The Geographic Mosaic of Coevolution
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Picking up where his influential The Coevolutionary Process left off, John N. Thompsonsynthesizes the state of a rapidly developing science that integrates approaches from evolutionary ecology, population genetics, phylogeography, systematics, evolutionary biochemistry and physiology, and molecular biology. Using models, data, and hypotheses to develop a complete conceptual framework, Thompson also draws on examples from a wide range of taxa and environments, illustrating the expanding breadth and depth of research in coevolutionary biology.
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The Geographic Mosaic of Coevolution - John N. Thompson
The University of Chicago Press, Chicago 60637
The University of Chicago Press, Ltd., London
© 2005 by The University of Chicago
All rights reserved. Published 2005
Printed in the United States of America
14 13 12 11 10 09 08 07 5 4 3 2
ISBN (cloth): 0-226-79761-9
ISBN (paper): 0-226-79762-7
ISBN (e-book): 978-0-226-11869-7
Library of Congress Cataloging-in-Publication Data
Thompson, John N.
The geographic mosaic of coevolution / John N. Thompson.
p. cm.—(Interspecific interactions)
Includes index.
ISBN 0-226-79761-9 (cloth : alk. paper)—ISBN 0-226-79762-7 (alk. paper)
1. Coevolution. I. Title. II. Series.
QH372.T482 2005
576.8'7—dc22
2004023861
The paper used in this publication meets the minimum requirements of the American National Standard for Information Sciences—Permanence of Paper for Printed Library Materials, ANSI Z39.48-1992.
The Geographic Mosaic of Coevolution
John N. Thompson
The University of Chicago Press
Chicago and London
INTERSPECIFIC INTERACTIONS
A series edited by John N. Thompson
Contents
Preface
Acknowledgments
Part 1. The Framework of Coevolutionary Biology
1. The Overall Argument
2. Raw Materials for Coevolution I: Populations, Species, and Lineages
3. Raw Materials for Coevolution II: Ecological Structure and Distributed Outcomes
4. Local Adaptation I: Geographic Selection Mosaics
5. Local Adaptation II: Rates of Adaptation and Classes of Coevolutionary Dynamics
6. The Conceptual Framework: The Geographic Mosaic Theory of Coevolution
7. Coevolutionary Diversification
8. Analyzing the Geographic Mosaic of Coevolution
Part 2. Specific Hypotheses on the Classes of Coevolutionary Dynamics
9. Antagonists I: The Geographic Mosaic of Coevolving Polymorphisms
10. Antagonists II: Sexual Reproduction and the Red Queen
11. Antagonists III: Coevolutionary Alternation and Escalation
12. Mutualists I: Attenuated Antagonism and Mutualistic Complementarity
13. Mutualists II: The Geographic Mosaic of Mutualistic Symbioses
14. Mutualists III: Convergence within Mutualistic Networks of Free-Living Species
15. Coevolutionary Displacement
16. Applied Coevolutionary Biology
Appendix: Major Hypotheses on Coevolution
Literature Cited
Index
Preface
Coevolution is reciprocal evolutionary change between interacting species driven by natural selection. It is one of the most important ecological and genetic processes organizing earth’s biodiversity. My goal in this book is to synthesize what we now know about the ways in which coevolution links species across space and time, connecting populations across landscapes and sometimes holding interactions together over thousands, even millions, of years. My parallel goal is to suggest where we can next make the greatest gains as we study coevolution in natural and fragmented environments and even try our hand at manipulating the coevolutionary process.
Together with many others I have been working for over thirty years toward the development of a framework for the science of coevolutionary biology. I have synthesized our collective progress in two previous books: Interaction and Coevolution (1982) and The Coevolutionary Process (1994). The first book confronted the problem of how different forms of interaction impose different selection pressures on interacting species. It appeared at a time when coevolutionary studies were still mostly at a stage of describing adaptations and counteradaptations of interacting taxa. My purpose then was to explore ways of moving beyond those descriptions to reach an understanding of coevolutionary selection that transcends taxonomic boundaries.
The Coevolutionary Process synthesized what we had learned in the twelve years since 1982. In that book I suggested how selection on specialization and the geographic structure of species could partition diffuse coevolution
into more specific coevolutionary processes. My intent was to bridge the gap between studies of coevolution within local communities and studies of diversification in interacting phylogenetic lineages, thereby creating a more hierarchical view of the structure of coevolution. By emphasizing the geographic structure of interactions, I argued that much of the coevolutionary process occurs above the level of local populations but below the level of the fixed traits of species. That is, much of the coevolutionary process falls between what were then the traditional approaches of evolutionary ecology and genetics on the one hand and systematics on the other. I called that overall view the geographic mosaic theory of coevolution, but at the time all I could do was develop the general arguments and suggest the kinds of theoretical and empirical studies needed to explore the structure and dynamics of co-evolution within that framework.
