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... brilliant ... Yet anybody can understand it: it reads like a detective story.' John Maddox, Editor of Nature ' ... he skillfully imbues us with his joy and fascination with the living world, and the role of DNA in it.' Bruce M. Alberts, President of the National Academy of Sciences Unraveling DNA provides both laymen and scientist readers with a concise highly readable understanding of the structure, properties, and functions of the DNA molecule. The reader will find answers to all major questions about the biological, biotechnological, medical, physical, chemical, and mathematical aspects of DNA. In addition, the book includes an historical retrospective of past DNA research and forecasts future trends in the field. Written by an internationally acclaimed professor of biophysics as well as one of the world's leading authorities in DNA research, Unraveling DNA is designed to help professionals not specializing in molecular biology to understand the recent advances in this rapidly expanding field. The book is also especially useful to advanced high school students, junior college students, and university students interested in modern biology, medicine, physics, chemistry, and mathematics.
Unraveling the Double Helix covers the most colorful period in the history of DNA, from the discovery of "nuclein" in the late 1860s to the publication of James Watson's The Double Helix in 1968. These hundred years included the establishment of the Nobel Prize, antibiotics, x-ray crystallography, the atom bomb and two devastating world wars—events which are strung along the thread of DNA like beads on a necklace. The story of DNA is a saga packed with awful mistakes as well as brilliant science, with a wonderful cast of heroes and villains. Surprisingly, much of it is unfamiliar. The elucidation of the double helix was one of the most brilliant gems of twentieth century science, but some of the scientists who paved the way have been airbrushed out of history. James Watson and Francis Crick solved a magnificent mystery, but Gareth Williams shows that their contribution was the last few pieces of a gigantic jigsaw puzzle assembled over several decades.The book is comprehensive in scope, covering the first century of the history of DNA in its entirety, including the eight decades that have been neglected by other authors. It also explores the personalities of the main players, the impact of their entanglement with DNA, and what unique qualities make great scientists tick.
What are genes? What do genes do? These seemingly simple questions are in fact challenging to answer accurately. As a result, there are widespread misunderstandings and over-simplistic answers, which lead to common conceptions widely portrayed in the media, such as the existence of a gene 'for' a particular characteristic or disease. In reality, the DNA we inherit interacts continuously with the environment and functions differently as we age. What our parents hand down to us is just the beginning of our life story. This comprehensive book analyses and explains the gene concept, combining philosophical, historical, psychological and educational perspectives with current research in genetics and genomics. It summarises what we currently know and do not know about genes and the potential impact of genetics on all our lives. Making Sense of Genes is an accessible but rigorous introduction to contemporary genetics concepts for non-experts, undergraduate students, teachers and healthcare professionals.
This innovative mannual introduces students to all of the basic techniques of modern molecular biology using an integrated series of laboratory exercises that involve the cloning and analysis of the bioluminescene genes.
The problem of unraveling two intertwined strands during the duplication of DNA was recognized shortly after the proposal of the DNA double helix structure in 1953. A group of enzymes called DNA topoisomerases solve this problem by breaking and rejoining DNA molecules in a controlled manner, thereby allowing strands to be passed through each other and thus untangled—not just during DNA replication, but also during many other basic cellular processes. Because of their intimate involvement in the workings of the cell, topoisomerases are also the logical targets of many antibiotics (including Cipro) and anticancer agents. This book, written by James Wang, the discoverer of the first topoisomerase and a leader in the field since, presents ten chapters covering the historical backdrop of the DNA entanglement problem and the discovery of the DNA topoisomerases, how DNA topoisomerases perform their magic in DNA replication, transcription, genetic recombination and chromosome condensation, and how they are targets of therapeutic agents. The book should appeal to readers from undergraduates upwards with interests in the biological and clinical aspects of topoisomerase function, or in the mathematics and physics of topology.
