A method for synthesizing a target double stranded (ds) polynucleotide byproviding an oligonucleotide library within an array device that has a diversity of oligonucleotide library members, each of which has a different nucleotide sequence and is contained in a separate library containment in an aqueous solution. The library includes single stranded oligonucleotides and double stranded oligonucleotides with at least one overhang and covers at least 10,000 pairs of matching oligonucleotides. In a first step, at least a first pair of matching oligonucleotides are transferred transferred from the library into a first reaction containment using a liquid handler and the matching oligonucleotides are assembled, thereby obtaining a first reaction product comprising at least one overhang. Further reaction products are then likewise obtained and are assembled in a predetermined workflow using an algorithm, thereby producing said target ds polynucleotide with an overhang, optionally followed by a finalization step to prepare blunt ends.

A method for determining the number of nucleic acid molecules (NAMs) in a group of NAMs, comprising i) obtaining an amplified and mutagenized group of NAMs that was produced by a. subjecting the group of NAMs to a chemical mutagenesis which mutates only select nucleic acid bases in the group of NAMs at a rate of 10% to 90% thus forming a group of mutagenized NAMs (mNAMs), and b. amplifying the group of mNAMs; ii) obtaining sequences of the mNAMs in the group of amplified mNAMs; and iii) counting the number of different sequences obtained in step (ii) to determine the number of unique mNAMs in the group of mNAMS,
thereby determining the number of NAMs in the group of NAMs.

Disclosed are methods, components, compositions, and kits for preparing and identifying engineered E. coli ribosomes. The E. coli ribosomes may be prepared and identified under a set of defined conditions, such as in the presences of antibiotics, in order to obtain an engineered ribosome that is resistant to the antibiotic.

Methods of generating conditionally active biologic proteins, in particular therapeutic or diagnostic proteins, which are more active at an aberrant condition than at a normal physiological condition. The methods include discovery methods using libraries of proteins and assays employing physiological concentrations of components of bodily fluids. The conditionally active biologic proteins may be further evolved, conjugated to other molecules, masked, reduced in activity by attaching a cleavable moiety. Criteria for selecting starting proteins for the discovery methods, as well as formats of the proteins are also disclosed.

The invention describes a method for isolating one or more genetic elements encoding a gene product having a desired activity, comprising the steps of: (a) compartmentalising genetic elements into microcapsules; and (b) sorting the genetic elements which express the gene product having the desired activity; wherein at least one step is under microfluidic control. The invention enables the in vitro evolution of nucleic acids and proteins by repeated mutagenesis and iterative applications of the method of the invention.

The present invention relates to methods for the screening, identification and/or application of microorganisms of use in imparting beneficial properties to plants.

A method of preparing a conditionally active biologic protein by selecting a wild-type biologic protein, evolving the DNA which encodes the wild-type biologic protein using one or more evolutionary techniques to create mutant DNAs, expressing the mutant DNAs in a eukaryotic cell production host to obtain a mutant protein, subjecting the mutant protein and the wild-type protein to an assay under a normal physiological condition and to an assay under an aberrant condition, selecting a conditionally active mutant protein which exhibits at least one of: (a) a decrease in activity in the assay at the normal physiological condition compared to the wild-type protein, and (b) an increase in activity in the assay under the aberrant condition compared to the wild-type protein; and producing the conditionally active biologic protein in the same eukaryotic cell production host used in the expression step.

A HTP genomic engineering platform for improving filamentous fungal cells that is computationally driven and integrates molecular biology, automation, and advanced machine learning protocols is provided. This integrative platform utilizes a suite of HTP molecular tool sets to create HTP genetic design libraries, which are derived from, inter alia, scientific insight and iterative pattern recognition. Methods for isolating clonal populations derived from individual fungal spores 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.

Disclosed are a phosphinothricin dehydrogenase mutant, a recombinant bacterium and a one-pot multi-enzyme synchronous directed evolution method. The phosphinothricin dehydrogenase mutant, with an amino acid sequence as shown in SEQ ID No.1, is obtained by mutating alanine at position 164 to glycine, arginine at position 205 to lysine, and threonine at position 332 to alanine in a phosphinothricin dehydrogenase derived from Pseudomonas fluorescens. The recombinant bacterium is obtained by introducing a gene encoding the phosphinothricin dehydrogenase mutant into a host cell. The host cell can also incorporate a gene encoding a glucose dehydrogenase or a gene encoding a formate dehydrogenase to undergo synchronous directed evolution to achieve double gene overexpression. The one-pot multi-enzyme synchronous directed evolution method of the present invention can screen recombinant bacteria with greatly improved activity. Compared with other catalysis processes such as the transaminase method, the method for preparing L-PPT of the present invention features relatively simple process, high conversion of raw materials of up to 100%, and high stereo selectivity.