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| genome biology and evolution journal impact factor: Environmental Epigenetics L. Joseph Su, Tung-chin Chiang, 2015-05-18 This book examines the toxicological and health implications of environmental epigenetics and provides knowledge through an interdisciplinary approach. Included in this volume are chapters outlining various environmental risk factors such as phthalates and dietary components, life states such as pregnancy and ageing, hormonal and metabolic considerations and specific disease risks such as cancer cardiovascular diseases and other non-communicable diseases. Environmental Epigenetics imparts integrative knowledge of the science of epigenetics and the issues raised in environmental epidemiology. This book is intended to serve both as a reference compendium on environmental epigenetics for scientists in academia, industry and laboratories and as a textbook for graduate level environmental health courses. Environmental Epigenetics imparts integrative knowledge of the science of epigenetics and the issues raised in environmental epidemiology. This book is intended to serve both as a reference compendium on environmental epigenetics for scientists in academia, industry and laboratories and as a textbook for graduate level environmental health courses. |
| genome biology and evolution journal impact factor: Quantitative Genetics in the Wild Anne Charmantier, Dany Garant, Loeske E. B. Kruuk, 2014 This book gathers the expertise of 30 evolutionary biologists from around the globe to highlight how applying the field of quantitative genetics - the analysis of the genetic basis of complex traits - aids in the study of wild populations. |
| genome biology and evolution journal impact factor: Plant Genomes J. -N. Volff, M. Schmid, 2008-04-14 Recent major advances in the field of comparative genomics and cytogenomics of plants, particularly associated with the completion of ambitious genome projects, have uncovered astonishing facets of the architecture and evolutionary history of plant genomes. The aim of this book was to review these recent developments as well as their implications in our understanding of the mechanisms which drive plant diversity. New insights into the evolution of gene functions, gene families and genome size are presented, with particular emphasis on the evolutionary impact of polyploidization and transposable elements. Knowledge on the structure and evolution of plant sex chromosomes, centromeres and microRNAs is reviewed and updated. Taken together, the contributions by internationally recognized experts present a panoramic overview of the structural features and evolutionary dynamics of plant genomes. This volume of Genome Dynamics will provide researchers, teachers and students in the fields of biology and agronomy with a valuable source of current knowledge on plant genomes. |
| genome biology and evolution journal impact factor: The Selfish Gene Richard Dawkins, 1989 Science need not be dull and bogged down by jargon, as Richard Dawkins proves in this entertaining look at evolution. The themes he takes up are the concepts of altruistic and selfish behaviour; the genetical definition of selfish interest; the evolution of aggressive behaviour; kinshiptheory; sex ratio theory; reciprocal altruism; deceit; and the natural selection of sex differences. 'Should be read, can be read by almost anyone. It describes with great skill a new face of the theory of evolution.' W.D. Hamilton, Science |
| genome biology and evolution journal impact factor: Genes and Genomes R.S. Verma, 1998-06-03 The laws of inheritance were considered quite superficial until 1903, when the chromosome theory of heredity was established by Sutton and Boveri. The discovery of the double helix and the genetic code led to our understanding of gene structure and function. For the past quarter of a century, remarkable progress has been made in the characterization of the human genome in order to search for coherent views of genes. The unit of inheritance termed factor or gene, once upon a time thought to be a trivial an imaginary entity, is now perceived clearly as the precise unit of inheritance that has continually deluged us with amazement by its complex identity and behaviour, sometimes bypassing the university of Mendel's law. The aim of the fifth volume, entitled Genes and Genomes, is to cover the topics ranging from the structure of DNA itself to the structure of the complete genome, along with everything in between, encompassing 12 chapters. These chapters relate much of the information accumulated on the role of DNA in the organization of genes and genomes per se. Several distinguished scientists, all pre-eminent authorities in each field to share their expertise. Obviously, since the historical report on the double helix configuration in 1953, voluminous reports on the meteoric advances in genetics have been accumulated, and to cover every account in a single volume format would be a Herculean task. Therefore, only a few topics are chosen, which are of great interest to molecular geneticists. This volume is intended for advanced graduate students who would wish to keep abreast with the most recent trends in genome biology. |
