Leading researchers in the area of the origin, evolution and distribution of life in the universe contributed to Exobiology: Matter, Energy, and Information in the Origin and Evolution of Life in the Universe. This volume provides a review of this interdisciplinary field. In 50 chapters many aspects that contribute to exobiology are reviewed by 90 authors. These include: historical perspective of biological evolution; cultural aspects of exobiology, cosmic, chemical and biological evolution, molecular biology, geochronology, biogeochemistry, biogeology, and planetology. Some of the current missions are discussed. Other subjects in the frontier of exobiology are reviewed, such as the search for planets outside the solar system, and the possible manifestation of intelligence in those new potential environments. The SETI research effort is well represented in this general overview of exobiology. This book is the proceedings of the Fifth Trieste Conference on Chemical Evolution that took place in September 1997. The volume is dedicated to the memory of Nobel Laureate Abdus Salam who suggested the initiation of the Trieste conferences on chemical evolution and the origin of life. Audience: Graduate students and researchers in the many areas of basic, earth, and life sciences that contribute to the study of chemical evolution and the origin, evolution and distribution of life in the universe.

There are many different types of organisms in the world: they differ in size, physiology, appearance, and life history. The challenge for evolutionary biology is to explain how such diversity arises. The Evolution of Life Histories does this by showing that natural selection is the principal underlying force molding life history variation. The book describes in particular the ways in which variation can be analyzed and predicted. It covers both the genetic and optimization approaches to life history analysis and gives an overview of the general framework of life history theory and the mathematical tools by which predictions can be made and tested. Factors affecting the age schedule of birth and death and the costs of reproduction are discussed. The Evolution of Life Histories concentrates on those theoretical developments that have been tested experimentally. It will interest both students and professionals in evolution, evolutionary ecology, mathematical and theoretical biology, and zoology and entomology.

Elie Metchnikoff (1845-1916), winner of the Nobel Prize in 1907 for his contributions to immunology, was first a comparative zoologist, who, working in the wake of Darwin's On the Origin of Species, made seminal contributions to evolutionary biology. His work in comparative embryology is best known in regard to the debates with Ernst Haeckel concerning animal genealogical relationships and the theoretical origins of metazoans. But independent of those polemics, Metchnikoff developed his phagocytosis theory' of immunity as a result of his early comparative embryology research, and only in examining the full breadth of his work do we appreciate his signal originality. Metchnikoff's scientific papers have remained largely untranslated into English. Assembled here, annotated and edited, are the key evolutionary biology papers dating from Metchnikoff's earliest writings (1865) to the texts of his mature period of the 1890s, which will serve as an invaluable resource for those interested in the historical development of evolutionary biology.

Developmental Instability: Its Origins and Evolutionary Implications is a collection of papers and transcribed discussions from a conference held in Tempe, Arizona in June 1993. The papers represent a wide range of contributions, from the empirical to the theoretical, and include methods for measuring developmental instability across a variety of taxa and traits. This volume presents contrasting views on how to assess developmental instability as well as on the relationship of instability to genotypic factors, environmental factors and the action of natural and sexual selection. Readers will derive a working knowledge of the best way to assess developmental instability and will be able to design future work in an authoritative way.

Current theories about human memory have been shaped by clinical observations and animal experiments. This doctrine holds that the medial temporal lobe subserves one memory system for explicit or declarative memories, while the basal ganglia subserves a separate memory system for implicit or procedural memories, including habits. Cortical areas outside the medial temporal lobe are said to function in perception, motor control, attention, or other aspects of executive function, but not in memory. 'The Evolution of Memory Systems' advances dramatically different ideas on all counts. It proposes that several memory systems arose during evolution and that they did so for the same general reason: to transcend problems and exploit opportunities encountered by specific ancestors at particular times and places in the distant past. Instead of classifying cortical areas in terms of mutually exclusive perception, executive, or memory functions, the authors show that all cortical areas contribute to memory and that they do so in their own ways-using specialized neural representations. The book also presents a proposal on the evolution of explicit memory. According to this idea, explicit (declarative) memory depends on interactions between a phylogenetically ancient navigation system and a representational system that evolved in humans to represent one's self and others. As a result, people embed representations of themselves into the events they experience and the facts they learn, which leads to the perception of participating in events and knowing facts. 'The Evolution of Memory Systems' is an important new work for students and researchers in neuroscience, psychology, and biology.

