This volume thoroughly covers HIV-1 antiretrovirals currently in clinical use, together with their advantages and limitations. HIV-1 inhibitor resistance is discussed in detail, and critical assessments as to what will be required of future antiretrovirals in order to halt viral replication, reduce viral resistance, and alter the state of viral latency are presented. Experts at the forefront of HIV-1 research provide overviews of approaches from the fields of virology, chemical biology and structural biology for obtaining small molecule inhibitors that target viral regulatory and structural components at multiple points in the viral lifecycle. The individual chapters will appeal to scientists and clinicians alike.

This book will take an evidence-based approach to current knowledge about biomolecules and their place in our lives, inviting readers to explore how we know what we know, and how current gaps in knowledge may influence the way we approach the information. Biomolecular science is increasingly important in our everyday life, influencing the choices we make about our diet, our health, and our wellness. Often, however, information about biomolecular science is presented as a list of immutable facts, discouraging critical thought. The book will introduce the basic tools of structural biology, supply real-life examples, and encourage critical thought about aspects of biology that are still not fully understood.

This book will take an evidence-based approach to current knowledge about biomolecules and their place in our lives, inviting readers to explore how we know what we know, and how current gaps in knowledge may influence the way we approach the information. Biomolecular science is increasingly important in our everyday life, influencing the choices we make about our diet, our health, and our wellness. Often, however, information about biomolecular science is presented as a list of immutable facts, discouraging critical thought. The book will introduce the basic tools of structural biology, supply real-life examples, and encourage critical thought about aspects of biology that are still not fully understood.

This volume thoroughly covers HIV-1 antiretrovirals currently in clinical use, together with their advantages and limitations. HIV-1 inhibitor resistance is discussed in detail, and critical assessments as to what will be required of future antiretrovirals in order to halt viral replication, reduce viral resistance, and alter the state of viral latency are presented. Experts at the forefront of HIV-1 research provide overviews of approaches from the fields of virology, chemical biology and structural biology for obtaining small molecule inhibitors that target viral regulatory and structural components at multiple points in the viral lifecycle. The individual chapters will appeal to scientists and clinicians alike.

Molecular Nature is a richly illustrated guide to the extraordinary diversity of molecules that are responsible for life. David Goodsell, author of the highly-praised book, The Machinery of Life, has synthesized a vast amount of data in a manner that is accessible to the general reader. Molecular Nature examines topics ranging from the shape of cells to the molecules responsible for digestion, immunity, and thought. The author's unique combination of scientific and artistic talents make this a readable, stimulating and highly evocative book. About the Author: David Goodsell is in the Department of Molecular Biology at the Research Institute of Scripps Clinic in La Jolla, California. His research involves computer graphics and X-ray crystallography. He is the author of The Machinery of Life (Springer-Verlag, 1992), and his artwork has been shown at exhibitions on science and art.

Dieses Buch ladt ein zu einer Reise in das Innere der Zelle. Es zeigt die Vielfalt der Molekule, die wie die Radchen einer Maschine ineinandergreifen. Sie sind die Grundlage allen Lebens, von ihrem Funktionieren hangen Gesundheit und Krankheit, Leben und Tod ab. David Goodsell erklart, was Biochemiker uber den Ablauf der lebenswichtigen Prozesse im Koerper herausgefunden haben. Den ungeheuren Groessenunterschied von unserer vertrauten Welt zur mikroskopisch kleinen Welt der Molekule uberbruckt er dabei durch faszinierende Bilder. Seine Zeichnungen bieten sachliche Informationen uber die molekulare Struktur der Zellen und sind zugleich von hohem asthetischem Reiz.

Imagine that we had some way to look directly at the molecules in a living organism. An x-ray microscope would do the trick, or since we re dreaming, perhaps an Asimov-style nanosubmarine (unfortunately, neither is currently feasible). Think of the wonders we could witness firsthand: antibodies atta- ing a virus, electrical signals racing down nerve fibers, proteins building new strands of DNA. Many of the questions puzzling the current cadre of sci- tists would be answered at a glance. But the nanoscale world of molecules is separated from our everyday world of experience by a daunting million-fold difference in size, so the world of molecules is completely invisible. I created the illustrations in this book to help bridge this gulf and allow us to see the molecular structure of cells, if not directly, then in an artistic rendition. I have included two types of illustrations with this goal in mind: watercolor paintings which magnify a small portion of a living cell by one million times, showing the arrangement of molecules inside, and comput- generated pictures, which show the atomic details of individual molecules. In this second edition of The Machinery of Life, these illustrations are presented in full color, and they incorporate many of the exciting scientific advances of the 15 years since the first edition."