| genome biology and evolution journal impact factor: Molecular Evolution Roderick D.M. Page, Edward C. Holmes, 2009-07-14 The study of evolution at the molecular level has given the subject of evolutionary biology a new significance. Phylogenetic 'trees' of gene sequences are a powerful tool for recovering evolutionary relationships among species, and can be used to answer a broad range of evolutionary and ecological questions. They are also beginning to permeate the medical sciences. In this book, the authors approach the study of molecular evolution with the phylogenetic tree as a central metaphor. This will equip students and professionals with the ability to see both the evolutionary relevance of molecular data, and the significance evolutionary theory has for molecular studies. The book is accessible yet sufficiently detailed and explicit so that the student can learn the mechanics of the procedures discussed. The book is intended for senior undergraduate and graduate students taking courses in molecular evolution/phylogenetic reconstruction. It will also be a useful supplement for students taking wider courses in evolution, as well as a valuable resource for professionals. First student textbook of phylogenetic reconstruction which uses the tree as a central metaphor of evolution. Chapter summaries and annotated suggestions for further reading. Worked examples facilitate understanding of some of the more complex issues. Emphasis on clarity and accessibility. |
| genome biology and evolution journal impact factor: The Mango Genome Chittaranjan Kole, 2021-03-27 This book represents the first comprehensive compilation of deliberations on botany; genetic resources; genetic diversity analysis; classical genetics & traditional breeding; in vitro culture & genetic transformation; detailed information on molecular maps & mapping of economic genes and QTLs; whole genome sequencing of the nuclear genome and sequencing of chloroplast genome; and elucidation of functional genomics. It also addresses alternate flowering, a unique problem in mango, and discusses currently available genomic resources and databases. Gathering contributions by globally reputed experts, the book will benefit the students, teachers, and scientists in academia and at private companies interested in horticulture, genetics, breeding, pathology, entomology, physiology, molecular genetics and breeding, in vitro culture & genetic engineering, and structural and functional genomics. |
| genome biology and evolution journal impact factor: Genome Editing and Engineering Krishnarao Appasani, 2018-08-23 A complete guide to endonuclease-based genomic engineering, from basic science to application in disease biology and clinical treatment. |
| genome biology and evolution journal impact factor: Evolutionary Biology: Understanding Evolutionary Processes Melody Glover, 2020-09-22 The sub-field of biology that is concerned with the study of evolutionary processes is referred to as evolutionary biology. The diversity of life on Earth is produced by evolutionary processes such as common descent, natural selection and speciation. Evolutionary biology makes use of principles from various fields like genetics, systematics, palaeontology and ecology. Some of the major sub-fields within this discipline are evolutionary ecology and evolutionary developmental biology. Evolutionary ecology seeks to take the evolutionary history of species as well as their interactions into consideration while studying ecology. Evolutionary developmental biology is involved in the comparison of the developmental processes of different organisms in order to understand the evolution of developmental processes and ancestral relationships between them. This book presents the complex subject of evolutionary biology in the most comprehensible and easy to understand language. Some of the diverse topics covered in this book address the varied branches that fall under this category. It will provide comprehensive knowledge to the readers. |
| genome biology and evolution journal impact factor: Biology of Trypanosoma cruzi Wanderley De Souza, 2019-12-18 Trypanosoma cruzi, an important zoonotic protozoan that causes Chagas disease, affects at least 8 million people in Latin America. Chagas disease is an important life-long infection in humans that can be divided into distinct clinical stages: the acute phase, where patient symptoms can vary from asymptomatic to severe; the indeterminate form, which is usually asymptomatic; and the chronic phase, where cardiomyopathy and/or digestive megasyndromes appear. In addition to its medical importance, T. cruzi is an interesting biological model for studying processes such as: (1) cell differentiation, where a non-infective stage transforms into an infective one; (2) cell invasion, where the infective stages are able to penetrate into a mammalian host cell, where they multiply several times and thus amplify the infection; and (3) evasion from the immune system, using several mechanisms. This book, with 13 chapters, has been organized in four major sections: 1. Basic Biology, 2. Biochemistry and Molecular Biology, 3. ParasiteHost Cell Interaction, and 4 Chemotherapy. The chapters include basic biological information on the protozoan lifecycle, including new information on parasite genomics and proteomics. In addition, they analyze the interaction with host cells as well the immune response and evasion, ending with information on experimental chemotherapy against Chagas disease. |
| genome biology and evolution journal impact factor: Chance and Necessity Jacques Monod, 1997 Change and necessity is a statement of Darwinian natural selection as a process driven by chance necessity, devoid of purpose or intent. |