This volume is based upon the seventeenth series of lectures delivered at Yale University on the Foundation established by the late Dwight H. Terry of Plymouth, Connecticut, through his gift of an endowment fund for the delivery and subsequent publication of "Lectures on Religion in the Light of Science and Philosophy." The deed of gift declares that "the object of this Foundation is not the promotion of scientific investigation and discovery, but rather the assimilation and interpretation of that which has been or shall be hereafter discovered, and its application to human welfare, especially by the building of the truths of science and philosophy into the structure of a broadened and purified religion. Dr. Millikan believes "modern science of the real sort is slowly learning to walk humbly with its God."

This book aims at defining and reassessing the role of population genetics in conservation biology and seeks to identify the progress made in the field during the last decade. It deals with conservation genetics from several currently researched points of view, namely, ecological and demographic measures of rarity or population persistence, loss of genetic variation, inbreeding, reduced migration rates and increased selective pressures under stress and the role of social behaviour and metapopulation structure. The use of molecular variation as the basis of naming or selecting target taxa and some strategic decisions about genetic variance maximization in the conserved population or community units are analysed. Several case studies and scenarios illustrate the application of genetic information in conservation practices.

In this examination of problems in the modern world, Michio Kitahara argues that a logical inconsistency in the philosophy of Enlightenment has caused humans to approach their environment in a way that is inconsistent with their biological background. Human biological and cultural evolution has created a form of suffering that derives in part from Western civilization's simultaneous acceptance and rejection of human variation. Both specialists and the general public assume that evolution is good and desirable, but Kitahara's analysis suggests the opposite: that evolution itself is tragic.

In his analysis of human evolution, Kitahara discusses deviant and criminal behavior, social conflict, liberalism, and the nature of Western civilization. He holds two axiomatic assumptions: that humans are characterized by stimulus seeking behavior accompanied by the manipulatory drive, and that humans are characterized by physical, psychological and cultural variation. He argues that the tyranny of the majority and the technology we have developed deny human variation, and that the drive to manipulate the environment is the wellspring of modern, sociocultural phenomena. This book will be of interest to scholars of anthropology, sociology, philosophy, history, political science, and environmental studies.

In the preface to Sir Vincent B. Wigglesworth's classic 1939 book on insect physiology he asserted that insects provide an ideal medium in which to study all the problems of physiology. A strong case can be made as well for the use of insects as significant systems for the study of behavior and genetics. Contributions to genetics through decades of research on Drosophila species have made this small fly the most important metazoan in genetics research. At the same time, population and behavioral research on insects and other invertebrates have provid ed new perspectives that can be combined with the genetics approach. Through such in tegrated research we are able to identify evolutionary genetics of behavior as a highly signifi cant emerging area of interest. These perspectives are ably described by Dr. Guy Bush in the introductory chapter of this book. During March 21-24, 1983, many of the world's leading scientists in invertebrate behavioral genetics were drawn together in Gainesville, Florida, for a colloquium entitled "Evolutionary Genetics of Invertebrate Behavior." This conference was sponsored jointly by the Department of Entomology and Nematology, University of Florida, chaired by Dr. Daniel Shankland, and the Insect Attractants, Behavior and Basic Biology Research Laboratory, U.S. Department of Agriculture, directed then by Dr. Derrell Chambers."

The increasing interest during recent years in vegetation history, long-term climatic changes and the development of biotic communities has resulted in a growth of the literature in this field and has provided an incentive for scientists to use palaeo-ecology concepts to clarify contemporary ecological issues. Quaternary ecology offers the perspective of time, in using "natural experiments of the past" to evaluate the responses of population, communities and ecosystems to climatic and environmental changes on a time scale extending back over the past two million years of the quaternary period. Examples from the palaeo-ecological literature demonstrate how quaternary ecology interfaces with other branches of ecology, including plant demography, ecological genetics, limnology and landscape ecology. The book provides an integrated overview of this interdisciplinary area. The authors examine the validity of space for time substitution in studies of plant succession, the individualistic nature of species migrations and invasions of pre-existing communities, the disassembly and reassembly of communities following major environmental change and the applications of quaternary ecology to predicting biotic responses to future global climatic change. By examining key ecological issues and controversies that can be approached fruitfully using palaeo-ecological methods, this book is intended to complement rather than replace traditional textbooks in ecology and palaeo-ecology.

