Synopses & Reviews
Fruit flies are "little people with wings" goes the saying in the scientific community, ever since the completion of the Human Genome Project and its revelations about the similarity amongst the genomes of different organisms. It is humbling that most signaling pathways which "define" humans are conserved in Drosophila
, the common fruit fly. Feed a fruit fly caffeine and it has trouble falling asleep; feed it antihistamines and it cannot stay awake. A C. elegans
worm placed on the antidepressant flouxetine has increased serotonin levels in its tiny brain. Yeast treated with chemotherapeutics stop their cell division. Removal of a single gene from a mouse or zebrafish can cause the animals to develop Alzheimer’s disease or heart disease. These organisms are utilized as surrogates to investigate the function and design of complex human biological systems.
Advances in bioinformatics, proteomics, automation technologies and their application to model organism systems now occur on an industrial scale. The integration of model systems into the drug discovery process, the speed of the tools, and the in vivo validation data that these models can provide, will clearly help definition of disease biology and high-quality target validation. Enhanced target selection will lead to the more efficacious and less toxic therapeutic compounds of the future.
This book will be of interest to geneticists, bioinformaticians, pharmacologists, molecular biologists and people working in the pharmaceutical industry, particularly genomics.
"...an invaluable resource for an researcher in the academic or private sector...essential for any graduate level course..." (Drug Discovery Today, Vol 9(7), April 2004)
"...summarised the major organisms of use in this area together with their relative strengths and weaknesses..." (British Society of Cell Biology Newsletter, Summer 2004)
Model organisms are becoming increasingly useful in a systematic approach to a broad array of disease-based questions. With the advanced genetic techniques that are available for the model organisms and the availability of their genome sequences, these organisms are poised to have a major impact in drug discovery, particularly in the critical area of protein target validation. This timely book details recent advances in bioinformatics, proteomics, genomics, biochemical and automation technologies as applied to simple organisms in an integrated drug discovery platform.
Table of Contents
List of contributors.
1. Introduction to Model Systems in Drug Discovery (Kevin Fitzgerald and Pamela M. Carroll).
2. Growing Yeast for Fun and Profit: Use of Saccharomyces cerevisiae as a Model System in Drug Discovery (Petra Ross-Macdonald).
3. Caenorhabditis elegans Functional Genomics in Drug Discovery: Expanding Paradigms (Titus Kaletta, Lynn Butler and Thierry Bogaert).
4. Drosophila as a Tool for Drug Discovery (Hao Li and Dan Garza).
5. Drosophila – a Model System for Targets and Lead Identification in Cancer and Metabolic Disorders (Corina Schütt, Barbara Froesch and Ernst Hafen).
6. Mechanism of Action in Model Organisms: Interfacing Chemistry, Genetics and Genomics (Pamela M. Carroll, Kevin Fitzgerald and Rachel Kindt).
7. Gene tics and Genomics in the Zebrafish: from Gene to Function and Back (Stefan Schulte-Merker).
8. Lipid Metabolism and Signaling in Zebrafish (Shiu-Ying Ho, Steven A. Farber and Michael Pack).
9. Chemical Mutagenesis in the Mouse: a Powerful Tool in Drug Target Identification and Validation (Andreas Russ, Neil Dear, Geert Mudde, Gabriele Stumm, Johannes Grosse, Andreas Schröder, Reinhard Sedlmeier, Sigrid Wattler and Michael Nehls).
10. Saturation Screening of the Druggable Mammalian Genome (Hector Beltrandelrio, Francis Kern, Thomas Lanthorn, Tamas Oravecz, James Piggott, David Powell, Ramiro Ramirez-Solis, Arthur T. Sands and Brian Zambrowicz).