Since the mid-1990s, coevolution has come into its own as new studies have taken increasingly rigorous approaches to the structure and dynamics of the coevolutionary process. The major advance has come from confronting the genetic, ecological, geographic, and phylogenetic structure of real species. Rather than treating local coevolution as indicative of the overall structure of coevolving species, we now have a solid set of theoretical and empirical studies that begin with the fact that almost all species are collections of genetically differentiated populations. Mathematical models of the coevolutionary process have begun to formalize how geographic selection mosaics, coevolutionary hotspots, and trait remixing interact to create pattern and dynamics. These models create coevolutionary dynamics different from those envisaged for isolated interactions within local communities. There is still plenty to do, but the models have begun to show how coevolutionary hotspots may develop within geographic landscapes and how local maladaptation may sometimes occur as an outcome of the coevolutionary process. We also now have a growing set of empirical studies that have analyzed the same interspecific interaction in multiple populations across broad geographic landscapes. These studies include evaluations of the scale of geographic selection mosaics, the structure of coevolutionary hotspots, and the effects of trait remixing as gene flow, local extinction, and random genetic drift shape geographic patterns. The study of local matches and mismatches in the traits of coevolving species has become an important component of studies evaluating ongoing coevolutionary dynamics.
We also now have multiple studies that have analyzed the current coevolutionary structure of species within a phylogenetic context. These studies suggest that only a small subset of coevolving traits may eventually scale up to become fixed traits of species. A few traits often become the focus for co-evolution, but those traits may vary among populations. We now understand that evaluation of the overall importance of coevolution to an interaction requires a thorough analysis of the geographic mosaic of coevolving traits.
Together, these ecological, genetic, mathematical, and phylogenetic studies are creating a view of coevolutionary dynamics that was not possible a decade ago. It is a view of coevolution as an ongoing ecological process that has fundamental importance for the maintenance of genetic diversity and the organization of biodiversity across landscapes worldwide. This book, then, is not about coevolution as a slow and stately process molding species through sustained directional selection over long periods of evolutionary time. That view creates a caricature of the coevolutionary process and boxes it into a nonecological framework. By that view, ongoing coevolutionary dances—meanderings, if you will—become meaningless fine adjustments, because they are often nondirectional and do not lead to major new events in the history of life. Instead, this book is explicitly an exploration of workaday co-evolution, the relentless dynamics of the coevolutionary process that keep the players in the evolutionary game as they respond and counterrespond to each other, population by population, across landscapes. By the time I had finished the book, I realized that it is also a statement about why an evolution-free approach to ecology, parasitology, epidemiology, biological control, agriculture, forestry, wildlife biology, and fisheries biology is never justifiable as we attempt to manage a rapidly changing earth. Ecological time scales are also evolutionary time scales.
The Geographic Mosaic of Coevolution develops a conceptual framework for coevolutionary biology in two stages. Part 1 sets forth the overall framework. It begins with an analysis of the fundamental properties of species that provide the raw material for long-term coevolution across constantly changing landscapes. It then progresses to an evaluation of what we have learned about local coadaptation as the basic module of coevolutionary change. Once that background is in place, the remaining chapters of part 1 explore how the geographic mosaic of coevolution reshapes these local modules over space and time as interacting species diversify across landscapes. These chapters include a formal development of the geographic mosaic theory of coevolution. They also include an analysis of the longer-term phylogenetic patterns that result from the geographic mosaic of coevolution. Part 1 ends with a discussion of forms of evidence in analyses of coevolution.
Part 2 then evaluates specific hypotheses that follow from the geographic mosaic of coevolution. In particular, these chapters evaluate how the geographic mosaic of coevolution maintains genetic polymorphisms, creates multispecific networks of antagonistic trophic interaction, shapes levels of resistance and virulence, contributes to the dynamics of sexual reproduction, favors convergence of traits in mutualistic symbioses and mutualistic networks of free-living species, and molds competitive interactions across large geographic scales. Part 2 ends with a discussion of the developing science of applied coevolutionary biology.
Almost all the work I evaluate in these chapters comes from studies published in the decade after The Coevolutionary Process appeared in print. The number of studies of coevolution has increased so much in recent years that it is impossible to cite within a single book the entire history of work on particular topics. The Coevolutionary Process included an extended discussion of the history of coevolutionary theory from Darwin to the early 1990s, and that book remains in print. Consequently, I have restricted most citations in this book to papers published since 1994. In some cases, however, I have reached back into the older literature to provide a context for current arguments, views, and results.
These chapters do not provide an encyclopedia of coevolutionary models and examples. Instead, I use a wide range of empirical and theoretical studies to develop four points. First, we have in hand a developing conceptual framework that can help us organize our understanding of the structure and dynamics of coevolution. Second, coevolution is much more of an ongoing, highly dynamic process than we had previously thought. Third, coevolutionary dynamics are important for our understanding of the organization of communities even when they do not lead to long-term directional change. Last, a thorough understanding of the coevolutionary process is increasingly important as we face up to major societal concerns ranging from the rapid evolution of pathogens to the conservation of biodiversity.