This two-volume work is a testament to the abiding interest and human fascination with ammonites. We offer a new model to explain the morphogenesis of septa and the shell, we explore their habitats by the content of stable isotopes in their shells, we discuss the origin and later evolution of this important clade, and we deliver hypotheses on its demise. The Ammonoidea produced a great number of species that can be used in biostratigraphy and possibly, this is the macrofossil group, which has been used the most for that purpose. Nevertheless, many aspects of their anatomy, mode of life, development or paleobiogeographic distribution are still poorly known. Themes treated are biostratigraphy, paleoecology, paleoenvironment, paleobiogeography, evolution, phylogeny, and ontogeny. Advances such as an explosion of new information about ammonites, new technologies such as isotopic analysis, tomography and virtual paleontology in general, as well as continuous discovery of new fossil finds have given us the opportunity to present a comprehensive and timely "state of the art" compilation. Moreover, it also points the way for future studies to further enhance our understanding of this endlessly fascinating group of organisms.

In January 1995 the first Complexity Seminar was held at the London School of Economics, in the UK. This was quite a momentous occasion as it proved to be the turning point for the series of seminars, which had started in December 1992. That seminar and those that followed it, had a profound effect on the research interests of Eve Mitleton-Kelly, the initiator and organiser of the series and editor of this volume, and thus laid the foundation for what became the LSE Complexity Research Programme, which proceeded to win several research awards for collaborative projects with companies. But the series also provided the material for this book. Earlier versions of the papers selected for this volume were first given at the LSE Complexity Seminar series.
The seminar series, focussed primarily on the application of the theories of complexity to organisations - an area of study which was quite new to UK businesses and academics; it slowly helped to disseminate these ideas and today, there is a proliferation of networks and seminar series throughout the UK on complexity; a strong and active academic community studying complexity in different disciplines and a growing number of organisations, experimenting with these revolutionary ideas and putting them into practice.
The 14 international authors in this volume reflect this interest in 10 chapters that range from the very practical application of the theory to more philosophical reflections on its nature and applicability. They do not all agree with each other, but since diversity and variety is at the heart of complexity they each provide a strand of an intertwined whole, which will enrich and deepen our understanding. In an environmentof increasing uncertainty and ambiguity it is necessary to learn how to hold, in tension, disparate or even contradictory views, without undue stress. The world is not a simple dyadic black or white entity, but a rich multi-coloured and many-hued ensemble, each strand or perspective contributing to an intricate and inter-related n-dimensional whole.

The evolution versus creationism conflict is here to stay. Even after their devastating defeat in the "Kitzmiller v. Dover" decision, advocates of intelligent design and other forms of creationism continue to revise their strategies for undermining the teaching of evolution-and thus of science in general-in American schools. In this revision of "Evolution vs. Creationism," Eugenie Scott, one of the leading proponents of teaching evolution in the schools, describes these ever-changing efforts to undermine science education and shows what students, parents, and teachers should be aware of to help ensure that American science education prepares our students to compete in the 21st century.

This second edition of "Evolution vs. Creationism" will help readers better understand the issues involved in these debates. It expands and updates the original work with an insider's look at the "Kitzmiller v. Dover" trial, a new selection of primary source documents on the Creationism/Evolution controversy in the media, and an up-to-date analysis of the most recent creationist challenges across the country.

The revision also expands and updates the collection of primary source documents that address cosmology, law, education, popular culture, and religious issues from all sides of the debate, as well as the resources for further information.

The dicynodonts, an important group of permo-triassic reptiles, were the first really successful herbivorous tetrapods. Moreover they provided the bulk of the prey species for the ecosystem in which the mammals evolved, which makes them interesting in a wider context. The dicynodonts left an abundant fossil record, mainly in what is now southern and eastern Africa. This abundance enables investigation of their community structure and permits observations to be made on the changes in diversity that the group underwent throughout history. Such palaeoecological studies are becoming increasingly important since they have direct bearing on the evolution of other fossil groups. Their detailed preservation allows functional considerations to be derived from structure, providing evidence for discussion of reproduction, thermoregulation and social behaviour - all important aspects of the study of the evolution of mammals. These studies are summarized by a recognized expert in the field and should be valuable to those interested in evolution, palaeoecology and palaeobiology, as well as geologists and zoologists. This book should be of interest to evolutionary biologists, palaeoecologists, palaeobiologists, geologists and zoologists.

