54 results about "DNA shuffling" patented technology

Disclosed is a process of performing Sexual PCR which includes generating random polynucleotides by interrupting or blocking synthesis or amplification process to slow or halt synthesis or amplification of at least one polynucleotides, optionally amplifying the polynucleotides, and reannealing the polynucleotides to produce random mutant polynucleotides. Also provided are vector and expression vehicles including such mutant polynucleotides, polypeptides expressed by the mutant polynucleotides and a method for producing random polypeptides.

Methods of shuffling DNA to obtain recombinant herbicide tolerance nucleic acids encoding proteins having new or improved herbicide tolerance activities, libraries of shuffled herbicide tolerance nucleic acids, transgenic plants and DNA shuffling mixtures are provided.

The present invention relates to codon optimization utilizing DNA shuffling. A method of producing gene sequences optimized for a desired functional property is described involving synthesizing a library of parental codon variant genes encoding some or all codon choices at some or all amino acid positions of a gene, reassorting the variant codons among the parental codon variant genes using DNA shuffling thereby forming progeny codon variant genes, expressing the progeny codon variant genes in a host; and screening or selecting for progeny codon variant genes encoding a desired functional property.

The present invention provides compositions and improved methods for multi-site directed mutagenesis and DNA shuffling. The present compositions and methods provide increased mutation frequency and increased number of transformants which allow one to sequence only a few clones in order to identify the correct mutants and to obtain the desired mutant by screening large number of transformants in a short time. Moreover, the inclusion of FEN-1, PEF and optimized buffer and cycling conditions provided in the present invention should also facilitate random mutagenized library construction and the mutagenesis of large or difficult templates.

The present invention relates to novel monooxygenase nucleic acids and polypeptides created using mutagenesis, DNA shuffling, or both, in a single iteration or multiple iterations, and methods for their creation and use. The monooxygenase enzymes of the present disclosure have particular utility as biocatalysts in industrial chemical redox reactions, such as the oxidation of aromatic hydrocarbons, for example, toluene, benzene, or nitrobenzene, into industrially desirable products. The systems and processes of the present invention are especially useful for the coupled synthesis and recovery of catechols, methylcatechols, resorcinols, methylresorcinols, hydroquinones, methylhydroquinones, hydroxybenzenes, cresols, nitrobenzenes, and nitrohydroxyquinones.

Disclosed is a process of performing "Sexual" PCR which includes generating random polynucleotides by interrupting or blocking a synthesis or amplification process to show or halt synthesis or amplification of at least one polynucleotide, optionally amplifying the polynucleotides, and reannealing the polynucleotides to produce random mutant polynucleotides. Also provided are vector and expression vehicles including such mutant polynucleotides, polypeptides expressed by the mutant polynucleotides and a method for producing random mutant polypeptides.

The invention relates to an in vitro molecular directed evolution method for reshaping antibody, which integrates ribosome displaying technology with DNA reorganization technology by designing reshaped antibody molecules, thus directly obtaining the extracorporal molecules of the single-chain antibody reshaped orientation.

The present invention provides methods for obtaining pest resistance genes that are improved over naturally occurring genes for conferring pest resistance to plants. The method involves the use of DNA shuffling of pest resistance genes to generate a library of recombinant pest resistance genes, and then screening the library to identify those genes that show an improved property of interest.

The invention relates to an in-vitro directed coevolution method for modifying L-phenylalanine gene engineering strains, which is realized in a way that: using genes aroG and pheA on an L-phenylalanine gene engineering strain constructed in the room as a whole; carrying out the in-vitro directed coevolution modification by using an error-prone PCR technology and a recombinant DNA technology; and screening to obtain a mutant strain, of which the yield of L-phenylalanine is increased by 114%. In the invention, by modifying the gene formed by coupling and connecting aroG and pheA in series, the key genes aroG and pheA in the metaboly process of the L-phenylalanine are used as a whole to carry out the directed modification, thereby obtaining a new metabolic balance, so that the expressed enzyme has high-efficiency catalytic activity and can resist the feedback inhibition of the L-phenylalanine, thereby obtaining the new modified high-yield L-phenylalanine gene engineering strain by screening. The method can provide an example for modifying the acid production rate of any amino acid gene engineering strain.

The invention belongs to the field of genetic engineering, relates to separation, determinate evolution in vitro and functional identification of a resistance gene capable of degrading herbicide glyphosate efficiently, and further relates to the resistance gene capable of degrading herbicide glyphosate in plants. The nucleotide sequence of the gene B3S1 is as shown in the figure SEQ ID NO: 1; the amino acid sequence of encoded protein of the resistance gene is as shown in the figure SEQ ID NO: 2. According to the invention, the glycine oxidase (thiO) from marine bacteria bacillus cereus (Bacillus cereus) is amplified, and two rounds of random mutagenesis and a round of DNA shuffling test are performed continuously on the glycine oxidase (thiO), and combined with an activity screening technology on the basis of T7 phage pyrolysis-horseradish peroxidase / dianisidine enzyme coupling, the final glyphosate oxidase mutant B3S1 is obtained. The function of the gene and the application approach of the gene in degrading the resistance of herbicide glyphosate are proved in the invention.

