Abstract: Compositions and methods for the autonomous in vitro evolution of molecules having specific properties, employing one-pot continuous evolution are disclosed.

Abstract: The invention provides a method for generating a polynucleotide sequence or population of sequences from parent polynucleotide sequences, the method comprising the steps of (a) providing a first population of polynucleotide molecules and a second population of polynucleotide molecules, the first and second populations together constituting plus and minus strands of parent polynucleotide sequences, (b) digesting the first and second populations of polynucleotide molecules with a nuclease to generate polynucleotide fragments, (c) contacting said polynucleotide fragments generated from the plus strands with fragments generated from the minus strands and (d) amplifying the fragments that anneal to each other to generate at least one polynucleotide sequence encoding one or more protein motifs having an altered amino acid sequence as compared to those encoded by the parent polynucleotides, wherein the degree of sequence variability in a selected region of the at least one polynucleotide molecule produced in step (d

Abstract: The invention provides a method for producing polymers having a desirable property, for example, catalytic activity or binding activity, via evolutionary nucleic acid-mediated chemistry.

Abstract: A novel method for prediction of the degree of heterotic phenotypes in plants is disclosed. Structural variation analyses of the genome are used to predict the degree of a heterotic phenotype in plants. In some examples, copy number variation is used to predict the degree of heterotic phenotype. In some methods copy number variation is detected using competitive genomic hybridization arrays. Further, methods for optimizing the arrays are disclosed, together with kits for producing such arrays, as well as hybrid plants selected for development based on the predicted results.

Abstract: The present invention includes compositions and methods for contacting one or more cells with a random RNA-containing library, treating the contacted cells and with a denaturing agent or digestion with one or more nucleases, and extracting from the cells one or more internalized nucleic acids resistant to the nucleases or denaturants.

Abstract: Methods are provided for the evolution of proteins of industrial and pharmaceutical interest, including methods for effecting recombination and selection. Compositions produced by these methods are also disclosed.

Abstract: The invention relates to a method for synthesizing templated molecules attached to the templated which directed the synthesis thereof. The method involves a template, a scaffold functional entity and a functional entity attached to a building block, which, in turn, is attached the template. The scaffold functional entity and the functional entity of the building block are both provided with complementary dimerization domains allowing the functional entities to come into close proximity when the complementary domains interact with to each other. The method may be used for generating libraries of templated molecules which may be selected for biological activity.

Abstract: The invention provides directed evolution methods for improving the folding, solubility and stability (including thermostability) characteristics of polypeptides. In one aspect, the invention provides a method for generating folding and stability-enhanced variants of proteins, including but not limited to fluorescent proteins, chromophoric proteins and enzymes. In another aspect, the invention provides methods for generating thermostable variants of a target protein or polypeptide via an internal destabilization baiting strategy. Internally destabilization a protein of interest is achieved by inserting a heterologous, folding-destabilizing sequence (folding interference domain) within DNA encoding the protein of interest, evolving the protein sequences adjacent to the heterologous insertion to overcome the destabilization (using any number of mutagenesis methods), thereby creating a library of variants. The variants in the library are expressed, and those with enhanced folding characteristics selected.

Abstract: The present invention provides methods and systems for the capture and enrichment of target nucleic acids and analysis of the enriched target nucleic acids. In particular, the present invention provides for the enrichment of targeted sequences in a solution based format.

Abstract: The present invention provides novel methods to identify polypeptide ligands for Toll-like Receptors (TLRs), such as TLR2, TLR4 and TLR5. The method involves the use of phage display technology in an iterative biopanning procedure. The invention also provides polypeptide TLR ligands identified by the methods of the invention. In preferred embodiments, the polypeptide TLR ligands so identified modulate TLR signaling and thereby regulate the Innate Immune Response. The invention also provides vaccines comprising a polypeptide TLR ligand identified by the methods of the invention and an antigen. The invention also provides methods of modulating TLR signaling using the polypeptide TLR ligands and vaccines of the invention.

