Abstract: Embodiments may include a method of determining a nucleic acid sequence. The nucleic acid may be DNA. The method may include forming, by a polymerase, a double-stranded nucleic acid molecule from a first nucleic acid strand and a second nucleic acid strand. Forming the double-stranded nucleic acid molecule may include adding a first compound to the second nucleic acid strand. The first compound may include a nucleotide attached to a third nucleic acid strand. The third nucleic acid strand may be attached to a moiety. The method may also include detaching the nucleotide from the third nucleic acid strand and the moiety. The method may further include measuring a change in an electrical characteristic of a transistor resulting from the moiety. Additionally, the method may include identifying the nucleotide based on the measured change in the electrical characteristic.

Abstract: A nanopore cell includes a conductive layer and a working electrode disposed above the conductive layer and at the bottom of a well into which an electrolyte may be contained, such that at least a portion of a top base surface area of the working electrode is exposed to the electrolyte. The nanopore cell further includes a first insulating wall disposed above the working electrode and surrounding a lower section of a well, and a second insulating wall disposed above the first insulating wall and surrounding an upper section of the well, forming an overhang above the lower section of the well. The upper section of the well includes an opening that a membrane may span across, and wherein a base surface area of the opening is smaller than the at least a portion of the top base surface area of the working electrode that is exposed to the electrolyte.

Abstract: Methods and compositions are described herein for primer extension target enrichment of immune receptor (BCR or TCR) sequences.

Abstract: The present disclosure provides biochips and methods for making biochips. A biochip can comprise a nanopore in a membrane (e.g., lipid bilayer) adjacent or in proximity to an electrode. Methods are described for forming the membrane and insert-ing the nanopore into the membrane. The biochips and methods can be used for nucleic acid (e.g., DNA) sequencing. The present disclosure also describes methods for detecting, sorting, and binning molecules (e.g., proteins) using biochips.

Abstract: The present invention relates to improving the processing rate of a sequencing reaction, for example in a nanopore sequencing reaction, by means of using improved nucleoside-tags. The tags are linked to the nucleoside phosphate via a Pictet Spengler reaction. Exemplary sequencing reactions that are improved by the present methods include nanopore-based nucleic acid sequencing-by-synthesis reactions.

Abstract: Techniques for measuring sequences of nucleic acids are provided. Time-based measurements (e.g., forming a histogram) particular to a given sequencing cell can be used to generate a tailored model. The model can include probability functions, each corresponding to different states (e.g., different states of a nanopore). Such probability functions can be fit to a histogram of measurements obtained for that cell. The probability functions can be updated over a sequencing run of the nucleic acid so that drifts in physical properties of the sequencing cell can be compensated. A hidden Markov model can use such probability functions as emission probabilities for determining the most likely nucleotide states over time. For sequencing cells involving a polymerase, a 2-state classification between bound and unbound states of the polymerase can be performed. The bound regions can be further analyzed by a second classifier to distinguish between states corresponding to different bound nucleotides.

Abstract: The present disclosure relates to compositions and methods based on polypeptide-tagged nucleotide, and the use of such polypeptide-tagged nucleotides in nanopore devices and methods.

Abstract: In one aspect, the present disclosure provides a system and method for the identification and characterization of a transglutaminase. Further, the present disclosure provides transglutaminase enzymes for forming isopeptide bonds, methods of forming isopeptide bonds in the presence of transglutaminases, and substrate tags for use with transglutaminases. In another aspect, the present disclosure provides glutamine-containing substrates (or Q-tag substrates) that are more resistant to proteases/clipping and therefore, more stable, than other Q-tag substrates, and their uses in substrate tags for cross-linking to an amine-donor tag via an isopeptide bond mediated by a microbial transglutaminase.

Abstract: A device for controlling, detecting, and measuring a molecular complex is disclosed. The device comprises a common electrode. The device further comprises a plurality of measurement cells. Each measurement cell includes a cell electrode and an integrator electronically coupled to the cell electrode. The integrator measures the current flowing between the common electrode and the cell electrode. The device further comprises a plurality of analog-to-digital converters, wherein an integrator from the plurality of measurement cells is electrically coupled to one analog-to-digital converter of the plurality of analog-to-digital converters.