Acknowledgments
I am indebted to the many colleagues who have generously shared thoughts, models, and results on the coevolutionary process. I am especially grateful to the following colleagues for discussions or responses to emails during crucial stages in the writing of this book, comments on sections of the manuscript, or preprints that helped me make this book as up to date as possible: Scott Armbruster, Jordi Bascompte, Fakhri Bazzaz, Craig Benkman, May Berenbaum, Giacomo Bernardi, Paulette Bierzychudek, Brendan Bohannan, Jacobus Boomsma, Paul Brakefield, Edmund D. Brodie Jr., Edmund D. Brodie III, Judie Bronstein, James Brown, Jeremy Burdon, Mark Carr, Scott Carroll, Patrick Carter, Yves Carton, Keith Clay, Gretchen Dailey, Peter de Jong, Paul Ehrlich, Niles Eldredge, James Estes, Stanley Faeth, Brian Farrell, Steven Frank, Laurel Fox, Douglas Futuyma, Sylvain Gandon, Sergey Gavrilets, Gregory Gilbert, Douglas Gill, Susan Harrison, Alan Hastings, Edward Allen Herre, Michael Hochberg, Robert Holt, David Jablonski, Jeremy Jackson, Pedro Jordano, Richard Lenski, Bruce Lieberman, Curt Lively, Jonathan Losos, Bruce Lyon, Marc Mangel, Mark McPeek, Kurt Merg, William Miller III, Martin Morgan, Jens Nielsen, Sören Nylin, Takayuki Ohgushi, Jens Olesen, John Pandolfi, Ingrid Parker, Matthew Parker, David Pfennig, Naomi Pierce, Grant Pogson, Don Potts, Peter Price, Peter Raimondi, O. J. Reichman, David Reznick, Kevin Rice, Victor Rico-Gray, Joan Roughgarden, Douglas Schemske, Dolph Schluter, Daniel Simberloff, Douglas Soltis, Pamela Soltis, Victoria Sork, Maureen Stanton, Sharon Strauss, Alan Templeton, David Tilman, James Trappe, Michael Turelli, Geerat Vermeij, Sara Via, Thomas Whitham, Christer Wiklund, and Arthur Zangerl. I am very grateful to Richard Gomulkiewicz and Scott Nuismer for ongoing and stimulating collaborations on formal mathematical models of the geographic mosaic of coevolution.
I thank Jeremy Burdon and Stanley Faeth for their many helpful comments on the outline for the book; Craig Benkman, Edmund Brodie III, Scott Nuismer, and Peter Thrall for their tremendously helpful comments on the entire manuscript; and colleagues in my laboratory at UCSC over the past year—Catherine Fernandez, Samantha Forde, Jason Hoeksema, Phillip Hoos, Katherine Horjus—for their insightful discussions and comments on the penultimate draft. I am indebted to the past and current graduate students, postdoctoral fellows, research associates, sabbatical visitors, and technical assistants who have kept our ongoing laboratory meetings on the co-evolutionary process so intellectually challenging over the years. During the gestation and writing of this book they have included David Althoff, Paulette Bierzychudek, Ryan Calsbeek, Bradley Cunningham, Catherine Fernandez, Samantha Forde, David Hembry, Jason Hoeksema, Phillip Hoos, Katherine Horjus, Niklas Janz, Kurt Merg, Scott Nuismer, James Richardson, and Kari Segraves.
I thank Catherine Fernandez for carefully drafting the figures, Abby Young for help with final preparation of the manuscript, and Barbara Norton for copyediting. Christie Henry has provided unflagging editorial insight, encouragement, and guidance. As always, I am deeply grateful to my wife, Jill Thompson, for her suggestions and support throughout the long process of writing a book like this one.
I am also very grateful to the organizations that have provided funds for my research and collaborations with others over the past decade, including the National Science Foundation, the National Center for Ecological Analysis and Synthesis (NCEAS), the Packard Foundation, the American Society of Naturalists, Washington State University, and the University of California, Santa Cruz. NCEAS has provided multiple forms of support, including a sabbatical year of work on coevolution, a workshop on rapid evolutionary change, a working group on mathematical models of coevolution, and a separate working group on evolutionary rates that brought together paleobiologists and population biologists. I thank all my colleagues who shared their thoughts in these meetings and working groups.
Part 1
The Framework of Coevolutionary Biology
1
The Overall Argument
This book uses the unifying framework of the geographic mosaic of coevolution to confront the major challenges in coevolutionary research: how species coevolve as groups of genetically distinct populations, how coevolving interactions can be locally transient yet persist for millions of years, and how networks of species coevolve. It is one thing to understand that a local interaction between a pair of populations eventually reaches genetic equilibrium under constant selection. It is quite another to understand how interspecific interactions are sometimes held together across millennia as species expand, contract, and diversify across complex and ever-changing landscapes. Local interacting pairs of populations are genetically linked to other populations of the same species, and these geographically variable interactions are embedded within even broader interaction networks.
The geographic and network complexity of interactions enriches the co-evolutionary process. There is no more reason to expect a priori that multi-specific interactions prevent coevolution than there is to expect that multiple influences of the physical environment—temperature, salinity, water, and light availability—prevent the evolution of populations. Whether researching evolution in general or coevolution in particular, all populations are confronted with multiple selection pressures and evolutionary processes. The scientific problem is to understand how species evolve in the midst of multiple conflicting selection pressures, and how species coevolve across complex landscapes amid interactions with multiple other species.
Background
Much of evolution is coevolution—the process of reciprocal evolutionary change between interacting species driven by natural selection. Most species survive and reproduce only by using a combination of their own genome and that of at least one other species, either directly or indirectly. Species evolve to a large degree by co-opting and manipulating other free-living species or by acquiring the entire genomes of other species through parasitic or mutualistic symbiotic relationships. The evolution of biodiversity is therefore largely about the evolution of interaction diversity.
As the science of coevolutionary biology has matured, we have been returning to a Darwinian appreciation of the entangled bank and an ecological approach to evolution that was largely put on hold during much of the twentieth century amid the excitement of the discovery of genes and the subsequent growth of population genetics and molecular biology. (See Thompson 1994 for a history of coevolutionary biology.) Those genetic and molecular tools have now become part of a renaissance in coevolutionary research, because they have begun to uncover the role of coevolution in the genomic and geographic complexity of life. Even hypotheses of speciation are increasingly based upon ecological and genetic processes driven directly by evolving interspecific interactions, whether by competition or by parasites that manipulate host reproduction.
