DOCSLIB.ORG

Biology 3 Origin and Diversity of Life

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Biology 3 Origin and Diversity of Life Biology 3 Origin and Diversity of Life Dr. Terence Lee What is Life? Virus? Ice Crystal? 1 What is necessary for Life? CONDITIONS ON EARTH AT THE TIME LIFE BEGAN The early atmosphere differed from that of today, and contained large amounts of carbon dioxide, nitrogen, methane, ammonia, hydrogen, and hydrogen sulfide. Small organic molecules eventually formed, providing the building blocks of life. THE UREY-MILLER EXPERIMENT In 1953, Stanley Miller and Harold Urey developed a simple four- step experiment that demonstrated how complex organic molecules could have arisen in earth’s early environment. 2 THE UREY-MILLER EXPERIMENT 1 They created a model of the chemicals present in the "warm little pond" and atmosphere early in earth's history: H 2, CH 4 (methane), and NH 3 (ammonia). 2 The atmosphere was subjected to sparks, to simulate lightning. 3 The atmosphere was cooled so that any compounds in it would rain back down into the water. 4 They examined the water, looking for organic molecules. Electrical charge 2 1 3 Cool 4 Heat Within a matter of days they discovered many organic molecules (including five different amino acids) in their primordial sea. RNA World Hypothesis • The world may have been filled with RNA- based life… 3 Why are cell membranes important? • Allow for higher concentrations of chemicals inside the cell relative to the outside. WHAT MAKES A SPECIES? SPECIES ARE • populations of organisms that interbreed with each other, • or could possibly breed, under natural conditions, • and are reproductively isolated from other such groups. Reproductive Isolation • Hybrids are bad. 4 Reproductive Isolation • Two ways to prevent hybrids: 1. Prezygotic isolating mechanisms 2. Postzygotic isolating mechanisms Conrad Lorenz • Prezygotic isolating mechanisms REPRODUCTIVE ISOLATION: KEEPING SPECIES SEPARATE PREZYGOTIC BARRIERS • Individuals are physically unable to mate with each other. OR • If individuals are able to mate, the male’s reproductive cell is unable to fertilize the female’s reproductive cell. 5 • Postzygotic isolating mechanisms - REPRODUCTIVE ISOLATION: KEEPING SPECIES SEPARATE POSTZYGOTIC BARRIERS • Matings produce hybrid individuals that do not survive long after fertilization. OR • If hybrid offspring survive, they are infertile or have reduced fertility. How do we name species? • Every species has a two part name. 1. Genus 2. specific epithet (species) • Example: Homo sapiens (Genus species ) – The first letter of the Genus is always capitalized . 6 THE ORGANIZATION OF LIFE DOMAIN Bacteria Archaea Eukarya KINGDOM Protists Plants Fungi Animals PHYLUM Chordata CLASS Mammalia ORDER Artiodactyla FAMILY Giraffidae GENUS Giraffa SPECIES Giraffa camelopardalis Memorizing Scientific Classifications 1. Kingdom 1. Kings 2. Phylum 2. Play 3. Class 3. Chess 4. Order 4. On 5. Family 5. Fine 6. Genus 6. Green 7. Species 7. Squares THE BIOLOGICAL SPECIES CONCEPT DOESN’T ALWAYS WORK The biological species concept is remarkably useful when describing most plants and animals, but it doesn’t work for distinguishing all life forms. 1 CLASSIFYING ASEXUAL SPECIES Asexual reproduction does not involve interbreeding, so the concept of reproductive isolation is no longer meaningful. 2 CLASSIFYING FOSSIL SPECIES Differences in size and shape of fossil bones cannot reveal whether there was reproductive isolation between the individuals from whom the bones came. 7 THE BIOLOGICAL SPECIES CONCEPT DOESN’T ALWAYS WORK 3 DETERMINING WHEN ONE SPECIES HAS CHANGED INTO ANOTHER There is rarely a definitive moment marking the transition from one species to another. 4 CLASSIFYING RING SPECIES Two non-interbreeding populations may be connected to each other by gene flow through another population, so there is no exact point where one species stops and the other begins. 5 CLASSIFYING HYBRIDIZING SPECIES Hybridization—the interbreeding of closely related species— sometimes occurs and produces fertile offspring, suggesting that the borders between the species are not clear cut. Ring Species How do new species arise? • Speciation describes the process of one species splitting into two distinct species in two phases. 8 Speciation • Allopatric Speciation – Physical barrier divides a population in two. – Ex. Mountain range, desert, ocean, river, etc… ALLOPATRIC SPECIATION Allopatric speciation occurs when a geographic barrier causes one group of individuals in a population to be reproductively isolated from another group. 1 INITIAL POPULATION ALLOPATRIC SPECIATION 2 REPRODUCTIVE ISOLATION Suppose a river forms through the squirrels’ habitat, separating the population. Because they cannot cross the river, they are reproductively isolated. 