Quantitative methods for optimizing the permeabilization of cellular tissues for spatial transcriptomics are provided. Also provided is an instrument for quantitatively optimizing the permeabilization of cellular tissues used for spatial transcriptomics.

Quantitative methods for optimizing the permeabilization of cellular tissues for spatial transcriptomics are provided. Also provided is an instrument for quantitatively optimizing the permeabilization of cellular tissues used for spatial transcriptomics.

Disclosed is a method of performing a non-isothermal nucleic acid amplification reaction, wherein the temperature at which the method is performed is non-isothermal and subject to a reduction of at least 2° C. during amplification process steps. The present invention provides an improved nucleic acid amplification technique having one or more advantages over existing techniques including, for example, decreased reaction time, increased yield, and decreased non-specific amplification products.

The present invention relates to the analysis of complex single cell sequencing libraries. Disclosed are methods for enrichment of library members based on the presence of cell-of origin barcodes to identify and concentrate DNA that is relevant to interesting cells or components that would be expensive or difficult to study otherwise. Also, disclosed are methods of capturing cDNA library molecules by use of CRISPR systems, hybridization or PCR. The present invention allows for identifying the properties of rare cells in single cell RNA-seq data and accurately profile them through clustering approaches. Further information on transcript abundances from subpopulations of single cells can be analyzed at a lower sequencing effort. The methods also allow for linking TCR alpha and beta chains at the single cell level.

The present invention relates to the analysis of complex single cell sequencing libraries. Disclosed are methods for enrichment of library members based on the presence of cell-of origin barcodes to identify and concentrate DNA that is relevant to interesting cells or components that would be expensive or difficult to study otherwise. Also, disclosed are methods of capturing cDNA library molecules by use of CRISPR systems, hybridization or PCR. The present invention allows for identifying the properties of rare cells in single cell RNA-seq data and accurately profile them through clustering approaches. Further information on transcript abundances from subpopulations of single cells can be analyzed at a lower sequencing effort. The methods also allow for linking TCR alpha and beta chains at the single cell level.

Engineered transversion base editors that enable expanded amino acid modifications and methods of using the same. Described herein, for example, are fusion proteins containing cytidine deaminases (e.g. human or rat APOBECs, pmCDA1 or AID) or adenosine deaminases (e.g. E. coli TadAs) or a combination thereof, catalytically impaired CRISPR-Cas proteins (e.g. Cas9, CasX or Cas12 nucleases), linkers, nuclear localization signals (NLSs) and a human or E. coli uracil-n-glycosylase (UNG) and/or REV1 protein that enable the CRISPR-guided programmable introduction of C-to-G and G-to-C transversions in DNA. The UNG may be fused to the deaminase-Cas fusion or not, in which case endogenous UNG may be recruited using molecular machinery that is integrated into the deaminase-Cas fusion architecture, e.g. using peptide or RNA aptamers or scFVs, sdABs or Fabs.

Engineered transversion base editors that enable expanded amino acid modifications and methods of using the same. Described herein, for example, are fusion proteins containing cytidine deaminases (e.g. human or rat APOBECs, pmCDA1 or AID) or adenosine deaminases (e.g. E. coli TadAs) or a combination thereof, catalytically impaired CRISPR-Cas proteins (e.g. Cas9, CasX or Cas12 nucleases), linkers, nuclear localization signals (NLSs) and a human or E. coli uracil-n-glycosylase (UNG) and/or REV1 protein that enable the CRISPR-guided programmable introduction of C-to-G and G-to-C transversions in DNA. The UNG may be fused to the deaminase-Cas fusion or not, in which case endogenous UNG may be recruited using molecular machinery that is integrated into the deaminase-Cas fusion architecture, e.g. using peptide or RNA aptamers or scFVs, sdABs or Fabs.

The invention relates to new methods for synthesising polynucleotide molecules according to a predefined nucleotide sequence. The invention also relates to methods for the assembly of synthetic polynucleotides following synthesis, as well as systems and kits for performing the synthesis and/or assembly methods.

The invention relates to new methods for synthesising polynucleotide molecules according to a predefined nucleotide sequence. The invention also relates to methods for the assembly of synthetic polynucleotides following synthesis, as well as systems and kits for performing the synthesis and/or assembly methods.

Embodiments provided herein relate to methods and compositions for preparing nucleic acid libraries. Some embodiments include preparing libraries from nucleic acids obtained from degraded samples, such as ancient samples and fixed samples.