The present disclosure provides devices, systems, and methods for detection of nucleic acids based on CRISPR-Cas editing systems, for example for use in biosurveillance. Disclosed herein are systems and methods utilizing two devices: 1) a point of—need disposable “FET Strip” (enzymatic), and 2) an instrument-operated “FET Multiplexor” (electronic), to provide detection of a nucleic acid for biosurveillance.

The present disclosure provides devices, systems, and methods for detection of nucleic acids based on CRISPR-Cas editing systems, for example for use in biosurveillance. Disclosed herein are systems and methods utilizing two devices: 1) a point of—need disposable “FET Strip” (enzymatic), and 2) an instrument-operated “FET Multiplexor” (electronic), to provide detection of a nucleic acid for biosurveillance.

The present disclosure provides devices, systems, and methods for detection of nucleic acids based on CRISPR-Cas editing systems, for example for use in biosurveillance. Disclosed herein are systems and methods utilizing two devices: 1) a point of—need disposable “FET Strip” (enzymatic), and 2) an instrument-operated “FET Multiplexor” (electronic), to provide detection of a nucleic acid for biosurveillance.

Methods, compositions, and kits are provided for CRISPR/Cas mediated transcriptional modulation.

Methods, compositions, and kits are provided for CRISPR/Cas mediated transcriptional modulation.

The present invention discloses a method for establishing a colorectal cancer HK2 reporter gene cell line, specifically including: firstly, designing a site-specific sgRNA sequence of an HK2 gene, and cloning same into a PX459 plasmid; integrating a homologous recombination sequence of an HK2 gene and a green fluorescent protein DNA fragment (EGFP), and transforming the plasmid and the integrated fragment together into a colorectal cancer cell line HCT116 by electroporation; and performing signal cell screening through a flow cytometer to obtain EGFP-expressing cells, and amplifying a monoclonal cell line; and identifying a positive HK2 reporter gene cell line through PCR identification and Western blot, among screened EGFP-expressing cell lines. The colorectal cancer cell line HK2 gene and EGFP are co-expressed, and the expression level of the EGFP is highly consistent with that of the HK2 gene. Therefore, the expression level of the HK2 gene can be accurately determined by detecting a change in the expression level of the EGFP. The method for establishing a cell line in the present invention are simple, easy to implement and efficient, and a gene site can be precisely positioned.

The present invention discloses a method for establishing a colorectal cancer HK2 reporter gene cell line, specifically including: firstly, designing a site-specific sgRNA sequence of an HK2 gene, and cloning same into a PX459 plasmid; integrating a homologous recombination sequence of an HK2 gene and a green fluorescent protein DNA fragment (EGFP), and transforming the plasmid and the integrated fragment together into a colorectal cancer cell line HCT116 by electroporation; and performing signal cell screening through a flow cytometer to obtain EGFP-expressing cells, and amplifying a monoclonal cell line; and identifying a positive HK2 reporter gene cell line through PCR identification and Western blot, among screened EGFP-expressing cell lines. The colorectal cancer cell line HK2 gene and EGFP are co-expressed, and the expression level of the EGFP is highly consistent with that of the HK2 gene. Therefore, the expression level of the HK2 gene can be accurately determined by detecting a change in the expression level of the EGFP. The method for establishing a cell line in the present invention are simple, easy to implement and efficient, and a gene site can be precisely positioned.

Control Devices are disclosed including RNA destabilizing elements (RDE), RNA control devices, and destabilizing elements (DE) combined with Chimeric Antigen Receptors (CARs) or other transgenes in eukaryotic cells. Multicistronic vectors are also disclosed for use in engineering host eukaryotic cells with the CARs and transgenes under the control of the control devices. These control devices can be used to optimize expression of CARs in the eukaryotic cells so that, for example, effector function is optimized. CARs and transgene payloads can also be engineered into eukaryotic cells so that the transgene payload is expressed and delivered after stimulation of the CAR on the eukaryotic cell.

Control Devices are disclosed including RNA destabilizing elements (RDE), RNA control devices, and destabilizing elements (DE) combined with Chimeric Antigen Receptors (CARs) or other transgenes in eukaryotic cells. Multicistronic vectors are also disclosed for use in engineering host eukaryotic cells with the CARs and transgenes under the control of the control devices. These control devices can be used to optimize expression of CARs in the eukaryotic cells so that, for example, effector function is optimized. CARs and transgene payloads can also be engineered into eukaryotic cells so that the transgene payload is expressed and delivered after stimulation of the CAR on the eukaryotic cell.

The present invention relates to compositions comprising and methods of producing genetically engineered bacteriophages, bacteriophage-like particles and non-replicating transduction particles (NRTPs) that contain non-native tail fibers that display altered host specificity and/or reactivity. The present invention also relates to methods of using these bacteriophages and NRTPs for the development of novel diagnostics, therapeutics and/or research reagents for bacteria-related diseases.