| genome biology and evolution journal impact factor: Evolution James Alan Shapiro, 2011 This book proposes an important new paradigm for understanding biological evolution. Shapiro demonstrates why traditional views of evolution are inadequate to explain the latest evidence, and presents an alternative. His information- and systems-based approach integrates advances in symbiogenesis, epigenetics, and saltationism, and points toward an emerging synthesis of physical, information, and biological sciences. |
| genome biology and evolution journal impact factor: Bioinformatics and Molecular Evolution Paul G. Higgs, Teresa K. Attwood, 2005 In the current era of complete genome sequencing, Bioinformatics and Molecular Evolution provides an up-to-date and comprehensive introduction to bioinformatics in the context of evolutionary biology. This accessible text: provides a thorough examination of sequence analysis, biological databases, pattern recognition, and applications to genomics, microarrays, and proteomics emphasizes the theoretical and statistical methods used in bioinformatics programs in a way that is accessible to biological science students places bioinformatics in the context of evolutionary biology, including population genetics, molecular evolution, molecular phylogenetics, and their applications features end-of-chapter problems and self-tests to help students synthesize the materials and apply their understanding is accompanied by a dedicated website - www.blackwellpublishing.com/higgs - containing downloadable sequences, links to web resources, answers to self-test questions, and all artwork in downloadable format (artwork also available to instructors on CD-ROM). This important textbook will equip readers with a thorough understanding of the quantitative methods used in the analysis of molecular evolution, and will be essential reading for advanced undergraduates, graduates, and researchers in molecular biology, genetics, genomics, computational biology, and bioinformatics courses. |
| genome biology and evolution journal impact factor: Mechanisms of Hormone Action P Karlson, 2013-10-22 Mechanisms of Hormone Action: A NATO Advanced Study Institute focuses on the action mechanisms of hormones, including regulation of proteins, hormone actions, and biosynthesis. The selection first offers information on hormone action at the cell membrane and a new approach to the structure of polypeptides and proteins in biological systems, such as the membranes of cells. Discussions focus on the cell membrane as a possible locus for the hormone receptor; gaps in understanding of the molecular organization of the cell membrane; and a possible model of hormone action at the membrane level. The text also ponders on insulin and regulation of protein biosynthesis, including insulin and protein biosynthesis, insulin and nucleic acid metabolism, and proposal as to the mode of action of insulin in stimulating protein synthesis. The publication elaborates on the action of a neurohypophysial hormone in an elasmobranch fish; the effect of ecdysone on gene activity patterns in giant chromosomes; and action of ecdysone on RNA and protein metabolism in the blowfly, Calliphora erythrocephala. Topics include nature of the enzyme induction, ecdysone and RNA metabolism, and nature of the epidermis nuclear RNA fractions isolated by the Georgiev method. The selection is a valuable reference for readers interested in the mechanisms of hormone action. |
| genome biology and evolution journal impact factor: Tropical Diseases Bulletin , 1922 |
| genome biology and evolution journal impact factor: A Life Decoded J. Craig Venter, 2007-10-18 The triumphant memoir of the man behind one of the greatest feats in scientific history Of all the scientific achievements of the past century, perhaps none can match the deciphering of the human genetic code, both for its technical brilliance and for its implications for our future. In A Life Decoded, J. Craig Venter traces his rise from an uninspired student to one of the most fascinating and controversial figures in science today. Here, Venter relates the unparalleled drama of the quest to decode the human genome?a goal he predicted he could achieve years earlier and more cheaply than the government-sponsored Human Genome Project, and one that he fulfilled in 2001. A thrilling story of detection, A Life Decoded is also a revealing, and often troubling, look at how science is practiced today. |
| genome biology and evolution journal impact factor: Molecular Analyses Scott Orland Rogers, 2022-07-11 DNA and RNA extraction methods from a variety of tissues and samples are now routine, including extraction from single cells. Many methods are now automated. Sequencing efficiency has reached the point where it is now possible to obtain gigabases of data, both quickly and inexpensively. Such methods permit the identification of gene versions, including those associated with disease (e.g. small nucleotide polymorphism analyses, or SNPs). The general public as well as clinicians can now access a wide variety of literature on the molecular bases of diseases, allowing them to better assess disease risks and treatments. This volume concentrates on medically-focused methods, and therefore the major audience will be medical professionals, students, and those involved in medically-related research endeavors. There are also papers in this volume dealing specifically with methods developed to analyze large sequence data sets. Many methods reviewed herein are more broadly applicable to other fields in biology, chemistry, bioinformatics, and bioengineering, and are intended for a broad readership. Key Features Summarizes nucleic acid extractions from a wide variety of tissues and cells Describes processes of nucleic acid preservation Reviews forensic sampling, detection of nucleic acids, and delivery of nucleic acids to multicellular organisms Provides essential guidance for sequencing, sequence analysis, database searches, and phylogenetic analyses Includes additional methods useful for analysis of nucleic acids and proteins Related Titles DeSalle, et al. Phylogenomics: A Primer (ISBN 978-0-3670-2849-7). Jennings, W. B. Phylogenomic Data Acquisition: Principles and Practice (ISBN 978-0-3678-6980-9). Wang, X. Next-Generation Sequencing Data Analysis (ISBN 978-1-4822-1788-9) Sung, W.-K. Algorithms for Next-Generation Sequencing (ISBN 978-0-3676-5797-0) |