Not all interactions are tightly coevolved. Nevertheless, as we learn more each year about the evolutionary ecology and genetics of species, we are finding that coevolution is a pervasive and ongoing influence on the organization of biodiversity. We now know that interactions between species can evolve and coevolve within decades. Appreciation of the speed of coevolution is increasing as the disciplines of ecology and evolutionary biology have encompassed studies of pathogens and parasites and incorporated molecular approaches. The traditional study organisms of ecology—plants, insects, rocky-intertidal invertebrates, fish, amphibians, reptiles, birds, and mammals—are now being complemented by studies of a wider array of invertebrates, fungi, bacteria, and viruses. During the past twenty years, the bacterial genus Wolbachia and similar intracellular symbionts have moved from being seen as interesting but esoteric causes of reproductive isolation or male sterility in a few insect species to becoming recognized as potential major causes of differentiation in the life history and population structure of a diverse mix of invertebrates. A universe of previously unknown and rapidly evolving interactions is opening as new molecular and ecological tools allow us to probe a wider range of the diversity of life.
We are also beginning to understand better the profound effects of co-evolution on human societies. Human history is partly a history of coevolution with the parasites and pathogens that have shaped the spread of our species and our cultures worldwide. The story of human agriculture is to a great degree the story of human-induced coevolution between crop plants and rapidly evolving parasites and pathogens. In recent years, the fields of epidemiology, agriculture, aquaculture, forestry, and conservation biology have all become increasingly attuned to the importance of ongoing coevolution and its effects on our lives. We have, in fact, made manipulation of the coevolutionary process a central part of our human repertoire. We spend billions of dollars a year on antibiotic development, and we are working toward engineering genes to help us fight our battles with parasites, using gene against gene and parasite against parasite.
These efforts are a continuation in different forms of the coevolutionary process that has molded the organization of life on earth. There is now little question that coevolution has shaped many of the major events in the history of life. Even a short list of these events encompasses most species. The eukaryotic cell originated from coevolved symbiotic interactions that became so tightly integrated that one of the species was shaped into the organelles we now call mitochondria. The same happened again in the formation of plants, creating the organelles we now call chloroplasts. Colonization of land by plants may have been made possible through mutualistic interactions with mycorrhizal fungi. Further proliferation of plants occurred partly through coevolved interactions between flowers and pollinators and partly through coevolution with other mutualists, as well as with herbivores and pathogens. The more than seventeen thousand orchid species are thought to rely upon mycorrhizal fungi for nutrition in the early stages of development following germination, because the dustlike seeds of most orchids carry little in the way of nutritional reserves. Primary succession in terrestrial environments relies heavily upon the coevolved interactions called lichens, and subsequent succession depends in many communities upon the coevolved nitrogen-fixation symbioses between rhizobial bacteria and legumes. The very survival of many vertebrate and invertebrate species depends upon obligate coevolved symbionts that reside either within their digestive tract or in special organs, allowing them to digest plant or other tissues. In the ocean, coral reefs, which form the substrate for some of the earth’s most diverse biological communities, rely upon coevolved symbioses between corals and zooanthellae and upon additional interactions between corals and algae-feeding fish, although how coevolution has shaped some of these interactions is still poorly understood. The list continues to grow.
It has taken decades for evolutionary biology to begin shifting from a restricted view of species as adapting and diversifying across environments
to a more coevolutionary view of species as inherently dependent upon other species. It will take longer still to fully integrate interspecific interactions and coevolution into our understanding of evolutionary processes. How much of adaptation is actually coadaptation with other species? How much of population structure is due directly to coevolving interactions? How much of speciation is driven by interactions with other species? To what extent are the widespread genetic polymorphisms found in many taxa maintained by co-evolution? How much has coevolution contributed to the persistence of some species across millions of years? How much of the overall organization of communities, regional biotas, continents, and oceans results directly or indirectly from the coevolutionary process?
The developing framework for coevolutionary research is allowing us to begin answering these questions. We now know that the outcomes of co-evolution between a pair or group of species can differ across the geographic ranges of the interacting species. We have moved from a view of coevolution as a stately, long-term process that molds species over eons to one in which coevolution constantly reshapes interacting species across highly dynamic landscapes.
The Geographic Mosaic as the Organizing Framework of Coevolution
The goal of coevolutionary biology should be to understand how reciprocal evolutionary change shapes interspecific interactions across continents and oceans and over time. The fundamental premise of this book is that coevolution is an inherently geographic process that results from the genetic and ecological structure of species. The overall argument draws on the conclusions of two previous books (Thompson 1982, 1994) and on the empirical data and models for coevolutionary dynamics that have appeared especially over the past decade through the work of an ever-widening community of researchers. As I hope these chapters show, we now have a science of coevolutionary biology that provides a conceptual framework, specific hypotheses that follow from that framework, and predictions that can be tested within natural populations.
The framework of coevolution is built upon four fundamental attributes of species and interspecific interactions that provide the raw materials for ongoing coevolution (chapters 2 and 3). Most species are collections of genetically differentiated populations, and most interacting species do not have identical geographic ranges. Species are phylogenetically conservative in their interactions, and that conservatism often holds interspecific relationships together for long periods of time. Most local populations specialize their interactions on only a few other species. The outcomes of these interspecific interactions differ within and among communities.