Abstract: According to one aspect, the present disclosure provides a method of identifying a substrate of a transglutaminase using a peptide array comprising a plurality of peptides. The method includes the steps of contacting the peptides in the peptide array with the transglutaminase, allowing the transglutaminase to bind to the peptides, and identifying the substrate of the transglutaminase.

Abstract: Described herein are engineered alpha-hemolysin subunits having mutated oligomerization domains for assembling into heptameric nanopores in lipid bilayers.

Abstract: This invention relates to peptide microarrays, methods of generating peptide microarrays, and methods of identifying peptide binders using microarrays. More specifically, this invention relates to peptide microarrays, methods of generating peptide microarrays, and methods of identifying peptide binders using microarrays wherein the microarrays comprise cyclic peptides. The invention also relates to methods and compositions for detecting the formation of cyclized peptides from linear peptides on a microarray by contacting the microarray with a detectable protein. The cyclized peptides include tags that are activated upon cyclization, facilitating the detection of successful cyclization reactions. In additional aspects, the invention relates to developing fragmented peptide tags that, upon cyclization, bind to detectable proteins. Additionally, the invention relates to methods of generating linear and cyclic peptides subarrays on a microarray.

Abstract: The invention provides methods, compositions, kits and devices for the detection of target molecules. In some embodiments, the invention allows for multiplexed target molecule detection.

Abstract: A nanopore-based sequencing system includes a plurality of nanopore-based sequencing chips. Each of the nanopore-based sequencing chips comprises a plurality of nanopore sensors. The system comprises at least one flow cell coupled to at least one of the plurality of nanopore-based sequencing chips, wherein the flow cell coupled to the at least one of the plurality of nanopore-based sequencing chips comprises one or more fluidic flow channels that allow a fluid external to the system to flow on top of the nanopore-based sequencing chip and out of the system. The system further comprises a printed circuit board electrically connected to the plurality of nanopore-based sequencing chips.

Abstract: The invention is a novel method of making and using a library such as a sequencing library of single stranded circular nucleic acid templates via splint ligation.

Abstract: The invention is a novel method of making and using a template for nucleic acid sequencing. The templates include circular and linear templates with symmetric and asymmetric adaptors. The methods include utilizing the templates in an asymmetric fashion.

Abstract: The invention is a novel method of generating a library of circular single stranded nucleic acid molecules by utilizing circular capture molecules. The method is not limited by size of target nucleic acid molecules and can potentially accommodate very long molecules. The method finds application in nucleic acid sequencing, e.g., nanopore sequencing where unlimited-length templates can be read.

Abstract: The present disclosure provides a system and method for depleting target nucleic acids from a nucleic acid sample. In one aspect, a kit according to the present disclosure includes a plurality of DNA probes. Each of the DNA probes is hybridizable to form a heteroduplex with at least one of a plurality of target RNA transcripts in a nucleic acid sample. The number of unique target RNA transcripts hybridized by the plurality of DNA probes is at least three. The kit further includes an enzyme having RNA-DNA hybrid ribonucleotidohydrolase activity, where degrades at least the RNA portion of the heteroduplex.

Abstract: This disclosure provides a biochip comprising a plurality of wells. The biochip includes a membrane that is disposed in or adjacent to an individual well of the plurality of wells. The membrane comprises a nanopore, and the individual well comprises an electrode that detects a signal upon ionic flow through the pore in response to a species passing through or adjacent to the nanopore. The electrode can be a non-sacrificial electrode. A lipid bilayer can be formed over the plurality of wells using a bubble.

Abstract: Described herein are nanopore protein conjugates that can be used in DNA sequencing reactions. The nanopore protein conjugates includes a nanopore protein monomer that is joined to a DNA binding domain. The nanopore protein monomer is available to oligomerize with other nanopore protein monomers, while the DNA binding domain is available to bind to a template DNA strand. In certain examples, the nanopore protein monomer is an alpha-hemolysin monomer or variant thereof and the DNA binding domain is an Sso7d protein or variant thereof, such as an Sso7d-like protein. Also provided are nanopore protein assemblies incorporating the nanopore protein conjugates, along with methods of using the nanopore protein assemblies in sequencing reactions.