| genome biology and evolution journal impact factor: Molecular Biology of the Cell , 2002 |
| genome biology and evolution journal impact factor: Foodomics Jorge Barros-Velázquez, 2021-03-23 Presenting an up-to-date review of the state-of-the-art and main applications of omics technologies to current hot topics in food sciences, this book is divided into four convenient sections. The first section represents an introduction to the development of foodomics and will provide a general overview of DNA-based and protein-based methods. The second section is focused on the main applications of omics to food safety issues, such as chemical hazards, foodborne pathogens, phages, food authentication or GMO detection. The third section is focused on specific food groups and how omics have revolutionized the investigation of dairy and meat products, seafood, agricultural and fermented food products. Finally, the fourth section is devoted to the link between foodomics and health: hot topics such as nutrimetabolomics, food allergy or probiotics are reviewed here. The book brings together work from top international scientists to produce the most significant academic book for some years on omics and food for a broad audience. It presents unique features not covered so far by other books, such as a detailed description of different strategies and applications of omics techniques to many food sectors and provides a welcome addition to the cutting-edge literature in this area for researchers and professionals in food science and food chemistry. |
| genome biology and evolution journal impact factor: DNA Methylation in Plants Associated With Abiotic Stress Markus Kuhlmann, Hua Jiang, Marco Catoni, Frank Johannes, 2021-12-21 |
| genome biology and evolution journal impact factor: The Material Basis of Evolution Richard Goldschmidt, 1982-01-01 An eminent geneticist examines the Darwinian theory of evolution, analyzes the hereditary differences that produce new species, and suggests changes in evolutionary theory based on his biological research |
| genome biology and evolution journal impact factor: Why Evolution is True Jerry A. Coyne, 2009 Weaves together the many threads of modern work in genetics, palaeontology, geology, molecular biology, anatomy and development that demonstrate the processes first proposed by Darwin and to present them in a crisp, lucid, account accessible to a wide audience. |
| genome biology and evolution journal impact factor: Evolutionary Genomics Maria Anisimova, 2012-03-08 Together with early theoretical work in population genetics, the debate on sources of genetic makeup initiated by proponents of the neutral theory made a solid contribution to the spectacular growth in statistical methodologies for molecular evolution. Evolutionary Genomics: Statistical and Computational Methods is intended to bring together the more recent developments in the statistical methodology and the challenges that followed as a result of rapidly improving sequencing technologies. Presented by top scientists from a variety of disciplines, the collection includes a wide spectrum of articles encompassing theoretical works and hands-on tutorials, as well as many reviews with key biological insight. Volume 2 begins with phylogenomics and continues with in-depth coverage of natural selection, recombination, and genomic innovation. The remaining chapters treat topics of more recent interest, including population genomics, -omics studies, and computational issues related to the handling of large-scale genomic data. Written in the highly successful Methods in Molecular BiologyTM series format, this work provides the kind of advice on methodology and implementation that is crucial for getting ahead in genomic data analyses. Comprehensive and cutting-edge, Evolutionary Genomics: Statistical and Computational Methods is a treasure chest of state-of the-art methods to study genomic and omics data, certain to inspire both young and experienced readers to join the interdisciplinary field of evolutionary genomics. |
| genome biology and evolution journal impact factor: Genome Chaos Henry H. Heng, 2025-06-01 Genome Chaos: Rethinking Genetics, Evolution, and Molecular Medicine, Second Edition transports readers from Mendelian genetics to 4D genomics, building a case for genes and genomes as distinct biological entities where the genome, rather than individual genes, defines system-level inheritance and represents a clear unit of selection for macroevolution. In this thought-provoking text, Dr. Henry Heng invigorates fresh discussions in Genome Architecture Theory and helps readers reevaluate their current understanding of human genetics, evolution, and new pathways for advancing molecular and precision medicine.In this timely new edition, Dr. Heng fully embraces the integration of system information with genome-mediated evolutionary mechanisms, and supports this framework with recent findings and growing, interdisciplinary research. Ten