Through these attributes, interactions are simultaneously held together at the species level even as they diversify among populations. Species become locally adapted to other species (chapter 4), and they continue to evolve rapidly, thereby blurring the artificial distinctions between ecological time and evolutionary time (chapter 5). These adaptations create a small set of classes of local coevolutionary dynamics, including coevolving polymorphisms, co-evolutionary alternation, coevolutionary escalation, attenuated antagonism, coevolving complementarity, coevolutionary convergence, and coevolutionary displacement (chapter 5). The transient local coevolutionary dynamics between any two or more species often differ among populations at any moment in time. The resulting mosaic of local adaptation and coadaptation in interspecific interactions establishes the basic structure of the coevolutionary mosaic.
The mosaic constantly changes as coevolving species continually adapt, counteradapt, diverge from other populations, and occasionally undergo speciation. The geographic mosaic theory of coevolution argues that these broader dynamics—which go beyond local coevolution—have three components (chapter 6):
• Geographic selection mosaics. Natural selection on interspecific interactions varies among populations partly because there are geographic differences in how fitness in one species depends upon the distribution of genotypes in another species. That is, there is often a genotype-by-genotype-by-environment interaction in fitnesses of interacting species.
• Coevolutionary hotspots. Interactions are subject to reciprocal selection only within some local communities. These coevolutionary hotspots are embedded in a broader matrix of coevolutionary coldspots, where local selection is nonreciprocal.
• Trait remixing. The genetic structure of coevolving species also changes through new mutations, gene flow across landscapes, random genetic drift, and extinction of local populations. These processes contribute to the shifting geographic mosaic of coevolution by continually altering the spatial distributions of potentially coevolving alleles and traits.
Through this tripartite process, coevolution produces identifiable ecological and evolutionary dynamics across landscapes (chapter 6). Populations differ in the traits shaped by an interaction. Coevolved traits are well matched between species in some communities but sometimes mismatched in others. Most locally coevolved traits do not scale up to produce long-term directional change in the traits of interacting species. Traits shaped by coevolving interactions ratchet in particular directions and become fixed in a species only through occasional selective sweeps across all populations of interacting species or through diversifying coevolution that creates new species (chapter 7). Most of the time, coevolution moves species around in genetic and ecological space without any sustained direction. These ongoing dynamics provide us ways of analyzing coevolution by using eleven forms of evidence and drawing on approaches from multiple subdisciplines (chapter 8).
The various classes of local coevolutionary dynamics fit within the broader geographic mosaic of coevolution, and part 2 develops specific hypotheses with predictions for further research (chapters 9–15). How the geographic mosaic molds these classes depends upon the mode of interaction among species. Within antagonistic trophic interactions, predation, grazing, and parasitism have different effects on the structure of coevolutionary selection. The geographic structure of interactions can sustain coevolving polymorphisms between parasites and hosts, while generating a mix of habitats in which traits are matched or mismatched (chapter 9). Under some conditions multispecific coevolution between parasites and hosts favors optimal allelic diversification in these polymorphisms (chapter 9), and it may favor the maintenance of sexual reproduction (chapter 10). Predators and grazers, and some parasites, often actively choose among multiple victim species, creating mosaics of coevolving networks through geographic differences in relative preference and the process of coevolutionary alternation, sometimes coupled with escalation (chapter 11).
The continuum in forms of interaction from mutualistic symbioses to mutualism between free-living species is as fundamental to the geographic mosaic of coevolution as is the continuum from parasitism to grazing and predation. Mutualisms coevolve through a combination of complementarity of traits (e.g., nutritional requirements of hosts and mutualistic symbionts; shapes of flowers and hummingbird bills) and convergence of traits within networks (e.g., convergent floral traits among species). The importance of coevolutionary convergence as part of the process differs among the forms of mutualism. Local adaptation sometimes favors the evolution of attenuated antagonism within symbiotic interactions (chapter 12). Those interactions that create reciprocal fitness benefits coevolve through selection toward mutualistic monocultures and complementary symbionts (chapter 12), creating geographic mosaics (chapter 13). Local adaptation among free-living mutualists also favors complementarity among interacting species, but it also favors convergence of unrelated taxa. These two classes of coevolutionary dynamics contribute to predictable network structure even as species composition changes across landscapes (chapter 14).
The remaining major outcome, coevolutionary displacement, results from a geographic mosaic in the intensity and form of interaction among species that share similar resources or habitats (chapter 15). Species may become displaced in traits or habitat use through competition, either alone or combined with other forms of interaction, and guilds of species may become displaced in similar ways across landscapes. Local character displacement in a pair of species is therefore only one component of the overall geographic mosaic of coevolutionary displacement.
The developing framework for coevolutionary biology provides an increasingly solid basis for the establishment of a science of applied coevolutionary biology (chapter 16). Selective breeding and genetic modification of crops and livestock for resistance against parasites is a form of human-induced coevolution that has some similarities to natural coevolution but also many differences from it. The development of antibiotics and vaccines has created, in effect, surrogate genes and a process of surrogate coevolution that we are now trying to manage. More broadly, our worldwide modification of landscapes and transport of species over vast distances is creating interactions with geographic configurations that differ in some ways from anything most species have experienced in the past.
