De novo synthesized large libraries of nucleic acids are provided herein with low error rates. Further, devices for the manufacturing of high-quality building blocks, such as oligonucleotides, are described herein. Longer nucleic acids can be synthesized in parallel using microfluidic assemblies. Further, methods herein allow for the fast construction of large libraries of long, high-quality genes. Devices for the manufacturing of large libraries of long and high-quality nucleic acids are further described herein.

The present invention includes a multivalent glycan microarray for detection of glycan-binding proteins. The multivalent glycan microarray allows a multivalent presentation of glycan on a microarray substrate, which can enhance binding of the glycan binding protein to the glycan microarray. The multivalent microarray includes a solid substrate having one or more branched polymers bonded to it via one or more silane-based linker reagents. The branched polymer in turn is bonded to a glycan, via one or more bifunctional linkers to form the multivalent glycan microarray. Nonspecific binding of glycan binding proteins to the multivalent glycan microarray can be reduced by using a blocking reagent coated on to the microarray substrate, which includes a polyethylene glycol surfactant attached to the solid substrate via a self-crosslinking azido-functionalized silane. Methods for making multivalent glycan microarrays and methods for using same to detect glycan-binding proteins are also disclosed.

The present invention includes a multivalent glycan microarray for detection of glycan-binding proteins. The multivalent glycan microarray allows a multivalent presentation of glycan on a microarray substrate, which can enhance binding of the glycan binding protein to the glycan microarray. The multivalent microarray includes a solid substrate having one or more branched polymers bonded to it via one or more silane-based linker reagents. The branched polymer in turn is bonded to a glycan, via one or more bifunctional linkers to form the multivalent glycan microarray. Nonspecific binding of glycan binding proteins to the multivalent glycan microarray can be reduced by using a blocking reagent coated on to the microarray substrate, which includes a polyethylene glycol surfactant attached to the solid substrate via a self-crosslinking azido-functionalized silane. Methods for making multivalent glycan microarrays and methods for using same to detect glycan-binding proteins are also disclosed.

Provided herein are architectures and compositions of capture templates and macro capture templates, optionally attached to dendrimers, methods of using capture templates and/or macro capture templates, optionally attached to dendrimers to route coding templates, novel combinations including solid supports and capture templates and/or macro capture templates, optionally attached to dendrimers, methods of using novel combinations of solid supports and dendrimers and capture templates and/or macro capture templates to route coding templates, novel compositions which include capture templates and macro capture templates, optionally attached to dendrimers, hybridized to coding templates and novel compositions including solid supports, and capture templates and/or macro capture templates optionally attached to dendrimers hybridized to coding templates.

A system includes a synthesizer unit having a fluid input to receive fluids and a communication input to receive commands to synthesize data-encoded DNA sequences and cleave the DNA. A first flexible chemistry reaction chamber module may be fluidically coupled to the synthesizer unit to receive the data-encoded DNA sequences and amplify the sequences. A deposition unit may be fluidically coupled to the first flexible chemistry reaction chamber module to receive the amplified DNA sequences and encapsulate the amplified DNA sequences into one or more wells in a storage plate for storage and retrieval to and from a plate storage unit. Retrieved DNA may be processed and read by further units.

Provided are an isolated oligonucleotide and a use thereof in nucleic acid sequencing, wherein the isolated oligonucleotide comprises a first strand, wherein the 5′-end nucleotide of the first strand has a phosphate group, and the 3′-end nucleotide of the first strand is a dideoxynucleotide, and a second strand, wherein the 5′-end nucleotide of the second strand does not have a phosphate group, and the 3′-end nucleotide of the second strand is a dideoxynucleotide, wherein the first strand is longer than the second strand in length, and a double-stranded structure is formed between the first strand and the second strand.

There is disclosed a process for in vitro synthesis and assembly of long, gene-length polynucleotides based upon assembly of multiple shorter oligonucleotides synthesized in situ on a microarray platform. Specifically, there is disclosed a process for in situ synthesis of oligonucleotide fragments on a solid phase microarray platform and subsequent, “on device” assembly of larger polynucleotides composed of a plurality of shorter oligonucleotide fragments.

The present invention is related to genomic nucleotide sequencing. In particular, the invention describes a paired end sequencing method that enables the sequencing of unique read pairs by co-localizing both 5′ ends on a single emulsion polymerase chain reaction bead. The method may use a customized forked adaptor primer pair that is compatible with massively parallel sequencing techniques. The compositions and methods disclosed herein contemplate sequencing complex genomes, amplified genomic regions, as well as detecting chromosomal structural rearrangements.

The present invention is related to genomic nucleotide sequencing. In particular, the invention describes a paired end sequencing method that enables the sequencing of unique read pairs by co-localizing both 5′ ends on a single emulsion polymerase chain reaction bead. The method may use a customized forked adaptor primer pair that is compatible with massively parallel sequencing techniques. The compositions and methods disclosed herein contemplate sequencing complex genomes, amplified genomic regions, as well as detecting chromosomal structural rearrangements.

Provided herein are methods and compositions relating to TIGIT libraries having nucleic acids encoding for a scaffold comprising a TIGIT domain. TIGIT libraries described herein encode for immunoglobulins such as antibodies.