evidence-based chapters discuss 4D genomics, genes and genomes as distinct biological entities, genome chaos and cellular macroevolution, karyotype coding and fuzzy inheritance, as well as an entirely novel model of evolution driven by information flow, and more. Brand-new chapters consider the creation and maintenance of system information for complexity and biodiversity, as well as modes of analyzing information-based and historically contingent evolutionary framework. This synthesis offers a revolutionary paradigm of evolutionary theory. It also hypothesizes about how information flow, matter arrangement, and energy interact. - Bridges basic research and clinical applications, providing a foundation for re-examining the results of large-scale -omics studies and precision medicine - Gathers the most pressing questions in genomics, cytogenomics, and evolution - Proposes a novel genome and information-based evolutionary theory that unites the study of physical, chemical, and biological mechanisms within organismal systems - Contains ten evidence-based chapters that discuss karyotype coding, function of sex, natural information self-creation, and evolution as platform for both innovation and conservation |
| genome biology and evolution journal impact factor: Animal Genomics Bhanu P. Chowdhary, 2003 This publication provides an update on the current status of gene maps in different livestock and pet/companion animal species. The findings summarized in species specific commentaries and original articles testify the rapid advances made in the field of animal genomics. Of significant interest is the fact that current investigations are providing headways for two important and exciting research fronts: targeted high-resolution mapping leading to the application of genomic information in addressing questions of economic and biological significance in animals, and the initiation of whole genome sequencing projects for some of the animal species. Like in humans and mice, this will set the stage for a new level of research and real time complex analysis of the genomes of these species. Animal Genomics signifies the beginning of a new era in this field and celebrates the achievements of the past 20 years of genomics research. It will be of special interest to researchers involved in genome analysis - both gross chromosomal as well as molecular - in various animal species, and to comparative and evolutionary geneticists. |
| genome biology and evolution journal impact factor: Evolution after Gene Duplication Katharina Dittmar, David Liberles, 2011-06-09 Gene duplication has long been believed to have played a major role in the rise of biological novelty through evolution of new function and gene expression patterns. The first book to examine gene duplication across all levels of biological organization, Evolution after Gene Duplication presents a comprehensive picture of the mechanistic process by which gene duplication may have played a role in generating biodiversity. Key Features: Explores comparative genomics, genome evolution studies and analysis of multi-gene families such as Hox, globins, olfactory receptors and MHC (immune system) A complete post-genome treatment of the topic originally covered by Ohno's 1970 classic, this volume extends coverage to include the fate of associated regulatory pathways Taps the significant increase in multi-gene family data that has resulted from comparative genomics Comprehensive coverage that includes opposing theoretical viewpoints, comparative genomics data, theoretical and empirical evidence and the role of bioinformatics in the study of gene duplication This up-to-date overview of theory and mathematical models along with practical examples is suitable for scientists across various levels of biology as well as instructors and graduate students. |
| genome biology and evolution journal impact factor: Data Analysis in Molecular Biology and Evolution Xuhua Xia, 2000-03-31 Data Analysis in Molecular Biology and Evolution introduces biologists to DAMBE, a proprietary, user-friendly computer program for molecular data analysis. The unique combination of this book and software will allow biologists not only to understand the rationale behind a variety of computational tools in molecular biology and evolution, but also to gain instant access to these tools for use in their laboratories. Data Analysis in Molecular Biology and Evolution serves as an excellent resource for advanced level undergraduates or graduates as well as for professionals working in the field. |
| genome biology and evolution journal impact factor: The Origins of Genome Architecture Michael Lynch, 2007-06 The availability of genomic blueprints for hundreds of species has led to a transformation in biology, encouraging the proliferation of adaptive arguments for the evolution of genomic features. This text explains why the details matter and presents a framework for how the architectural diversity of eukaryotic genomes and genes came to arise. |
| genome biology and evolution journal impact factor: Prokaryotic Toxin-Antitoxins Kenn Gerdes, 2012-10-19 Prokaryotic Toxins – Antitoxins gives the first overview of an exciting and rapidly expanding research field. Toxin – antitoxin (TA) genes were discovered on plasmids 30 years ago. Since then it has become evident that TA genes are highly abundant in bacterial and archaeal chromosomes. TA genes code for an antitoxin that combine with and neutralize a cognate toxin. When activated, the toxins inhibit protein synthesis and cell growth and thereby induce dormancy and multidrug tolerance (persistence). Remarkably, in some species, the TA gene families have undergone dramatic expansions. For example, the highly persistent major human pathogen Mycobacterium tuberculosis has »100 TA loci. The large expansion of TA genes by some organisms is a biological mystery. However, recent observations indicate that TA genes contribute cumulatively to the persistence of bacteria. This medically important phenomenon may thus for the first time become experimentally tractable at the molecular level. |