Confronting all these challenges requires a three-pronged approach in the development of coevolutionary biology. We must continue to refine our understanding of the geographic mosaic of coevolution across a broad range of landscapes and forms of interaction. We must understand the differences between natural coevolution and processes such as surrogate coevolution. And we must use more effectively the precious and free research and development that exists in the earth’s remaining wilderness areas. No amount of money can ever replace the valuable information about the structure and dynamics of coevolution contained within long-coevolved interactions. The geographic mosaic of coevolution across wilderness landscapes is our touchstone for understanding the dynamics we are trying to manipulate across most of the earth’s landscapes. Through these combined approaches, coevolutionary biology should become one of the most important sciences for helping us maintain the long-term health of our societies and the world that we now increasingly manage.
2
Raw Materials for Coevolution I
Populations, Species, and Lineages
The central problem of coevolution is to understand how interactions between species are shaped by reciprocal natural selection and persist across space and time even as they undergo constant and often rapid coevolutionary change. In an idealized interaction, one population of one species co-evolves with one population of another species within a single local environment. Under intense reciprocal selection, the interaction coevolves either to a state of equilibrium or to local extinction of one of the species. Coevolution in real species, however, involves multiple interconnected populations, distributed across complex environments subject to ongoing major physical events such as El Niño and North Atlantic oscillations, ice ages, periods of global warming, and erratic volcanism that can change worldwide weather patterns for years on end. As environments change, so do the geographic ranges of species, bringing different populations of coevolving species into contact while shifting other populations outside the range of the interaction.
The resulting coevolutionary changes continue to reshape interactions over years, decades, and centuries. Somehow, in the midst of all this constant coevolutionary change, some interactions persist for millions of years. As these coevolving species diversify, they in turn create descendant lineages that interact in a similar way. Any realistic scientific framework for the coevolutionary process must therefore confront the temporal, geographic, and phylogenetic structure of species and interactions. It must explain the process by which short-term coevolutionary change and long-term persistence are interrelated.
The raw materials both for short-term and long-term coevolution consist of four fundamental attributes of the biology of species (Thompson 1999d), which are explored in this chapter and the next.
• Most species are collections of genetically differentiated populations, and most interacting species do not have identical geographic ranges.
• Species are phylogenetically conservative in their interactions, and that conservatism often holds interspecific relationships together for long periods of time.
• Most local populations specialize their interactions on a few other species.
• The ecological outcomes of these interspecific interactions differ within and among communities.
The first two attributes emphasize the malleable yet conservative structure of species and are explored in this chapter. The second two attributes emphasize the dynamic yet bounded ecological structure of interspecific interactions and are developed in the next chapter. Together, these components of interspecific interactions create a template upon which natural selection both drives and constrains coevolving relationships among species across multiple temporal and spatial scales. In effect, these components create the conditions that shape short-term coevolutionary dynamics and make long-term coevolution possible.
Most Species are Collections of Genetically Differentiated Populations, and Most Interacting Species Do Not Have Identical Geographic Ranges
The single clearest result from the past thirty years of research in population biology and molecular ecology is that most species are collections of populations that differ genetically from each other. Populations differ at the molecular level at DNA positions that are selectively neutral and at positions under strong selection. They differ at the phenotypic level in traits that shape their adaptations to the physical environment and their interactions with other species. Through a combination of non-panmictic breeding among populations, random genetic drift, selection on particular alleles, and geographic differences in interspecific interactions, species become collections of small evolutionary experiments. Over time, these experiments expand, contract, diversify, and anastomose across continents and oceans.
Within regions, populations may form metapopulations, with each local deme potentially differing in genetic and ecological structure from other demes (Hastings and Harrison 1994; Husband and Barrett 1996; Hanski 1999, 2003; Hastings 2003; Smith, Ericson, and Burdon 2003). Different configurations of metapopulations can lead to different genetic dynamics over time through differences in patterns of gene flow and the dynamics of extinction and recolonization (Hanski and Gilpin 1997). Similarly, different spatial structures can lead to different patterns of population dynamics (Murdoch, Briggs, and Nisbet 2003), which can feed back on the genetic dynamics by altering the temporal patterns of extinction, recolonization, random genetic drift, and natural selection. The regional structure of most species is therefore likely to be in constant genetic flux.
Over larger geographic areas, more stable genetic differences among populations create lineages of populations that have provided the basis for the development of the field of phylogeography (Avise 1994, 2000). Even some species known for long-distance migrations show geographic structure, because individuals within these species often return to their natal areas to breed (Dingle 1996). Together, local metapopulation dynamics and the broader geographic structure of most species guarantee that spatial structure will influence the coevolutionary dynamics of almost all interspecific interactions.
MOLECULAR DIFFERENTIATION
As data on DNA sequences and polymorphisms continue to accumulate for more taxa, the evidence is pointing toward more rather than less genetic differentiation among populations than we previously suspected for many species. The extreme of true panmixis throughout the range of any moderately wide-ranging species seems increasingly unlikely. Even panmixis over moderately large subregions of species seems uncommon for many taxa.
