Provided herein are compositions and methods for accurate and scalable Primary Template-Directed Amplification (PTA) nucleic acid amplification and sequencing methods, and their applications for mutational analysis in research, diagnostics, and treatment. Further provided herein are multiomics methods for parallel analysis of DNA, RNA, and/or proteins from single cells. Provided herein are methods of multiomic single-cell analysis comprising: (a) isolating a single cell from a population of cells; (b) sequencing a cDNA library comprising polynucleotides amplified from mRNA transcripts from the single cell; and (c) sequencing a genome of the single cell.

Provided herein are compositions and methods for accurate and scalable Primary Template-Directed Amplification (PTA) nucleic acid amplification and sequencing methods, and their applications for mutational analysis in research, diagnostics, and treatment. Further provided herein are multiomics methods for parallel analysis of DNA, RNA, and/or proteins from single cells. Provided herein are methods of multiomic single-cell analysis comprising: (a) isolating a single cell from a population of cells; (b) sequencing a cDNA library comprising polynucleotides amplified from mRNA transcripts from the single cell; and (c) sequencing a genome of the single cell.

Described herein are systems, assays, methods and compositions for identification of oxidase microbial redox-enzymes (MREs) specific to an analyte of interest from an environmental source. The technology relates to identification of analyte-responsive MREs that can quantify the concentration of a target analyte with high specificity and high sensitivity, for example, where the identified analyte-responsive redox-enzyme can be used to engineer an electrochemical biosensor.

Described herein are systems, assays, methods and compositions for identification of oxidase microbial redox-enzymes (MREs) specific to an analyte of interest from an environmental source. The technology relates to identification of analyte-responsive MREs that can quantify the concentration of a target analyte with high specificity and high sensitivity, for example, where the identified analyte-responsive redox-enzyme can be used to engineer an electrochemical biosensor.

An example of a flow cell includes a substrate and a pattern of two different silanes on at least a portion of a surface of the substrate. A first polymer is attached to a first of the two different silanes and a second polymer is attached to a second of the two different silanes. The first and second polymers respectively include a first functional group and a second functional group of a functional group pair, the functional group pair being selected from the group consisting of an activated ester functional group and an azide functional group, a tetrazine functional group and an activated ester functional group, and a tetrazine functional group and an azide functional group. A first primer set is grafted to the first polymer and a second primer set is grafted to the second polymer. The first and second primer sets are different.

An example of a flow cell includes a substrate and a pattern of two different silanes on at least a portion of a surface of the substrate. A first polymer is attached to a first of the two different silanes and a second polymer is attached to a second of the two different silanes. The first and second polymers respectively include a first functional group and a second functional group of a functional group pair, the functional group pair being selected from the group consisting of an activated ester functional group and an azide functional group, a tetrazine functional group and an activated ester functional group, and a tetrazine functional group and an azide functional group. A first primer set is grafted to the first polymer and a second primer set is grafted to the second polymer. The first and second primer sets are different.

Sub-millimeter scale three-dimensional (3D) structures are disclosed with customizable chemical properties and/or functionality. The 3D structures are referred to as drop-carrier particles. The drop-carrier particles allow the selective association of one solution (i.e., a dispersed phased) with an interior portion of each of the drop-carrier particles, while a second non-miscible solution (i.e., a continuous phase) associates with an exterior portion of each of the drop-carrier particles due to the specific chemical and/or physical properties of the interior and exterior regions of the drop-carrier particles. The combined drop-carrier particle with the dispersed phase contained therein is referred to as a particle-drop. The selective association results in compartmentalization of the dispersed phase solution into sub-microliter-sized volumes contained in the drop-carrier particles. The compartmentalized volumes can be used for single-molecule assays as well as single-cell, and other single-entity assays.

Sub-millimeter scale three-dimensional (3D) structures are disclosed with customizable chemical properties and/or functionality. The 3D structures are referred to as drop-carrier particles. The drop-carrier particles allow the selective association of one solution (i.e., a dispersed phased) with an interior portion of each of the drop-carrier particles, while a second non-miscible solution (i.e., a continuous phase) associates with an exterior portion of each of the drop-carrier particles due to the specific chemical and/or physical properties of the interior and exterior regions of the drop-carrier particles. The combined drop-carrier particle with the dispersed phase contained therein is referred to as a particle-drop. The selective association results in compartmentalization of the dispersed phase solution into sub-microliter-sized volumes contained in the drop-carrier particles. The compartmentalized volumes can be used for single-molecule assays as well as single-cell, and other single-entity assays.

Provided include methods, compositions, kits, and systems for replenishing a rolling circle amplification (RCA) reaction in a vessel. The RCA reaction can be initiated by contacting a nucleic acid template and a primer with a loading buffer comprising a DNA polymerase and polymerase extension agents including a divalent metal cation and a polyelectrolyte, followed by replenishing with an amplification buffer to continue the nucleic acid amplification through primer extension. The amplification buffer is different in composition from the loading buffer and does not comprise any DNA polymerase.

Provided include methods, compositions, kits, and systems for replenishing a rolling circle amplification (RCA) reaction in a vessel. The RCA reaction can be initiated by contacting a nucleic acid template and a primer with a loading buffer comprising a DNA polymerase and polymerase extension agents including a divalent metal cation and a polyelectrolyte, followed by replenishing with an amplification buffer to continue the nucleic acid amplification through primer extension. The amplification buffer is different in composition from the loading buffer and does not comprise any DNA polymerase.