| genome biology and evolution journal impact factor: Postgenomics Sarah S. Richardson, Hallam Stevens, 2015-05-29 Ten years after the Human Genome Project’s completion the life sciences stand in a moment of uncertainty, transition, and contestation. The postgenomic era has seen rapid shifts in research methodology, funding, scientific labor, and disciplinary structures. Postgenomics is transforming our understanding of disease and health, our environment, and the categories of race, class, and gender. At the same time, the gene retains its centrality and power in biological and popular discourse. The contributors to Postgenomics analyze these ruptures and continuities and place them in historical, social, and political context. Postgenomics, they argue, forces a rethinking of the genome itself, and opens new territory for conversations between the social sciences, humanities, and life sciences. Contributors. Russ Altman, Rachel A. Ankeny, Catherine Bliss, John Dupré, Michael Fortun, Evelyn Fox Keller, Sabina Leonelli, Adrian Mackenzie, Margot Moinester, Aaron Panofsky, Sarah S. Richardson, Sara Shostak, Hallam Stevens |
| genome biology and evolution journal impact factor: The Timetree of Life S. Blair Hedges, Sudhir Kumar, 2009-04-23 The evolutionary history of life includes two primary components: phylogeny and timescale. Phylogeny refers to the branching order (relationships) of species or other taxa within a group and is crucial for understanding the inheritance of traits and for erecting classifications. However, a timescale is equally important because it provides a way to compare phylogeny directly with the evolution of other organisms and with planetary history such as geology, climate, extraterrestrialimpacts, and other features.The Timetree of Life is the first reference book to synthesize the wealth of information relating to the temporal component of phylogenetic trees. In the past, biologists have relied exclusively upon the fossil record to infer an evolutionary timescale. However, recent revolutionary advances in molecular biology have made it possible to not only estimate the relationships of many groups of organisms, but also to estimate their times of divergence with molecular clocks. The routineestimation and utilization of these so-called 'time-trees' could add exciting new dimensions to biology including enhanced opportunities to integrate large molecular data sets with fossil and biogeographic evidence (and thereby foster greater communication between molecular and traditional systematists). Theycould help estimate not only ancestral character states but also evolutionary rates in numerous categories of organismal phenotype; establish more reliable associations between causal historical processes and biological outcomes; develop a universally standardized scheme for biological classifications; and generally promote novel avenues of thought in many arenas of comparative evolutionary biology.This authoritative reference work brings together, for the first time, experts on all major groups of organisms to assemble a timetree of life. The result is a comprehensive resource on evolutionary history which will be an indispensable reference for scientists, educators, and students in the life sciences, earth sciences, and molecular biology. For each major group of organism, a representative is illustrated and a timetree of families and higher taxonomic groups is shown. Basic aspects ofthe evolutionary history of the group, the fossil record, and competing hypotheses of relationships are discussed. Details of the divergence times are presented for each node in the timetree, and primary literature references are included. The book is complemented by an online database(www.timetree.net) which allows researchers to both deposit and retrieve data. |
| genome biology and evolution journal impact factor: The Pear Genome Schuyler S. Korban, 2019-07-03 Addressing the pear genome, this book covers the current state of knowledge regarding genetic and genomic resources, breeding approaches and strategies, as well as cutting-edge content on how these tools and resources are being / soon will be utilized to pursue genetic improvement efforts that will combine fruit quality, high productivity, precocious fruit bearing, and long postharvest storage life, along with elevated levels of resistance to various major diseases and insect pests. Throughout, the book also explores potential opportunities and challenges in genomic analysis, sequence assembly, structural features, as well as functional studies that will assist in future genetic improvement efforts for pears. The pear (Pyrus), an important tree fruit crop, is grown worldwide, and has several economically relevant cultivars. In recent years, modern genetic and genomic tools have resulted in the development of a wide variety of valuable resources for the pear. In the past few years, completion of whole genome assemblies of ‘Dangshansuli’, an Asian pear, and ‘Bartlett’, a European pear, have paved the way for new discoveries regarding for example, the pear’s genomic structure, chromosome evolution, and patterns of genetic variation. This wealth of new resources will have a major impact on our knowledge of the pear genome; in turn, these resources and knowledge will have significant impacts on future genetic improvement efforts. |