Populations can come to differ from one another simply because they are finite in size and individuals do not have equal likelihood of mating with one another among the populations. Until recently, the most commonly used measures of population-genetic differentiation were those that use, directly or indirectly, the variance in allele frequencies among populations, such as Wright’s F-statistic FST (Wright 1951, 1965) or Nei’s GST. (Nei 1973). FST measures the relative proportion of total genetic variation that is found among populations rather than within populations. It is essentially a measure of average population-genetic differentiation and provides no information of the spatial configuration of that differentiation (Rogers 1988; Epperson 2003). Nevertheless, calculation of FST has often provided a simple index of whether populations show some degree of differentiation across the spatial scale of a particular group of populations under study. Major reviews of population subdivision in plants and animals using these measures have usually shown some degree of subdivision in most species (Hamrick and Godt 1990; Bohonak 1999). Sometimes substantial subdivision may occur at scales of a few kilometers or less, whereas in other species substantial gene flow occurs over large scales. This overall lack of panmictic structure in many species creates part of the raw material for the geographic mosaic of coevolution. We are only starting to understand, however, how the scale of population subdivision indexed by these measures affects coevolutionary dynamics within regions.
At larger spatial scales, many molecular studies of terrestrial and freshwater taxa show evidence of substantial subdivision of populations, creating breaks among faunistic or floristic regions. For example, comparative phylogeographic studies of fish species in the southeastern United States have shown major molecular differences between populations in rivers draining into the Atlantic Ocean and those in rivers draining into the Gulf of Mexico. This pattern holds for spotted sunfish (Lepomis punctatus), three other sunfish species (Lepomis spp.), mosquito fish (Gambusia spp.), largemouth bass (Micropterus salmoides), and bowfin (Amia calva) (Bermingham and Avise 1986; Walker and Avise 1998) (fig. 2.1).
Similar studies in Europe have identified three broad patterns in post-Pleistocene recolonization from southern European refugia (Hewitt 2001) (fig. 2.2). For taxa such as meadow grasshoppers and alders, the Pyrenees and the Alps were major barriers, and much of Europe was recolonized from the Balkans. Other taxa, such as hedgehogs and oak species, are parapatric along a north–south line through Europe, suggesting recolonization from multiple refugia to the west and east. For brown bears and shrews, the Pyrenees seem to have been less of a barrier than the Alps, and much of central Europe was colonized by populations from the Iberian peninsula and the Caucasus.
Analyses of comparative phylogeographic structure are now appearing for an increasingly wide range of taxa and regions (Soltis et al. 1997; Bernatchez and Wilson 1998; Moritz and Faith 1998; Althoff and Thompson 1999; Ditchfield 2000; Stuart-Fox et al. 2001; Brunsfeld et al. 2002; Calsbeek, Thompson, and Richardson 2003). These studies are making it possible to compile composite phylogeographic analyses of entire ecoregions. The current conclusions, however, are best viewed as working hypotheses, requiring much infill of species and populations. For example, as recently as 2002 only fifty-five species or species complexes were available for a comparative phylogeographic analysis of California animals and plants, when the analysis was restricted to species studied in multiple populations within California using molecular markers or DNA sequences (Calsbeek, Thompson, and Richardson 2003). That analysis showed several major molecular breaks within the California Floristic Province common to multiple animal taxa (e.g., the transverse range of southwestern California) but less evident structure among plant species. Molecular-clock analyses of the animal species suggest major patterns of genetic differentiation (i.e., deep phylogeographic splits) starting around five to seven million years ago, with additional splits during the Pleistocene (fig. 2.3).
Fig. 2.1 Major river drainages of the southeastern United States, the patterns of faunal similarity among fish taxa across the region, and the pattern of mitochondrial DNA differentiation in one species, the spotted sunfish (Lepomis punctatus). After Walker and Avise 1998.
Some neighboring large regions show very different patterns of molecular differentiation. In both Europe and the North American Pacific Northwest, northern populations of some species show relatively little regional differentiation in DNA sequence and molecular markers compared with more southern populations that were less affected by Pleistocene ice sheets (Brown et al. 1997; Soltis and Soltis 1999; Avise 2000; Hewitt 2001; Calsbeek, Thompson, and Richardson 2003). In many cases these northern populations have resulted from rapid post-Pleistocene expansion, which has allowed little time for molecular differentiation at neutral DNA positions.
For example, the moth Greya politella has relatively few mitochondrial DNA haplotypes in Idaho, Washington, and Oregon relative to populations in California (fig. 2.4). All the northern populations so far tested for cytochrome oxidase I and II share the same one or two haplotypes. The southern Oregon populations are genetically very similar to those found farther north, differing only by a few base substitutions. In contrast, Californian populations show greater regional differentiation in cytochrome oxidase haplotypes, even though only parts of that region have been sampled (Brown et al. 1997). Similar patterns of shallow molecular differentiation at neutral markers in the Pacific Northwest have been found in the few other insect, plant, and vertebrate species that have been studied across the same habitats (e.g., Althoff and Thompson 1999; Segraves et al. 1999; Soltis et al. 1997; Nielson, Lohman, and Sullivan 2001; Janzen et al. 2002; Good et al. 2003; Thompson and Calsbeek 2004).
Fig. 2.2 Patterns of post-Pleistocene expansion of species into northern Europe based upon phylogeographic analyses. After Hewitt 2001.
Fig. 2.3 Examples of geographic patterns in molecular differentiation in four taxa within California: (A) rubber boas, Charina bottae; (B) intertidal copepods, Tigriopus californicus; (C) the prodoxid moth Greya politella; and (D) mountain yellow-legged frogs, Rana muscosa. Arrows indicate nodes corresponding to major geographic boundaries within California. After Calsbeek, Thompson, and Richardson 2003.
