The present disclosure provides T7 RNA polymerase variants with enhanced transcriptional activity, and methods of using such variants to produce modified oligonucleotides, such as 2′-modified oligonucleotides. These polymerase variants and methods thereof improve the transcription yield of modified oligonucleotides.

A method for the expression of a protein of interest by a bacterium, notable in that it comprises the culturing of a bacterium temporarily or continuously expressing an Hsp protein, in that said bacterium also comprises a nucleic acid sequence, encoding a protein of interest, under the control of a lac promoter and in that said bacterium is cultured in a medium which does not contain IPTG or a metabolized molecule in such a way as to automatically induce the induction of transcription from the lac promoter.

Expression vectors ideal for use in vaccinating individuals against disease based on vaccinia virus and other chordopoxviruses having high expression of recombinant genes and low expression of vector genes in target animals, and low expression of recombinant genes and high expression of vector genes in cells used for propagation.

Provided herein, in some aspects, are methods and compositions for cell-free production of ribonucleic acid.

A bacteriophage RNA polymerase variant is provided. In some embodiments, the variant may have increased thermostability relative to the corresponding wild type bacteriophage RNA polymerase and/or wild type T7 RNA polymerase. Compositions, kits and methods that employ the variant are also provided.

Some aspects of this disclosure provide methods for phage-assisted continuous evolution (PACE) of proteases. Some aspects of this invention provide methods for evaluating and selecting protease inhibitors based on the likelihood of the emergence of resistant proteases as determined by the protease PACE methods provided herein. Some aspects of this disclosure provide strategies, methods, and reagents for protease PACE, including fusion proteins for translating a desired protease activity into a selective advantage for phage particles encoding a protease exhibiting such an activity and improved mutagenesis-promoting expression constructs. Evolved proteases that recognize target cleavage sites which differ from their canonical cleavage site are also provided herein.

Described herein are stabilized polymerase compositions comprising a polymerase and an polymerase stabilizing agent, such as a non-detergent zwitterionic stabilizer or a cationic ester disclosed, for use in nucleic acid amplification or nucleic acid sequencing. Compositions are provided for the stabilization of one or more polymerases in a single stabilized liquid formulation. Also disclosed are methods for making and using stabilized polymerase compositions and kits for nucleic acid amplification and sequencing comprising the stabilized polymerase compositions provided.

The present invention provides engineered RNA polymerase variants and compositions comprising these variants. The present invention further provides engineered T7 RNA polymerase variants and compositions comprising these variants. These variants have been evolved for selective incorporation of the m7G(5′)ppp(5′)m7G cap analog over GTP at the initiation of in vitro transcription. The present invention also provides methods for selective capping of RNA transcripts.

The present invention relates to a method for producing a molecule of interest in bacteria which is based on reversible growth arrest of the bacteria at cellular growth global control system level, thus allowing an improved yield of production of said molecule of interest.

Provided are a beta prime subunit mutant of RNA polymerase, a microorganism of the Corynebacterium genus including a polynucleotide coding the same, and a method for producing L-lysine by culturing the same.