| genome biology and evolution journal impact factor: Computational Molecular Evolution Ziheng Yang, 2006-10-05 This book describes the models, methods and algorithms that are most useful for analysing the ever-increasing supply of molecular sequence data, with a view to furthering our understanding of the evolution of genes and genomes. |
| genome biology and evolution journal impact factor: The Cell Cycle and Cancer Renato Baserga, 1971 |
| genome biology and evolution journal impact factor: The Biology of Genomes: Abstracts of Papers Presented at the 2009 Meeting Held May 5-9, 2009 , 2009 |
| genome biology and evolution journal impact factor: 2018 IEEE International Conference on Mechatronics, Robotics and Automation (ICMRA). , 2018 |
| genome biology and evolution journal impact factor: Computational Methods in Protein Evolution Tobias Sikosek, 2018-10-09 This volume presents a diverse collection of methodologies used to study various problems at the protein sequence and structure level. The chapters in this book look at issues ranging from broad concepts like protein space to specifics like antibody modeling. Topics include point mutations, gene duplication, de novo emergence of new genes, pairwise correlated mutations, ancestral protein reconstruction, homology modelling, protein stability and dynamics, and protein-protein interactions. The book also covers a wide range of computational approaches, including sequence and structure alignments, phylogenies, physics-based and mathematical approaches, machine learning, and more. Written in the highly successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and prerequisites, step-by-step, readily reproducible computational protocols (using command line or graphical user interfaces, sometimes including computer code), and tips on troubleshooting and avoiding known pitfalls. Cutting-edge and authoritative, Computational Methods in Protein Evolution is a valuable resource that offers useful workflows and techniques that will help both novice and expert researchers working with proteins computationally. |
| genome biology and evolution journal impact factor: Theory and Applications of Ontology: Computer Applications Roberto Poli, Michael Healy, Achilles Kameas, 2010-09-17 Ontology was once understood to be the philosophical inquiry into the structure of reality: the analysis and categorization of ‘what there is’. Recently, however, a field called ‘ontology’ has become part of the rapidly growing research industry in information technology. The two fields have more in common than just their name. Theory and Applications of Ontology is a two-volume anthology that aims to further an informed discussion about the relationship between ontology in philosophy and ontology in information technology. It fills an important lacuna in cutting-edge research on ontology in both fields, supplying stage-setting overview articles on history and method, presenting directions of current research in either field, and highlighting areas of productive interdisciplinary contact. Theory and Applications of Ontology: Computer Applications presents ontology in ways that philosophers are not likely to find elsewhere. The volume offers an overview of current research in ontology, distinguishing basic conceptual issues, domain applications, general frameworks, and mathematical formalisms. It introduces the reader to current research on frameworks and applications in information technology in ways that are sure to invite reflection and constructive responses from ontologists in philosophy. |
| genome biology and evolution journal impact factor: Proceedings of 2017 SAR in Big Data Era: Models, Methods and Applications (BIGSARDATA) , |
| genome biology and evolution journal impact factor: Function and Evolution of Repeated DNA Sequences Guy-Franck Richard, 2024-01-31 The genome of a living being is composed of DNA sequences with diverse origins. Beyond single-copy genes, whose product has a biological function that can be inferred by experimentation, certain DNA sequences, present in a large number of copies, escape the most refined approaches aimed at elucidating their precise role. The existence of what 20th century geneticists had already perceived (and wrongly described as junk DNA!) was confirmed by the sequencing of the first complex genomes, including that of Homo sapiens. A large part of what defines a living thing is not unique, but repeated, sometimes a very large number of times, increasing in complexity with successive duplications and multiplication. Understanding and defining the many functions of this myriad of repeated sequences, as well as their evolution through natural selection, has become one of the major challenges for 21st century genomics. |
Genome - Wikipedia
An image of the 46 chromosomes making up the diploid genome of a human male (the mitochondrial chromosomes are not shown). A genome is all the genetic information of an …
Genome
4 days ago · The genome is the entire set of DNA instructions found in a cell. In humans, the genome consists of 23 pairs of chromosomes located in the cell’s nucleus, as well as a small …
What is a genome? | Definition of a genome
A genome is an organism’s complete set of genetic instructions. Each genome contains all of the information needed to build that organism and allow it to grow and develop.