The method to prepare high active extended spectrum beta-lactamase through directed evolution in vitro of the invention belongs to medical bioengineering technical field. In particular, the invention adopts two directed evolution strategies of error-prone PCR and DNA shuffling to transform a lab strain plant which contains TEM-1 gene. The substrate spectrum enzymes of the mutated strain plant and the wild strain plant, and the activity of the substrate spectrum enzymes are compared, showing that the original substrate spectrum is enlarged because of mutation and the degradability of the third representative generation of beta-lactam antibiotics ceftazidime (CAZ) and the cefotaxime (CTX) is improved from zero to a specific activity of 43IU / mg to 78IU / mg.

Polypeptides with desirable biophysical properties such as solubility, stability, high expression, monomericity, binding specificity or non-aggregation, including monomeric human VHs and VLs, are identified using a high throughput method for screening polypeptides, comprising the steps of obtaining a phage display library, allowing infection of a bacterial lawn by the library phage, and identifying phage which form larger than average plaques on the bacterial lawn. Sequences of monomeric human VHs and VLs are identified, which may be useful for immunotherapy or as diagnostic agents. Multimer complexes of human VHs and VLs are also identified. The VHs and VLs identified may be used to create further libraries for identifying additional polypeptides. Further, the VHs and VLs may be subjected to DNA shuffling to select for improved biophysical properties.

Compositions and methods for protecting a plant from a pathogen, particularly a fungal pathogen, are provided. Compositions include amino acid sequences, and variants and fragments thereof, for novel variants of antipathogenic polypeptides generated through DNA shuffling that exhibit improved antipathogenic activity. Polynucleotides that encode the antipathogenic polypeptides are also provided. A method for inducing pathogen resistance in a plant using the polynucleotides disclosed herein is further provided. Compositions comprising an antipathogenic polypeptide or a microorganism comprising an antipathogenic polynucleotide of the invention in combination with a carrier and methods of using these compositions to protect a plant from a pathogen are further provided. Plants, plant cells, seeds, and microorganisms comprising an antipathogenic polynucleotide or polypeptide of the invention are also disclosed.

The present invention provides a method for shuffling DNA to obtain a recombinant herbicide tolerance nucleic acid, the protein encoded by the nucleic acid has new or improved herbicide tolerance activity, and the invention also provides the shuffled herbicide tolerance nucleic acid Libraries, transgenic plants and DNA shuffling mixtures.

The invention provides a novel plant strong salt tolerant gene AtNHXS1 acquired through DNA reshuffling technology, and the ionic transport activity of Na+ / H+ antiporter protein coded by the gene is stronger than that of wild Na+ / H+ antiporter protein ATNHX1. A nucleotide sequence of the gene as shown in SEQ ID NO:1 also comprises genes of the nucleotide sequence of sequence 1 in a sequence table with the homology between 70 and 100 percent, or a nucleotide sequence of an amino acid sequence of sequence 2 in a coded sequence table. The new Na+ / H+ antiporter has a protein of the amino acid sequence of sequence 2 in the sequence table, protein of the amino acid sequence of the sequence 2 with the homology between 70 and 100 percent, or protein which replaces, deletes or adds one or a plurality of amino acids in the amino acid sequence of the sequence 2 with the same homology. The invention also provides the construction of recombinant vector, the transgenic plant and other methods so as to apply the gene and the protein, thereby cultivating a novel variety of transgenic plant with strong capacity of salt tolerance or other improved biologic characters.

The invention relates to the field of plant genetic engineering and provides a novel plant strong salt-tolerant gene NHXS1 obtained by a restructuring technology. A nucleotide sequence of the plant strong salt-tolerant gene NHXS1 is SEQ ID NO: 1, or a DNA sequence which has 70 to 100 percent homology with the SEQ ID NO: 1 nucleotide sequence or a DNA sequence for coding a protein sequence of SEQ ID NO: 2. Na + / H + antiporter NHXS1 colded by the gene has stronger ion transport activity than the wild-type Na + / H + antiporter AtNHX1. The invention also provides methods for construction of recombinant vectors and transgenic plants to apply the genes and proteins, and can culture a novel breed of transgenic plant with stronger salt-tolerant property or other improved biological characteristics.

The invention relates to an artificially modified glucose oxidase gene and expression application thereof, belonging to the fields of protein or enzyme preparation modification engineering and glucose oxidase production. The artificially modified glucose oxidase gene aims to further enhance enzyme activity on the basis of the existing glucose oxidase. An irrational means DNA (deoxyribonucleic acid) shuffling technique in protein or enzyme preparation modification engineering is utilized to modify a glucose oxidase gene derived from Aspergillus niger Z-25; and a gene segment subjected to DNaseI random cutting is subjected to the DNA shuffling technique to recombine the segment into a complete variant gene, and the complete variant gene is connected with a shuttling expression plasmid and integrated into the yeast genome. The strain with obviously higher enzyme activity is screened from the mutant library, and the variant sequence is disclosed as SEQ ID NO.2. In a 3L scale-up experiment of yeast, the end enzyme activity of the glucose oxidase reaches the higher level. Finally, in the aspect of enzyme activity and genes, the obtained high-enzyme-activity expression strain has favorable hereditary.