Converging evidence from disciplines including sociobiology, evolutionary psychology and human biology forces us to adopt a new idea of what it means to be a human. As cherished concepts such as free will, naive realism, humans as creation's crowning glory fall and our moral roots in ape group dynamics become clearer, we have to take leave of many concepts that have been central to defining our humanness. What emerges is a new human, the homo novus, a human being without illusions. Leading authors from many different fields explore these issues by addressing a range of illusions and providing evidence for the need, despite considerable reluctance, to relinquish some of our most cherished ideas about ourselves.

Modern approaches to microbial classification and identification, particularly those based on nucleic acid analysis, have raised the awareness and interest of microbiologists in systematics during the past decade. The extended scope of the subject has revolutionized microbial ecology with the demonstration of uncultivable microorganisms as a major component of the biosphere and evolution, with the ribosomal RNA phylogenetic tree as the basis of current classifications. However, advances in microbial systematics have also had enormous impact on other, diverse aspects of microbiology such as animal pathogenicity, plant-microbe interactions and relationships with food. In this book, we survey and discuss in depth the contribution of modern taxonomic approaches to our understanding of the microbiology of these various systems. The book does not concentrate on methods - these have been well reported elsewhere - instead it provides a unique insight into the application and value of modern systematics in diverse branches of microbiology. It will be of value to microbiologists at both research and technical levels who need to appreciate the range of organisms with which they work and the diversity within them. It will also be of value to teachers and students of microbiology courses who want to understand how systematics can enhance microbiology beyond the routine of classification, nomenclature, and identification.

Fifty thousand years ago--merely a blip in evolutionary time--our "Homo sapiens" ancestors were competing for existence with several other human species, just as their precursors had done for millions of years. Yet something about our species distinguished it from the pack, and ultimately led to its survival while the rest became extinct. Just what was it that allowed "Homo sapiens" to become masters of the planet? Ian Tattersall, curator emeritus at the American Museum of Natural History, takes us deep into the fossil record to uncover what made humans so special. Surveying a vast field from initial bipedality to language and intelligence, Tattersall argues that "Homo sapiens" acquired a winning combination of traits that was not the result of long-term evolutionary refinement. Instead, the final result emerged quickly, shocking our world and changing it forever.

Molecular approaches have opened new windows on a host of ecological and evolutionary disciplines, ranging from population genetics and behavioral ecology to conservation biology and systematics. Molecular Markers, Natural History and Evolution summarizes the multi-faceted discoveries about organisms in nature that have stemmed from analyses of genetic markers provided by polymorphic proteins and DNAs. The first part of the book introduces rationales for the use of molecular markers, provides a history of molecular phylogenetics, and describes a wide variety of laboratory methods and interpretative tools in the field. The second and major portion of the book provides a cornucopia of biological applications for molecular markers, organized along a scale from micro-evolutionary topics (such as forensics, parentage, kinship, population structure, and intra-specific phylogeny) to macro-evolutionary themes (including species relationships and the deeper phylogenetic structure in the tree of life). Unlike most prior books in molecular evolution, the focus is on organismal natural history and evolution, with the macromolecules being the means rather than the ends of scientific inquiry. Written as an intellectual stimulus for the advanced undergraduate, graduate student, or the practicing biologist desiring a wellspring of research ideas at the interface of molecular and organismal biology, this book presents material in a manner that is both technically straightforward, yet rich with concepts and with empirical examples from the world of nature.

The amount of information that can be obtained by using molecular techniques in evolution, systematics and ecology has increased exponentially over the last ten years. The need for more rapid and efficient methods of data acquisition and analysis is growing accordingly. This manual presents some of the most important techniques for data acquisition developed over the last years. The choice and justification of data analysis techniques is also an important and critical aspect of modern phylogenetic and evolutionary analysis and so a considerable part of this volume addresses this important subject. The book is mainly written for students and researchers from evolutionary biology in search for methods to acquire data, but also from molecular biology who might be looking for information on how data are analyzed in an evolutionary context. To aid the user, information on web-located sites is included wherever possible. Approaches that will push the amount of information which systematics will gather in the

This volume brings together, for the first time, a wide range of up-to-the-minute and traditional techniques and approaches to the study of genetics of organisms living in freshwater or marine habitats. Carefully edited chapters are headed by broad review articles against which are set a number of more specific experience papers which demonstrate the breadth and range of approaches currently being undertaken.