Genome - Definition and Examples - Biology Online Dictionary
Jul 24, 2022 · As defined in biology, a genome is a complete set of deoxyribonucleic acid (DNA) within a living cell. The human cell generally contains up to 3 billion base pairs of DNA, which …
What is genome? - Genetic Education
Jun 19, 2018 · “Entire DNA present in a cell of an organism is called a genome which inherited information from one generation to another and regulates gene expression.” Or in simple …
What is the genome and what does it do? - OCR 21st Century The genome …
Learn about the genome; how it can be used to understand inherited disorders and disease; discover the genetic and environmental causes of variation.
Genome - New World Encyclopedia
Genome is one complete set of hereditary information that characterizes an organism, as encoded in the DNA (or, for some viruses, RNA).
What Is a Genome? | PLOS Genetics
Jul 21, 2016 · The genome is often described as the information repository of an organism. Whether millions or billions of letters of DNA, its transmission across generations confers the …
National Human Genome Research Institute (NHGRI)
Jan 21, 2025 · The Human Genome Project, which had as its primary goal the sequencing of the 3 billion DNA letters that make up the human genetic instruction book, was successfully …
What is a Genome? (with pictures) - AllTheScience
May 21, 2024 · A genome is defined as all the deoxyribonucleic acid that is inside a cell. This includes the DNA in the mitochondria and the chromosomes inside the nucleus of the cell. The …
Genome - Wikipedia
An image of the 46 chromosomes making up the diploid genome of a human male (the mitochondrial chromosomes are not shown). A genome is all the genetic information of an …
Genome
4 days ago · The genome is the entire set of DNA instructions found in a cell. In humans, the genome consists of 23 pairs of chromosomes located in the cell’s nucleus, as well as a small …
What is a genome? | Definition of a genome
A genome is an organism’s complete set of genetic instructions. Each genome contains all of the information needed to build that organism and allow it to grow and develop.
Genome - Definition and Examples - Biology Online Dictionary
Jul 24, 2022 · As defined in biology, a genome is a complete set of deoxyribonucleic acid (DNA) within a living cell. The human cell generally contains up to 3 billion base pairs of DNA, which …
What is genome? - Genetic Education
Jun 19, 2018 · “Entire DNA present in a cell of an organism is called a genome which inherited information from one generation to another and regulates gene expression.” Or in simple …
What is the genome and what does it do? - OCR 21st Century The genome …
Learn about the genome; how it can be used to understand inherited disorders and disease; discover the genetic and environmental causes of variation.
Genome - New World Encyclopedia
Genome is one complete set of hereditary information that characterizes an organism, as encoded in the DNA (or, for some viruses, RNA).
What Is a Genome? | PLOS Genetics
Jul 21, 2016 · The genome is often described as the information repository of an organism. Whether millions or billions of letters of DNA, its transmission across generations confers the …
National Human Genome Research Institute (NHGRI)
Jan 21, 2025 · The Human Genome Project, which had as its primary goal the sequencing of the 3 billion DNA letters that make up the human genetic instruction book, was successfully …
What is a Genome? (with pictures) - AllTheScience
May 21, 2024 · A genome is defined as all the deoxyribonucleic acid that is inside a cell. This includes the DNA in the mitochondria and the chromosomes inside the nucleus of the cell. The …