How tiny variations in our personal DNA can determine how we look, how we behave, how we get sick, and how we get well. News stories report almost daily on the remarkable progress scientists are making in unraveling the genetic basis of disease and behavior. Meanwhile, new technologies are rapidly reducing the cost of reading someone's personal DNA (all six billion letters of it). Within the next ten years, hospitals may present parents with their newborn's complete DNA code along with her footprints and APGAR score. In Genetic Twists of Fate, distinguished geneticists Stanley Fields and Mark Johnston help us make sense of the genetic revolution that is upon us. Fields and Johnston tell real life stories that hinge on the inheritance of one tiny change rather than another in an individual's DNA: a mother wrongly accused of poisoning her young son when the true killer was a genetic disorder; the screen siren who could no longer remember her lines because of Alzheimer's disease; and the president who was treated with rat poison to prevent another heart attack. In an engaging and accessible style, Fields and Johnston explain what our personal DNA code is, how a few differences in its long list of DNA letters makes each of us unique, and how that code influences our appearance, our behavior, and our risk for such common diseases as diabetes or cancer.
Around 60,000 years ago, a man—genetically identical to us—lived in Africa. Every person alive today is descended from him. How did this real-life Adam wind up as the father of us all? What happened to the descendants of other men who lived at the same time? And why, if modern humans share a single prehistoric ancestor, do we come in so many sizes, shapes, and races? Examining the hidden secrets of human evolution in our genetic code, Spencer Wells reveals how developments in the revolutionary science of population genetics have made it possible to create a family tree for the whole of humanity. Replete with marvelous anecdotes and remarkable information, from the truth about the real Adam and Eve to the way differing racial types emerged, The Journey of Man is an enthralling, epic tour through the history and development of early humankind.
Genetics is a fascinating and complex field, which reveals the secrets of the genetic code present in every living being. Through the investigation of genes and their interaction with the environment, we are able to better understand the biological processes that shape our existence. In this book, we'll explore the wonders and challenges of genetics, as well as its applications in areas such as medicine, criminal investigation, and genetic engineering. The first part of this book will take us through the intricate world of the genetics of aging and longevity. We will investigate the genetic mechanisms that determine the rate of aging of organisms and explore the possibilities of prolonging a healthy life. We'll discover how the latest research is unlocking the mysteries of aging and offering new insights into human longevity. Then we will enter the field of genetic engineering and genetically modified organisms (GMOs). We will explore the innovative techniques that allow the manipulation of DNA and the creation of organisms with specific characteristics. We'll see how this technology is revolutionizing agriculture, medicine, and industry, while raising important ethical and environmental questions. Forensic genetics will also gain prominence on our journey. We will investigate how DNA analysis has become a powerful tool in solving crimes, unraveling mysteries and assisting in the pursuit of justice. We'll discover how technological advances are revolutionizing criminal investigation and providing a deeper understanding of the genetic bonds between individuals. Entering the field of health, we will explore the genetics of neurodegenerative, cardiovascular, autoimmune and psychiatric disorders. We will understand how genes play a key role in the development of these diseases and how this understanding can open the way to more effective treatments and prevention strategies. In addition, we will investigate pharmacogenomics and precision medicine, examining how genetic individuality influences individuals' response to medications, enabling personalized and more effective treatments. We'll also cover the genetics of metabolism and obesity, sleep disorders, and the genetic implications for these conditions. The second part of this book will take us on a philosophical journey into the world of the mind. We'll explore debates about the nature of consciousness, the mind-body problem, reductionism, and dualism. We will investigate the relationship between the mind and the brain, the question of personal identity over time, and the philosophical implications of the mind in relation to artificial intelligence, free will, neuroscience, qualia, and even animal consciousness.
According to the modern version of Darwin's theory, DNA contains a program for embryo development that is passed down from generation to generation; the program is implemented by proteins encoded by the DNA, and accidental DNA mutations introduce changes in those proteins that natural selection then shapes into new species, organs and body plans. When scientists discovered forty years ago that about 98% of our DNA does not encode proteins, the non-protein-coding portion was labeled “junk” and attributed to molecular accidents that have accumulated in the course of evolution. Recent books by Richard Dawkins, Francis Collins and others have used this “junk DNA” as evidence for Darwinian evolution and evidence against intelligent design (since an intelligent designer would presumably not have filled our genome with so much garbage). But recent genome evidence shows that much of our non-protein-coding DNA performs essential biological functions. The Myth of Junk DNA is written for a general audience by biologist Jonathan Wells, author of Icons of Evolution. Citing some of the abundant evidence from recent genome projects, the book shows that “junk DNA” is not science, but myth.