The annual Evolutionary Biology Meetings in Marseille aim to bring together leading scientists, promoting an exchange of state-of-the-art knowledge and the formation of inter-group collaborations. This book presents the most representative contributions to the 13th meeting, which was held in September 2009. It comprises 21 chapters, which are organized into the following three categories: * Evolutionary Biology Concepts * Genome/Molecular Evolution * Morphological Evolution/Speciation This book offers an up-to-date overview of evolutionary biology concepts and their use in the biology of the 21st century.

The topics of style and function within evolutionary archaeology have been the subject of great debate in the field of archaeology in general over the past two decades. Evolutionary archaeologists have a unique perspective on these concepts-one that has sometimes been misunderstood by archaeologists working within other theoretical perspectives.

The dichotomy between style and function was first formulated in the late 1970s by Robert Dunnell and remains axiomatic within the theoretical perspective of evolutionary archaeology. The original definitions of style and function were grounded in biological evolutionary concepts regarding neutral variation versus variation that is subject to natural selection. Several chapters expand upon these concepts, and explore how Darwinian evolutionary theory may be used to understand the archaeological record. Other chapters demonstrate this application through empirical case studies. Dunnell provides a foreword introducing and re-examining his original thesis.

This volume is the only text devoted to the topic of style and function within the literature of evolutionary archaeology. It provides not only theoretical discussions and augmentation, but also significant historical background regarding the development of the style/function distinction within archaeology. Moreover, it presents several case studies that provide examples of how evolutionary style and function may be applied to the prehistoric record.

With contributions from a team of leading experts, this volume provides a comprehensive survey of recent achievements in our scientific understanding of evolution. The questions it asks concern the beginnings of the universe, the origin of life and the chances of its arising at all, the role of contingency, and the search for universal features in the plethora of evolutionary phenomena. Rather than oversimplified or premature answers, the chapters provide a clear picture of how these essential problems are being tackled, enabling the reader to understand current thinking and open questions. The tools employed stem from a range of disciplines including mathematics, physics, biochemistry and cell biology. Self-organization as an overarching concept is demonstrated in the most diverse areas: from galaxy formation in the universe to spindle and aster formation in the cell. Chemical master equations, population dynamics, and evolutionary game theory are presented as suitable frameworks for understanding the universal mechanisms and organizational principles observed in a wide range of living units, ranging from cells to societies. This book will provide engaging reading and food for thought for all those seeking a deeper understanding of the science of evolution.

The three well known revolutions of the past centuries - the Copernican, the Darwinian and the Freudian - each in their own way had a deflating and mechanizing effect on the position of humans in nature. They opened up a richness of disillusion: earth acquired a more modest place in the universe, the human body and mind became products of a long material evolutionary history, and human reason, instead of being the central, immaterial, locus of understanding, was admitted into the theater of discourse only as a materialized and frequently out-of-control actor. Is there something objectionable to this picture? Formulated as such, probably not. Why should we resist the idea that we are in certain ways, and to some degree, physically, biologically or psychically determined? Why refuse to acknowledge the fact that we are materially situated in an ever evolving world? Why deny that the ways of inscription (traces of past events and processes) are co-determinative of further "evolutionary pathways"? Why minimize the idea that each intervention, of each natural being, is temporally and materially situated, and has, as such, the inevitable consequence of changing the world? The point is, however, that there are many, more or less radically different, ways to consider the "mechanization" of man and nature. There are, in particular, many ways to get the message of "material and evolutionary determination," as well as many levels at which this determination can be thought of as relevant or irrelevant.

This volume is a collection of the some of the most significant lectures that well-known experts presented at our two international summits on evolution (2005, 2009) as updated and revised chapters. The meetings took place on one of the large islands of the Galapagos archipelago (San Cristobal) at GAIAS (Galapagos Institute for the Arts and Sciences) of the Universidad San Francisco de Quito (USFQ), Ecuador. The main goal of the two Galapagos Summits on Evolution has been to bring together scientists and graduate students engaged in the study of evolution, from life s origin to its current diversity. Because of their historical significance, the Galapagos are a unique venue for promoting comprehensive research on evolution and ecology and to make the research results available to students and teachers everywhere, but especially from developing countries. As shown by the enthusiastic attendance at both summits and the many suggestions to keep them continuing, the meetings have opened new opportunities for students from Ecuador and other Latin American countries to be inspired by some of the most brilliant minds in evolutionary science.