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In Vitro Mutagenesis

Overview of attention for book
In Vitro Mutagenesis
Springer New York

Table of Contents

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    Book Overview
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    Chapter 1 Design and Validation of CRISPR/Cas9 Systems for Targeted Gene Modification in Induced Pluripotent Stem Cells.
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    Chapter 2 Mutagenesis and Genome Engineering of Epstein-Barr Virus in Cultured Human Cells by CRISPR/Cas9.
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    Chapter 3 Use of CRISPR/Cas Genome Editing Technology for Targeted Mutagenesis in Rice.
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    Chapter 4 All-in-One CRISPR-Cas9/FokI-dCas9 Vector-Mediated Multiplex Genome Engineering in Cultured Cells.
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    Chapter 5 CRISPR/Cas9-Mediated Mutagenesis of Human Pluripotent Stem Cells in Defined Xeno-Free E8 Medium.
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    Chapter 6 Development of CRISPR/Cas9 for Efficient Genome Editing in Toxoplasma gondii.
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    Chapter 7 Generation of Stable Knockout Mammalian Cells by TALEN-Mediated Locus-Specific Gene Editing.
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    Chapter 8 Efficient Generation of Gene-Modified Mice by Haploid Embryonic Stem Cell-Mediated Semi-cloned Technology.
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    Chapter 9 Insertion of Group II Intron-Based Ribozyme Switches into Homing Endonuclease Genes.
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    Chapter 10 Generating a Genome Editing Nuclease for Targeted Mutagenesis in Human Cells.
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    Chapter 11 Use of Group II Intron Technology for Targeted Mutagenesis in Chlamydia trachomatis.
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    Chapter 12 In Silico Approaches to Identify Mutagenesis Targets to Probe and Alter Protein-Cofactor and Protein-Protein Functional Relationships.
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    Chapter 13 In Silico Prediction of Deleteriousness for Nonsynonymous and Splice-Altering Single Nucleotide Variants in the Human Genome.
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    Chapter 14 In Silico Methods for Analyzing Mutagenesis Targets.
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    Chapter 15 Methods for Detecting Critical Residues in Proteins.
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    Chapter 16 A Method for Bioinformatic Analysis of Transposon Insertion Sequencing (INSeq) Results for Identification of Microbial Fitness Determinants.
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    Chapter 17 Application of In Vitro Transposon Mutagenesis to Erythromycin Strain Improvement in Saccharopolyspora erythraea.
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    Chapter 18 Engineering Gram-Negative Microbial Cell Factories Using Transposon Vectors.
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    Chapter 19 PERMutation Using Transposase Engineering (PERMUTE): A Simple Approach for Constructing Circularly Permuted Protein Libraries.
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    Chapter 20 Transposon Insertion Mutagenesis for Archaeal Gene Discovery.
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    Chapter 21 Genome-Wide Transposon Mutagenesis in Mycobacterium tuberculosis and Mycobacterium smegmatis.
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    Chapter 22 Multiple Site-Directed and Saturation Mutagenesis by the Patch Cloning Method.
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    Chapter 23 Seamless Ligation Cloning Extract (SLiCE) Method Using Cell Lysates from Laboratory Escherichia coli Strains and its Application to SLiP Site-Directed Mutagenesis.
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    Chapter 24 Facile Site-Directed Mutagenesis of Large Constructs Using Gibson Isothermal DNA Assembly.
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    Chapter 25 Revised Mechanism and Improved Efficiency of the QuikChange Site-Directed Mutagenesis Method.
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    Chapter 26 An In Vitro Single-Primer Site-Directed Mutagenesis Method for Use in Biotechnology.
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    Chapter 27 Use of Megaprimer and Overlapping Extension PCR (OE-PCR) to Mutagenize and Enhance Cyclodextrin Glucosyltransferase (CGTase) Function.
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    Chapter 28 Step-By-Step In Vitro Mutagenesis: Lessons From Fucose-Binding Lectin PA-IIL.
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    Chapter 29 Analytical Methods for Assessing the Effects of Site-Directed Mutagenesis on Protein-Cofactor and Protein-Protein Functional Relationships.
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    Chapter 30 Biochemical and Biophysical Methods to Examine the Effects of Site-Directed Mutagenesis on Enzymatic Activities and Interprotein Interactions.
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    Chapter 31 Use of Random and Site-Directed Mutagenesis to Probe Protein Structure-Function Relationships: Applied Techniques in the Study of Helicobacter pylori.
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    Chapter 32 Novel Random Mutagenesis Method for Directed Evolution.
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    Chapter 33 Random Mutagenesis by Error-Prone Polymerase Chain Reaction Using a Heavy Water Solvent.
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    Chapter 34 Development and Use of a Novel Random Mutagenesis Method: In Situ Error-Prone PCR (is-epPCR).
Attention for Chapter 15: Methods for Detecting Critical Residues in Proteins.
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Chapter title
Methods for Detecting Critical Residues in Proteins.
Chapter number 15
Book title
In Vitro Mutagenesis
Published in
Methods in molecular biology, January 2017
DOI 10.1007/978-1-4939-6472-7_15
Pubmed ID
27709579
Book ISBNs
978-1-4939-6470-3, 978-1-4939-6472-7
Authors

Nurit Haspel, Filip Jagodzinski

Editors

Andrew Reeves

Abstract

In proteins, certain amino acids may play a critical role in determining their structure and function. Examples include flexible regions, which allow domain motions, and highly conserved residues on functional interfaces, which play a role in binding and interaction with other proteins. Detecting these regions facilitates the analysis and simulation of protein rigidity and conformational changes, and aids in characterizing protein-protein binding. We present a protocol that combines graph-theory rigidity analysis and machine-learning-based methods for predicting critical residues in proteins. Our approach combines amino-acid specific information and data obtained by two complementary methods. One method, KINARI, performs graph-based analysis to find rigid clusters of amino acids in a protein, while the other method relies on evolutionary conservation scores to find functional interfaces in proteins. Our machine learning model combines both methods, in addition to amino acid type and solvent-accessible surface area.

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Mendeley readers

Mendeley readers

The data shown below were compiled from readership statistics for 7 Mendeley readers of this research output. Click here to see the associated Mendeley record.

Geographical breakdown

Country Count As %
Unknown 7 100%

Demographic breakdown

Readers by professional status Count As %
Student > Master 2 29%
Student > Bachelor 2 29%
Professor 1 14%
Student > Ph. D. Student 1 14%
Unknown 1 14%
Readers by discipline Count As %
Agricultural and Biological Sciences 3 43%
Immunology and Microbiology 2 29%
Biochemistry, Genetics and Molecular Biology 1 14%
Unknown 1 14%

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