Abstract: Nature evolves biological molecules such as proteins through iterated rounds of diversification, selection, and amplification. The power of Nature and the flexibility of organic synthesis are combined in nucleic acid-templated synthesis. The present invention provides a variety of template architectures for performing nucleic acid-templated synthesis, methods for increasing the selectivity of nucleic acid-templated reactions, methods for performing stereoselective nucleic acid-templated reactions, methods of selecting for reaction products resulting from nucleic acid-templated synthesis, and methods of identifying new chemical reactions based on nucleic acid-templated synthesis.

Abstract: The instant invention comprises a process for selecting and manufacturing antibodies useful for therapeutic, prophylactic, diagnostic or research purposes using epitope peptide mixtures synthesized by the solid phase synthesis, such process defined by a set of rules regarding the identity and the frequency of occurrence of amino acids that substitute a base or native amino acid of a known epitope. The resulting antibodies are related to but distinct from antibodies that bind to the known epitope.

Abstract: The present invention provides a device and methods for the detection and quantification of one or more target agents in a sample by rapid and specific electrochemical detection. The present invention includes kits, devices and compositions capable of performing rapid, specific and accurate detection of one or more target agents in a sample.

Abstract: In silico nucleic acid recombination methods, related integrated systems utilizing genetic operators and libraries made by in silico shuffling methods are provided.

Abstract: The present invention concerns a protein mixture comprising at least a first fusion protein comprising a protein or protein fragment, and an interaction domain and a protein translocation sequence, which effects that the fusion protein upon expression in a bacterium is translocated through the cytoplasmic membrane in an essentially unfolded state and at least a second fusion protein comprising a protein or protein fragment, and an interaction domain and a protein translocation sequence which effects that the fusion protein is translocated through the cytoplasmic membrane upon expression in a bacterium in an essentially folded state, wherein the interaction domain of the first protein can bind to those of the second protein.

Abstract: The present invention is directed to a method for reducing the complexity of a nucleic acid sample in a reproducible manner by enriching for specific nucleic acid target sequences in the population of nucleic acids. More specifically, the invention relates to a method for enriching specific target sequences in a population using libraries of oligonucleotides.

Abstract: Nature evolves biological molecules such as proteins through iterated rounds of diversification, selection, and amplification. The present invention provides methods, compositions, and systems for synthesizing, selecting, amplifying, and evolving non-natural molecules based on nucleic acid templates. The sequence of a nucleic acid template is used to direct the synthesis of non-natural molecules such as unnatural polymers and small molecules. Using this method combinatorial libraries of these molecules can be prepared and screened. Upon selection of a molecule, its encoding nucleic acid template may be amplified and/or evolved to yield the same molecule or related molecules for re-screening. The inventive methods and compositions of the present invention allow for the amplification and evolution of non-natural molecules in a manner analogous to the amplification of natural biopolymer such as polynucleotides and protein.

Abstract: A series of methods that utilize the incremental truncation of nucleic acids are described to create a plurality of modified nucleic acids and hybrid polypeptides. A plurality of substantially all possible single base-pair deletions of a given nucleic acid sequence is created. A method of making shuffled incremental truncated nucleic acids, which is independent of nucleic acid sequence homology, is also described. These methods can be used in protein engineering, protein folding, protein evolution, and the chemical synthesis of novel hybrid proteins and polypeptides.

Abstract: The present invention is generally directed to the evolution of new metabolic pathways and the enhancement of bioprocessing through a process herein termed recursive sequence recombination. Recursive sequence recombination entails performing iterative cycles of recombination and screening or selection to “evolve” individual genes, whole plasmids or viruses, multigene clusters, or even whole genomes. Such techniques do not require the extensive analysis and computation required by conventional methods for metabolic engineering.

Abstract: The present invention relates to a novel method for analyzing nucleic acid sequences based on real-time detection of DNA polymerase-catalyzed incorporation of each of the four nucleotide bases, supplied individually and serially in a microfluidic system, to a reaction cell containing a template system comprising a DNA fragment of unknown sequence and an oligonucleotide primer. Incorporation of a nucleotide base into the template system can be detected by any of a variety of methods including but not limited to fluorescence and chemiluminescence detection. Alternatively, microcalorimetic detection of the heat generated by the incorporation of a nucleotide into the extending template system using thermopile, thermistor and refractive index measurements can be used to detect extension reactions.

