An All-Inclusive Review of the Achievements and Trends in the Fast-Growing Protein Engineering Field From humble beginnings like making fire for mere survival, engineering now steadfastly penetrates all aspects of our lives and even life itself at the molecular level. Protein engineering is a molecular biological discipline focused on designing and constructing novel proteins with desired properties. The currently limited understanding of the relationship between protein structure and function greatly hinders rational protein design. However, despite great challenges, protein engineering has become a major molecular discipline with a large array of successful applications to many complex medicinal problems. Medicinal Protein Engineering sheds light on this largely unchartered field, covering major strategies for engineering of proteins with predetermined biological properties. It discusses computational approaches to protein design and experimental approaches to protein construction. This volume also explores the tight connection between protein and genetic engineering. It moves researchers beyond experimental protein construction and theoretical protein design to the medicinal applications of engineered proteins. Examines Medicinal Applications of Protein Engineering for the Diagnosis, Treatment, and Prevention of Diseases Focusing on the application of protein engineering to medicine, this seminal work outlines the appropriate techniques for studying protein properties and building mathematical engineering models of novel vaccines, diagnostic reagents, and therapeutic treatments. As a truly comprehensive assessment of the medical protein engineering research available and its future implications for disease control and prevention, this is an indispensable reference for biological researchers in this groundbreaking

Combining elements of biochemistry, molecular biology, and immunology, artificial DNA can be employed in a number of scientific disciplines. Some of the varied applications include site-specific mutagenesis, hybridization, amplification, protein engineering, anti-sense technology, DNA vaccines, protein vaccines, recombinant antibodies, screening for genetic and pathogenic diseases, development of materials with new biochemical and structural properties, and many more. Artificial DNA: Methods and Applications introduces the concept of artificial DNA that has been rationally designed and explains how it may be exploited in order to develop products that will achieve your intended purpose. The first part of the book covers methods of oligonucleotide synthesis and direct applications of synthetic DNA. The second part describes methods of gene assembly from synthetic oligonucleotides and applications of synthetic genes. The authors also discuss the different trends and future developments within each application area . With state-of-the art research, the contributing authors describe how to engineer proteins using rational and semi-rational design to exhibit the desired traits and detail the various amplification reactions and hybridization techniques for modeling evolution and for use in basic research. The only text devoted to this subject, Artificial DNA offers a comprehensive review that allows you to understand the strategy, design, and applications of synthetic oligonucleotides.

Combining elements of biochemistry, molecular biology, and immunology, artificial DNA can be employed in a number of scientific disciplines. Some of the varied applications include site-specific mutagenesis, hybridization, amplification, protein engineering, anti-sense technology, DNA vaccines, protein vaccines, recombinant antibodies, screening for genetic and pathogenic diseases, development of materials with new biochemical and structural properties, and many more.

Artificial DNA: Methods and Applications introduces the concept of artificial DNA that has been rationally designed and explains how it may be exploited in order to develop products that will achieve your intended purpose. The first part of the book covers methods of oligonucleotide synthesis and direct applications of synthetic DNA. The second part describes methods of gene assembly from synthetic oligonucleotides and applications of synthetic genes. The authors also discuss the different trends and future developments within each application area .

With state-of-the art research, the contributing authors describe how to engineer proteins using rational and semi-rational design to exhibit the desired traits and detail the various amplification reactions and hybridization techniques for modeling evolution and for use in basic research. The only text devoted to this subject, Artificial DNA offers a comprehensive review that allows you to understand the strategy, design, and applications of synthetic oligonucleotides.

An All-Inclusive Review of the Achievements and Trends in the Fast-Growing Protein Engineering Field

From humble beginnings like making fire for mere survival, engineering now steadfastly penetrates all aspects of our lives and even life itself at the molecular level. Protein engineering is a molecular biological discipline focused on designing and constructing novel proteins with desired properties. The currently limited understanding of the relationship between protein structure and function greatly hinders rational protein design. However, despite great challenges, protein engineering has become a major molecular discipline with a large array of successful applications to many complex medicinal problems.

Medicinal Protein Engineering sheds light on this largely unchartered field, covering major strategies for engineering of proteins with predetermined biological properties. It discusses computational approaches to protein design and experimental approaches to protein construction. This volume also explores the tight connection between protein and genetic engineering. It moves researchers beyond experimental protein construction and theoretical protein design to the medicinal applications of engineered proteins.

Examines Medicinal Applications of Protein Engineering for the Diagnosis, Treatment, and Prevention of Diseases

Focusing on the application of protein engineering to medicine, this seminal work outlines the appropriate techniques for studying protein properties and building mathematical engineering models of novel vaccines, diagnostic reagents, and therapeutic treatments. As a truly comprehensive assessment of the medical protein engineering research available and its future implications for disease control and prevention, this is an indispensable reference for biological researchers in this groundbreaking field.