Probing the Mechanism of HIV-1 Protease Through Total Chemical Synthesis
Probing the Mechanism of HIV-1 Protease Through Total Chemical Synthesis

Author: Manuel Baca

Publisher:

Published: 1994

Total Pages: 480

ISBN-13:

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Total chemical synthesis has been used to explore structure-function relationships of the protease from human immunodeficiency virus 1 (HIV-1 protease). Analogues of this enzyme were prepared by conventional stepwise solid phase peptide synthesis and by chemical ligation of unprotected peptide segments. These analogues contained unnatural elements of structure, each designed to address a specific aspect of HIV-1 protease structure-function. Replacement of a surface [beta]-turn in each subunit of the homodimeric enzyme with a constrained, type II [prime] [beta]-turn mimic produced a fully active enzyme analogue with enhanced resistance to thermal inactivation. These results indicate that the precise geometry of this [beta]-turn is not critical for activity, and that replacement of native sequence with a rigid [beta]-turn mimic can lead to superior protein stability. Mass spectrometric and NMR experiments were designed to study the properties of a solution enzyme-inhibitor complex. No evidence for a specifically bound water molecule was found in the noncovalent ternary complex between the homodimeric enzyme and a reversible substrate-based inhibitor as detected by mass spectrometry. Bound water is reputedly involved in mediating hydrogen bonds between the enzyme flaps and substrate P2 and P1 [prime] carbonyls. The mode of binding and catalytic contribution of these enzyme-substrate hydrogen bonds was also investigated. An analogue of HIV-1 protease was designed in which the functionally relevant amide -CONH- linkage between residues Gly[49]-Ile[50] in each flap was replaced by an isosteric thioester -COS- bond. The catalytic activity (kcat) of the backbone modified enzyme was reduced approximately 3000 fold compared to the native amide bond-containing enzyme. This result confirms that backbone hydrogen bonds from the enzyme flaps to substrate are important for the catalytic function of the HIV-1 protease. These hydrogen bonds were further studied by removing the hydrogen bonding potential from one flap only. Existing peptide ligation methods were adapted to allow the linking of multiple peptide segments. Using these new methods, a tethered dimer analogue of HIV-1 protease was prepared in which the Gly[49]-Ile[50] amide bond was replaced in one subunit only by an ester -COO- bond. The kcat for this tethered dimer analogue was reduced only twofold. This suggests that both flap-substrate hydrogen bonds may originate from only a single flap, and not symmetrically from each flap as has been observed crystallographically. This hydrogen bonding pattern would coincide with that observed for the related pepsin-like aspartic proteases. Elucidation of the mechanistically relevant pattern of enzyme-substrate hydrogen bonding could have important applications to the design of HIV-1 protease inhibitors.

Computational Drug Discovery and Design
Computational Drug Discovery and Design

Author: Riccardo Baron

Publisher: Humana Press

Published: 2011-12-21

Total Pages: 0

ISBN-13: 9781617794643

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Due to the rapid and steady growth of available low-cost computer power, the use of computers for discovering and designing new drugs is becoming a central topic in modern molecular biology and medicinal chemistry. In Computational Drug Discovery and Design: Methods and Protocols expert researchers in the field provide key techniques to investigate biomedical applications for drug developments based on computational chemistry. These include methods and techniques from binding sites prediction to the accurate inclusion of solvent and entropic effects, from high-throughput screening of large compound databases to the expanding area of protein-protein inhibition, toward quantitative free-energy approaches in ensemble-based drug design using distributed computing. Written in the highly successful Methods in Molecular BiologyTM series format, chapters include introductions to their respective topics, reference to software and open source analysis tools, step-by-step, readily reproducible computational protocols, and key tips on troubleshooting and avoiding known pitfalls. Thorough and intuitive, Computational Drug Discovery and Design: Methods and Protocols aids scientists in the continuing study of state-of-the-art concepts and computer-based methodologies.

Total Chemical Synthesis of Proteins
Total Chemical Synthesis of Proteins

Author: Ashraf Brik

Publisher: John Wiley & Sons

Published: 2021-06-08

Total Pages: 626

ISBN-13: 3527346600

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How to synthesize native and modified proteins in the test tube With contributions from a panel of experts representing a range of disciplines, Total Chemical Synthesis of Proteins presents a carefully curated collection of synthetic approaches and strategies for the total synthesis of native and modified proteins. Comprehensive in scope, this important reference explores the three main chemoselective ligation methods for assembling unprotected peptide segments, including native chemical ligation (NCL). It includes information on synthetic strategies for the complex polypeptides that constitute glycoproteins, sulfoproteins, and membrane proteins, as well as their characterization. In addition, important areas of application for total protein synthesis are detailed, such as protein crystallography, protein engineering, and biomedical research. The authors also discuss the synthetic challenges that remain to be addressed. This unmatched resource: Contains valuable insights from the pioneers in the field of chemical protein synthesis Presents proven synthetic approaches for a range of protein families Explores key applications of precisely controlled protein synthesis, including novel diagnostics and therapeutics Written for organic chemists, biochemists, biotechnologists, and molecular biologists, Total Chemical Synthesis of Proteins provides key knowledge for everyone venturing into the burgeoning field of protein design and synthetic biology.

HIV-1 Integrase
HIV-1 Integrase

Author: Nouri Neamati

Publisher: John Wiley & Sons

Published: 2011-08-10

Total Pages: 710

ISBN-13: 1118015363

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This book comprehensively covers the mechanisms of action and inhibitor design for HIV-1 integrase. It serves as a resource for scientists facing challenging drug design issues and researchers in antiviral drug discovery. Despite numerous review articles and isolated book chapters dealing with HIV-1 integrase, there has not been a single source for those working to devise anti-AIDS drugs against this promising target. But this book fills that gap and offers a valuable introduction to the field for the interdisciplinary scientists who will need to work together to design drugs that target HIV-1 integrase.

Antiviral Drug Discovery and Development
Antiviral Drug Discovery and Development

Author: Xinyong Liu

Publisher: Springer Nature

Published: 2021-07-13

Total Pages: 357

ISBN-13: 9811602670

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This book summarizes state-of-the-art antiviral drug design and discovery approaches starting from natural products to de novo design, and provides a timely update on recently approved antiviral drugs and compounds in advanced clinical development. Special attention is paid to viral infections with a high impact on the world population or highly relevant from the public health perspective (HIV, hepatitis C, influenza virus, etc.). In these chapters, limitations associated with adverse effects and emergence of drug resistance are discussed in detail. In addition to classical antiviral strategies, chapters will be dedicated to discuss the non-classical drug development strategies to block viral infection, for instance, allosteric inhibitors, covalent antiviral agents, or antiviral compounds targeting protein–protein interactions. Finally, current prospects for producing broad-spectrum antiviral inhibitors will be also addressed. The book is distinctive in providing the most recent update in the rapidly evolving field of antiviral therapeutics. Authoritative reviews are written by international scientists well known for their contributions in their topics of research, which makes this book suitable for researchers not only within the antiviral research community but also attractive to a broad audience in the drug discovery field. This book covers molecular structures and biochemical mechanisms mediating the antiviral effects, while discussing various ligand design strategies, which include traditional medicinal chemistry, computational chemistry, and chemical biology approaches. The book provides a comprehensive review of antiviral drug discovery and development approaches, particularly focusing on current innovations and future trends.