A polynucleotide sequencing method comprises (i) removing a label and a blocking moiety from a blocked, labeled nucleotide incorporated into a copy polynucleotide strand that is complementary to at least a portion of a template polynucleotide strand; and (ii) washing the removed label and blocking moiety away from the copy strand with a wash solution comprising a first buffer comprising a scavenger compound. Removing the label and blocking moieties may comprise chemically removing the moieties. The first buffer may also comprise an antioxidant and may be used in a scanning buffer used during a nucleotide detection step.

A polynucleotide sequencing method comprises (i) removing a label and a blocking moiety from a blocked, labeled nucleotide incorporated into a copy polynucleotide strand that is complementary to at least a portion of a template polynucleotide strand; and (ii) washing the removed label and blocking moiety away from the copy strand with a wash solution comprising a first buffer comprising a scavenger compound. Removing the label and blocking moieties may comprise chemically removing the moieties. The first buffer may also comprise an antioxidant and may be used in a scanning buffer used during a nucleotide detection step.

The present disclosure relates, in some embodiments, to isolated nucleic acids (also referred to as cap guides) and methods of use thereof for RNA mapping. The disclosure is based, in part, on guide RNAs that bind to a position that is at least 7 nucleotides downstream of the first nucleotide of an mRNA molecule.

The present disclosure relates, in some embodiments, to isolated nucleic acids (also referred to as cap guides) and methods of use thereof for RNA mapping. The disclosure is based, in part, on guide RNAs that bind to a position that is at least 7 nucleotides downstream of the first nucleotide of an mRNA molecule.

Methods for quenching a nuclease digestion of a target nucleic acid prior to downstream analysis of the target nucleic acid are disclosed herein. Particularly, methods for controlling the end point of a nuclease digestion prior to sequence analysis of a target nucleic acid is provided. Quenching of a nuclease digestion in the present disclosure employs at least one non-ionic or anionic denaturant combined with an optional reducing agent. The methods presented in this disclosure aids preserving the sample comprising the target nucleic acid or fragments thereof for long term storage and ensures that the effect of contaminating nucleases is eliminated during pretreatment step.

Methods for quenching a nuclease digestion of a target nucleic acid prior to downstream analysis of the target nucleic acid are disclosed herein. Particularly, methods for controlling the end point of a nuclease digestion prior to sequence analysis of a target nucleic acid is provided. Quenching of a nuclease digestion in the present disclosure employs at least one non-ionic or anionic denaturant combined with an optional reducing agent. The methods presented in this disclosure aids preserving the sample comprising the target nucleic acid or fragments thereof for long term storage and ensures that the effect of contaminating nucleases is eliminated during pretreatment step.

The present invention provides methods, compositions, and systems for enriching compositions for polymerase enzyme complexes. In particular, the methods, compositions, and systems of the present invention remove free polymerases from the compositions using one or more purification steps, including protease treatment, thus enriching the compositions for polymerases complexed with a template nucleic acid.

The present invention provides methods, compositions, and systems for enriching compositions for polymerase enzyme complexes. In particular, the methods, compositions, and systems of the present invention remove free polymerases from the compositions using one or more purification steps, including protease treatment, thus enriching the compositions for polymerases complexed with a template nucleic acid.

The invention is directed to compositions and methods for collecting, transporting, and storing microorganisms obtained from samples of biological, clinical, forensic, and environmental origin. Compositions preserve the viability of the collected organisms and permit the long-term storage of samples. Compositions are compatible with subsequent manipulation of the sample, including propagation and culture of the collected microorganisms, or isolation, purification, detection, and characterization of proteins, nucleic acids, and all macromolecules. When the compositions containing microorganisms and any polynucleotides therein are further processed, such as by nucleic acid testing, there is an increased ability to detect, isolate, purify and/or characterize select microbes and their components, such as nucleic acids, when compared to conventional microbial transport media that contain interfering substance(s). In particular formulations, the compositions disclosed herein allow biological samples to be collected, transported, and even stored for extended periods, and are compatible with nucleic acid extraction, identification, quantitation, PCR amplification, and genomic analysis methodologies.

Provided herein is the use of measurements of cell-free DNA, protein, and/or metabolite found in biofluid (e.g., urine) for identifying and treating organ injury. Provided herein are methods and compositions for monitoring, detecting, quantifying, and treating kidney injury in subjects suffering from or suspected of having an altered renal status by measuring amounts of cfDNA and one or more other markers, such as inflammation markers, apoptosis markers, protein, and DNA methylation.