Methods for detecting the presence of a pathogen infection are described. In particular, this document provides a method of detecting target nucleic acids, such as pathogen-specific RNA, in a biological sample obtained from a subject, where the method comprises using one or more toehold switch sensors and an isothermal amplification step to detect the target nucleic acid. Methods specific for detecting and identify the presence of a virus such as Zika virus are also provided.

Methods for detecting the presence of a pathogen infection are described. In particular, this document provides a method of detecting target nucleic acids, such as pathogen-specific RNA, in a biological sample obtained from a subject, where the method comprises using one or more toehold switch sensors and an isothermal amplification step to detect the target nucleic acid. Methods specific for detecting and identify the presence of a virus such as Zika virus are also provided.

This disclosure provides methods for preparing a sequencing library including the steps of providing a template nucleic acid sequence, dNTPs, dUTP, a primer, a polymerase, a dUTP excising enzyme, and a plurality of beads including oligonucleotide adapter sequence segments; amplifying the template nucleic acid with the polymerase, dNTPs, dUTP and random hexamer to provide a complementary nucleic acid sequence including occasional dUTPs; and excising the incorporated dUTPs with the dUTP excising enzyme to provide nicks in the complementary nucleic acid sequence to provide a sequencing library.

This disclosure provides methods for preparing a sequencing library including the steps of providing a template nucleic acid sequence, dNTPs, dUTP, a primer, a polymerase, a dUTP excising enzyme, and a plurality of beads including oligonucleotide adapter sequence segments; amplifying the template nucleic acid with the polymerase, dNTPs, dUTP and random hexamer to provide a complementary nucleic acid sequence including occasional dUTPs; and excising the incorporated dUTPs with the dUTP excising enzyme to provide nicks in the complementary nucleic acid sequence to provide a sequencing library.

Embodiments disclosed herein provide methods for identifying cell-type-specific nucleosomal DNA modifications. The methods leverage nucleosomal DNA barcoding and pool-and-split multiplexing to provide high-throughout, quantitative profiling of nucleosomal DNA states. The methods enable the profiling of multiple nucleosomal DNA marks across different cell types and/or conditions thereby linking quantitative changes in chromatin landscapes to different genotypes and chemical and physical perturbations.

Embodiments disclosed herein provide methods for identifying cell-type-specific nucleosomal DNA modifications. The methods leverage nucleosomal DNA barcoding and pool-and-split multiplexing to provide high-throughout, quantitative profiling of nucleosomal DNA states. The methods enable the profiling of multiple nucleosomal DNA marks across different cell types and/or conditions thereby linking quantitative changes in chromatin landscapes to different genotypes and chemical and physical perturbations.

Provided herein are methods and compositions for rapid, highly sensitive detection of SARS-CoV-2 in biological samples. In particular, provided herein is a rapid, low-cost method for detecting SARS-CoV-2 that provides reliable, visible test results and does not require PCR reagents, elaborate biosafety precautions, or sophisticated laboratory equipment.

Provided herein are methods and compositions for rapid, highly sensitive detection of SARS-CoV-2 in biological samples. In particular, provided herein is a rapid, low-cost method for detecting SARS-CoV-2 that provides reliable, visible test results and does not require PCR reagents, elaborate biosafety precautions, or sophisticated laboratory equipment.

Compositions that are used in nucleic acid amplification in vitro are disclosed, which include a target specific universal (TSU) promoter primer or promoter provider oligonucleotide that includes a target specific (TS) sequence that hybridizes specifically to a target sequence that is amplified and a universal (U) sequence that is introduced into the sequence that is amplified, by using a primer for the universal sequence. Methods of nucleic acid amplification in vitro are disclosed that use one or more TSU oligonucleotides to attached a U sequence to a target nucleic acid in a target capture step and then use a primer for a U sequence in subsequent amplification steps performed in substantially isothermal conditions to make amplification products that contain a U sequence that indicates the presence of the target nucleic acid in a sample.

Compositions that are used in nucleic acid amplification in vitro are disclosed, which include a target specific universal (TSU) promoter primer or promoter provider oligonucleotide that includes a target specific (TS) sequence that hybridizes specifically to a target sequence that is amplified and a universal (U) sequence that is introduced into the sequence that is amplified, by using a primer for the universal sequence. Methods of nucleic acid amplification in vitro are disclosed that use one or more TSU oligonucleotides to attached a U sequence to a target nucleic acid in a target capture step and then use a primer for a U sequence in subsequent amplification steps performed in substantially isothermal conditions to make amplification products that contain a U sequence that indicates the presence of the target nucleic acid in a sample.