Fig. 2.4 Molecular differentiation in cytochrome oxidase I and II among populations of the moth Greya politella in the western United States. Populations in the Pacific Northwest (Washington, Idaho, and Oregon) show less molecular differentiation among populations (haplotypes W1–2) than populations in California (haplotypes C1–7). Haplotypes are more closely related within regions than between regions (i.e., W1–2 group together, and C1–7 group together). After Brown et al. 1997.
There are still too few studies of marine taxa to make any general conclusions about geographic patterns of differentiation in marine environments as compared with terrestrial and freshwater environments. Some intertidal species show strong phylogeographic structure (Burton 1998), but until recently marine species were considered to be fundamentally different from most terrestrial organisms, because many marine species have pelagic larvae that drift in ocean currents for extended periods of time. Panmixis over large regions does, in fact, seem to occur in some species such as plaice (Pleuronectes platessa) and turbot (Scophthalmus maximus) (Hoarau et al. 2002), but examples of restricted gene flow are accumulating for species in all the major oceans (Palumbi 1994; Terry, Bucciarelli, and Bernardi, 2000). In some cases, the molecular differentiation is between major regions, such as occurs in crown-of-thorns starfish (Acanthaster planci) populations between the Indian and Pacific oceans (Benzie 1999). Other species, such as the widespread scleractinian coral Plesiastrea versipora, show molecular evidence of geographic structure in some regions of the Pacific Ocean but not in others (Rodriguez-Lanetty and Hoegh-Guldberg 2002). Still others, such as Atlantic cod (Gadus morhua), show differentiation within regions. Analysis of natural selection on the pantophysin locus in cod has suggested that coastal and arctic populations have undergone recent diversifying selection (Pogson 2003).
Some oceanic species or species complexes showing restricted regional gene flow are associated with island habitats (Taylor and Hellberg 2003), which may favor reduced pelagic larval periods and restricted gene flow into the open ocean. Yet other species such as superb blackfish (Embiotoca jacksoni) and the predatory snail Nucella caniliculata lack pelagic stages (Bernardi 2000; Sanford et al. 2003). Superb blackfish is subdivided into groups of populations along the California and Baja California coasts, showing major breaks north and south of the Big Sur/Monterey Bay region, near Santa Monica in southern California, and near Punta Eugenia in Baja California (fig. 2.5). Populations on the northern Channel Islands also differ in their haplotypes from those on the southern Channel Islands (fig. 2.5). Similarly, Nucella caniliculata shows genetic differences among populations along the west coast of North America, although less pronounced and at larger geographic scales (Sanford et al. 2003). The populations show significant isolation by distance between California and the Pacific Northwest.
Overall, marine taxa show a wide range of geographic scales at which populations are genetically differentiated. Even studies of phytoplankton are showing more population differentiation or cryptic speciation than previously suspected (Goetze 2003). As with terrestrial and freshwater species, there is therefore a potential for marine species and species complexes to differ geographically in coevolution with other species. If it turns out, however, that geographic patterns of population differentiation differ fundamentally in terrestrial and marine environments, those results will be crucial for our understanding of how the coevolutionary process has shaped the earth’s biodiversity in different major environments.
MOLECULAR DIFFERENTIATION COMPARED WITH PHENOTYPIC DIFFERENTIATION
Even with high levels of gene flow among populations, regional genetic differentiation may still be possible, if natural selection is stronger than the effects of gene flow. Consequently, estimates of gene flow and population subdivision using molecular markers alone are insufficient as a template for understanding the geographic mosaic of coevolution. In fact, our current estimates of molecular differentiation among populations often do not match patterns of phenotypic differentiation. At one extreme, microsatellite analyses may show so much fine-scale molecular diversity that they swamp the spatial scale of local adaptation. At the other extreme, DNA sequences of several genes and genome-wide analyses of restriction fragment length polymorphisms (RFLPs) or amplified fragment length polymorphisms (AFLPs) often underestimate the more fine-scaled geographic structure of species that can result from regional differences in natural selection acting on populations. Low levels of molecular regional differentiation sometimes found in these studies do not automatically suggest a lack of differentiation in traits under selection across the geographic range of a species. In fact, there is now strong evidence of differentiation across landscapes in phenotypic traits of some species that show little molecular differentiation across the same regions. For example, color patterns differ among butterfly fish in the Pacific Ocean despite the high levels of gene flow indicated by studies of allozymes and mitochondrial DNA (McMillan, Weigt, and Palumbi 1999).
Fig. 2.5 Molecular differentiation at the mitochondrial control region among populations of the black surfperch, Embiotoca jacksoni, among the Channel Islands off California. The top panel shows the position of sampling sites off the Channel Islands. The bottom panel shows the phylogeographic structure of Channel Island populations. Each circle is a sample. The northern populations (black circles) are significantly differentiated from the southern populations (white circles). From Bernardi 2000.
This is where studies of phylogeography and evolutionary ecology meet, showing the need for caution in both kinds of analysis. The patterns found in most molecular data show the combined history of gene flow, mutation, and random genetic drift in neutral genes, and those processes alone can create geographic structure given enough time (Charlesworth, Charlesworth, and Barton 2003). In some regions, such as the North American Pacific Northwest, there has been little time for neutral molecular differentiation among populations of many species. Populations are now living in regions that were under ice less than eighteen thousand years ago. Phylogeographic data therefore provide important information on the large-scale geographic breaks among