Abstract: Methods for improving antibodies by a variety of DNA diversification and selection procedures are provided. Improvements include increases in affinity, alterations in specificity and effector function, as well as reduced antigenicity, e.g. humanization. Libraries of recombinant antibody sequences are provided, as are cells expressing members of such libraries. Novel phage display vectors are provided. Methods for the coevolution of an antibody and its cognate antigen are provided. Coevolution is used to evolve HIV envelope proteins with increased antigenicity and broadly neutralizing antibodies that interact therewith. Methods of improving antibodies for use in the detection of biological warfare agents are provided.

Abstract: The present invention provides novel methods for reducing the complexity of a genomic sample for further analysis such as direct DNA sequencing, resequencing or SNP calling. The methods use pre-selected immobilized oligonucleotide probes to capture target nucleic acid molecules from a sample containing denatured, fragmented genomic nucleic acid. The disclosed method provides for cost-effective, flexible and rapid enrichment of target nucleic acid from complex biological samples.

Abstract: The present invention provides novel methods for reducing the complexity of preferably a genomic sample for further analysis such as direct DNA sequencing, resequencing or SNP calling. The methods use pre-selected immobilized oligonucleotide probes to capture target nucleic acid molecules from a sample containing denatured, fragmented (genomic) nucleic acids for reducing the genetic complexity of the original population of nucleic acid molecules.

Abstract: The invention relates to the use of protein design automation (PDA) to generate computationally prescreened secondary libraries of proteins, and to methods and compositions utilizing the libraries.

Abstract: The present invention relates to a high efficiency method of expressing immunoglobulin molecules in eukaryotic cells. The invention is further drawn to a method of producing immunoglobulin heavy and light chain libraries, particularly using the trimolecular recombination method, for expression in eukaryotic cells. The invention further provides methods of selecting and screening for antigen-specific immunoglobulin molecules, and antigen-specific fragments thereof. The invention also provides kits for producing, screening and selecting antigen-specific immunoglobulin molecules. Finally, the invention provides immunoglobulin molecules, and antigen-specific fragments thereof, produced by the methods provided herein.

Abstract: The present invention provides a novel method for specifically isolating and separating large segments of genomic DNA that can subsequently be used to determine a genomic haplotype. The invention relies on using a solid phase having a flat surface arrayed with oligonucleotides designed to specifically hybridize to each particular haplotype of an individual sample, e.g., oligonucleotides designed to specifically hybridize with each of the two HLA-B haplotypes, HLA-A, HLA-C, HLA-DR, HLA-DQ, and the like. The genomic DNA is contacted and hybridized to the arrayed oligonucleotides to form a genomic DNA/oligonucleotide complex. The excess genomic DNA is washed away and the haplotype separated genomic DNA is denatured from the oligonucleotide probe and collected. The method of the present invention allows for the separation of genomic DNA fragments of between approximately 2 to about 4 megabases (Mb).

Abstract: The present invention relates to a method for in vitro creation of molecular libraries evolution of protein function. Particularly, it relates to variability and modification of protein function by shuffling polynucleotide sequence segments. A protein of desired characteristics can be obtained by incorporating variant peptide regions (variant motifs) into defined peptide regions (scaffold sequence). The variant motifs can be obtained from parent DNA which has been subjected to mutagenesis to create a plurality of differently mutated derivatives thereof or they can be obtained from in vivo sequences. These variant motifs can then be incorporated into a scaffold sequence and the resulting coded protein screened for desired characteristics. This method is ideally used for obtaining antibodies with desired characteristics by isolating individual CDR DNA sequences and incorporating them into a scaffold which may, for example, be from a totally different antibody.

Abstract: Viruses expressing ligands on their surfaces are used as a detection means for the related polypeptide which binds the ligand. Multiple copies of the ligand can be expressed on the viral surface. These viruses may be used to detect polypeptides, cells, receptors and channel proteins.