The present disclosure provides compositions and methods for polynucleotide synthesis in vitro, specifically the use of single-subunit RNA polymerases for synthesis and manufacturing of RNA.

The present disclosure provides RNA polymerase variants for high efficiency transcription.

Provided herein relates to DNA polymerase variants and kits including the same, where the DNA polymerase variant has an improved function and activity of performing template-independent nucleic acids synthesis using canonical nucleotides and non-canonical nucleotide analogues in a thermotolerant manner.

Vectors for cloning, maintaining and expressing a wide range of coding sequences in inducible T7 expression systems in Escherichia coli expression hosts are disclosed herein. Target genes that can be stably maintained and expressed include those that specify proteins that are highly toxic to the host cell. Different configurations of vectors and expression hosts provide different rates of transcription and translation of target genes and therefore different rates of accumulation of target proteins. Methods for cloning by asymmetric ligation and co-expression of more than one target protein in a single vector are also disclosed, as are variants of BL21(DE3) having lower basal transcription by T7 RNA polymerase.

The invention provides compounds of formula Ia, Ib, Ic, or as well as compositions comprising a compound of formula Ia-Id, methods of making such compounds, and methods of using such compounds, e.g., as inhibitors of bacterial RNA polymerase and as antibacterial agents. ##STR00001##

The present disclosure provides technologies for in vitro transcription reactions, particularly for production of pharmaceutical grade RNA, and in some embodiments for large scale production.

A method for the production of proteins used in the in vitro transcription (IVT) of messenger RNA (mRNA), wherein the proteins are evaluated for purity and efficacy by the efficiency with which mRNA synthetically derived therefrom, subsequently transfects cells and produces encoded proteins.

This application relates to mutant polymerases. This application discloses mutant phage-type RNA polymerases, such as a mutant T7, SP6, and T3 RNA polymerase, may use 2′-modified nucleoside triphosphates or deoxynucleotide triphosphates as substrates. Methods for producing nucleic acid molecules using these mutant polymerases are also disclosed.

The invention relates to constructs comprising a transmembrane protein pore subunit and a nucleic acid handling enzyme. The pore subunit is covalently attached to the enzyme such that both the subunit and enzyme retain their activity. The constructs can be used to generate transmembrane protein pores having a nucleic acid handling enzyme attached thereto. Such pores are particularly useful for sequencing nucleic acids. The enzyme handles the nucleic acid in such a way that the pore can detect its component nucleotides by stochastic sensing.

Provided are sequencing-by-binding methods of detecting cognate nucleotides using a crippled DNA polymerizing enzyme that possesses the ability to bind the next correct nucleotide downstream of a primer in a template-dependent fashion, but does not possess the activity needed to promote phosphodiester bond formation. Use of the crippled DNA polymerase permits interrogation of one nucleotide at a time, without incorporation of any nucleotide. Labeled nucleotides, such as fluorescently labeled nucleotides, can be used in conjunction with the crippled DNA polymerase to establish cognate nucleotide identity in a rapid manner.