the transcription factor. The chimeras may be configured for inhibition of HIV Tat mediated transcription and thus provide a novel means of preventing reactivation of integrated HIV, providing a new tool for emerging “block and lock” HIV cure strategies.

A bacteriophage structure, a method of making the structure, and uses of the structure are described. The structure is a substrate with a surface having an ordered arrangement of parallel microridges thereon. Each microridge is composed of a plurality of nanoridges and has a longitudinal axis. Each nanoridge contains a bundle of phage nano fibers having longitudinal axes. The phage nanofibers in each nanoridge bundle are arranged in a substantially smectic alignment. The longitudinal axis of each microridge is perpendicular to the longitudinal axes of the phage nanofibers which make up the nanoridges of the microridge. The structure may be used as a growth surface for inducing differentiation of stem cells such as neural progenitor cells.

The present invention provides for a modified virus, such as a recombinant M13 phage, which in an array, such as a film, is capable of producing piezoelectricity. The modified virus comprises a coat protein can displays a negatively charged amino acid sequence. The present invention provides for a device comprising a piezoelectric element comprising a suitable virus, such as the modified virus, a first surface and a second surface, wherein the first surface is in contact with a first electrode and the second surface is in contact with a second electrode, wherein when pressure is applied to the film, the film is capable of generating an electric current. The present invention provides for a method of making the device, and a method for generating electricity using the device.

The present invention relates to vectors suitable for use in displaying proteins on the surface of bacteriophage M13 as fusion constructs with the surface protein P.III, bacteriophage M13 particles comprising a mutated P.III protein on the phage coat surface, as well as methods for producing bacteriophage M13 particles and methods for transfecting or infecting a host cell comprising the vectors and bacteriophage of the invention.