The invention discloses a method for de novo synthesis of a library by using a chip synthesized oligonucleotide library for DNA shuffling. The method mainly comprises the following steps: cutting a parent sequence into oligonucleotide sequences by combining comparison software; carrying out high-throughput error correction on an oligonucleotide library by using a mismatch binding protein MutS immobilized cellulose column; and carrying out full-length recombinant library assembly by using the cut oligonucleotides. Compared with the existing method, the method disclosed by the invention has theadvantages of high recombination rate, reduced difficulty of assembling into a full-length gene sequence, reduced synthesis cost, improved diversity of the sequence, improved accuracy of the oligo pool, improved fidelity of the synthesized gene library and improved probability of recombination.

The invention provides a method for carrying out directional evolution on a gene promoter. The method comprises the following steps: amplifying the promoter by adopting an error-prone PCR technology, thus obtaining a group of promoter sequences with high mutation frequency; removing harmful mutation by adopting a DNA shuffling technology, and collecting beneficial mutation, thus obtaining the promoter after shuffling; forming an expression cassette by adopting the recombinant promoter and a galactosidase gene, transforming host cells by adopting the expression cassette, and carrying out blue and white spot screening and enzyme activity determination, thus obtaining the target mutation promoter. With the method provided by the invention, the functional region of the gene promoter does not need to be analyzed, the cost is low, the operation is efficient, rapid, easy and convenient, the success rate is high, and the method is suitable for carrying out directional evolution on gene promoters of escherichia coli or other bacteria, fungi and mammalian cells.

The invention relates to a simple and efficient gene in vitro directed evolution system based on half-reasoning design; the system can achieve larger mutation potential and more definite mutation region compared with the conventional reshuffle mutation by combining DNA reshuffle mutation and the half-reasoning design and can provide more diversified mutant population for the modification of gene and protein, wherein, the mutant sites of the diversified mutant population are positioned in critical area.. With the combination of a screening system, reliable improved gene or protein can be obtained more easily; moreover, the system of the invention has effectiveness as well as simple and convenient operation.

Compositions and methods for protecting a plant from a pathogen, particularly a fungal pathogen, are provided. Compositions include amino acid sequences, and variants and fragments thereof, for novel variants of antipathogenic polypeptides generated through DNA shuffling that exhibit improved antipathogenic activity. Polynucleotides that encode the antipathogenic polypeptides are also provided. A method for inducing pathogen resistance in a plant using the polynucleotides disclosed herein is further provided. Compositions comprising an antipathogenic polypeptide or a microorganism comprising an antipathogenic polynucleotide of the invention in combination with a carrier and methods of using these compositions to protect a plant from a pathogen are further provided. Plants, plant cells, seeds, and microorganisms comprising an antipathogenic polynucleotide or polypeptide of the invention are also disclosed.

The present invention belongs to the technical field of DNA shuffling, and specifically discloses a bacterial outer membrane protein ompAs-19 after DNA shuffling and application thereof as an immunomodulator. The invention for the first time uses the DNA shuffling technology combined with immunological research; the outer membrane proteins of OmpA vibrio alginolyticus, Vibrio parahaemolyticus, Edwardsiella tarda and Escherichia coli are research objects; DNA shuffling technology is employed to obtain the bacterial outer membrane protein ompAs-19 after DNA shuffling, and the amino acid sequence is shown as SEQ ID NO: 2. The bacterial outer membrane protein ompAs-19 after DNA shuffling has high immune protection to vibrio alginolyticus, and reaches relative immune protective rate (RPS) of 100%. In addition, the bacterial outer membrane protein ompAs-19 after DNA shuffling also shows cross immunogenicity to Edwardsiella tarda and the reaches immune protective rate (RPS) of 85.71%. The results indicate that No.19 shuffled OmpA (ompAs-19) can be used as a vaccine component.

The invention provides a method for improving riboflavin production capacity of escherichia coli engineering bacteria by using DNA shuffling, and relates to the field of genetic engineering, and the method comprises the following steps: constructing riboflavin-producing escherichia coli engineering bacteria containing 26 genes; carrying out DNA rearrangement and directional screening on the T7RNA polymerase gene expression unit, and extracting to obtain a first batch of positive plasmids; carrying out DNA rearrangement and directional screening on a riboflavin biosynthesis and transport system, and extracting to obtain a second batch of positive plasmids; carrying out DNA rearrangement and directional screening on the Escherichia coli sigma factor gene, and extracting to obtain a third batch of positive plasmids; introducing the third batch of plasmids into different chassis cells to obtain recombinant strains; and selecting the positive strain with the highest riboflavin yield. The toxicity problem of T7RNAP to an escherichia coli host in the construction process of the riboflavin-producing escherichia coli engineering bacteria, the feedback inhibition problem of a product and the moderate and coordinated expression problem of a constructed riboflavin biosynthetic gene are effectively eliminated. The efficiency and the yield of biosynthesis of riboflavin by the escherichia coli engineering strain are further improved.