9 ALLOPATRIC SPECIATION 3 REPRODUCTIVE ISOLATION Suppose a river forms through the squirrels’ habitat, separating the population. Because they cannot cross the river, they are reproductively isolated. Harris’s antelope White-tailed antelope ground squirrel ground squirrel ALLOPATRIC SPECIATION: GALÁPAGOS ISLAND FINCHES Large cactus finch Vampire finch Large ground finch Woodpecker finch Small tree finch Due to allopatric speciation, fourteen different species of finches have evolved in the Galápagos Islands. Only one species of finch is found on the nearest mainland. 10 Speciation • Sympatric speciation Allopatric Sympatric SYMPATRIC SPECIATION Sympatric speciation results in the reproductive isolation of populations that coexist in the same area. Two scenarios, common in plants, lead to this method of speciation. POLYPLOIDY 1 During cell division, an error occurs in which chromosomes are duplicated Parent cell but the cell does not divide. This creates a gamete with twice as many sets of chromosomes as a gamete of MEIOSIS the parent from which it came. Gametes 2 A gamete with two sets of chromosomes cannot produce offspring by fertilizing a gamete with one set of chromosomes. Gamete Gamete 3 A gamete with two sets of chromosomes can, however, produce offspring by fertilizing another gamete with two sets of chromosomes, Gamete Gamete producing an individual with four sets of chromosomes. FERTILIZATION The new individual has achieved instant reproductive isolation from the original population and, therefore, is considered a new species. New individual SYMPATRIC SPECIATION Sympatric speciation results in the reproductive isolation of populations that coexist in the same area. Two scenarios, common in plants, lead to this method of speciation. ALLOPOLYPLOIDY 1 Two plants from different but closely related species interbreed, forming a hybrid. Species 1 Species 2 FERTILIZATION 2 The hybrid may no longer be able to interbreed with either of the parental species. Species 1 Species 2 Hybrid ASEXUAL REPRODUCTION 3 The hybrid may, however, be able to propagate itself asexually—as many plants can. The hybrid individual has achieved reproductive isolation Hybrid from the original parental populations and, therefore, is considered a new species. 11 Micro vs. Macro Evolution • Micro = slight changes in allele frequencies over one or a few generations • Macro = EVOLUTION: MICRO vs. MACRO Evolution is one thing only: a change in allele frequencies within a population. But over time, these changes can lead to new species and groups of species that vary tremendously. MACROEVOLUTION The accumulated effect of microevolution over a long period of time Time MICROEVOLUTION A slight change in allele frequencies over one or a few generations Rate of Evolution • Not constant over time 12 Rates of Evolution • Gradualism Rates of Evolution • Punctuated Equilibrium – evolution occurs in jumps and spurts 13 THE TEMPO OF EVOLUTION The pace of evolution varies for different species. Some species have evolved gradually over time, while others spend vast amounts of time with little change. GRADUAL CHANGE Evolution by creeps: The pace of evolution occurs gradually in incremental steps. Time PUNCTUATED EQUILIBRIUM Evolution by jerks: Rapid periods of evolutionary change are punctuated by longer periods with little change. Time Even though this period of rapid evolutionary change may only cover 1% of the species’ evolutionary history, it still may cover hundreds or thousands of generations. This could take tens of thousands of years in a primate or a matter of months in bacteria. 14.
Load more

Recommended publications
  • Sympatric Speciation: Models and Empirical Evidence
    ANRV328-ES38-19 ARI 24 September 2007 7:20 Sympatric Speciation: Models and Empirical Evidence Daniel I. Bolnick1 and Benjamin M. Fitzpatrick2 1Section of Integrative Biology, University of Texas, Austin, Texas 78712; email: [email protected] 2Department of Ecology and Evolutionary Biology, University of Tennessee, Knoxville, Tennessee 37996; email: benfi[email protected] Annu. Rev. Ecol. Evol. Syst. 2007. 38:459–87 Key Words First published online as a Review in Advance on assortative mating, disruptive selection, reinforcement August 8, 2007 reproductive isolation The Annual Review of Ecology, Evolution, and Systematics is online at Abstract http://ecolsys.annualreviews.org Sympatric speciation, the evolution of reproductive isolation with- This article’s doi: 10.1146/annurev.ecolsys.38.091206.095804 out geographic barriers, remains highly contentious. As a result of new empirical examples and theory, it is now generally accepted that Copyright c 2007 by Annual Reviews. All rights reserved sympatric speciation has occurred in at least a few instances, and is theoretically plausible. Instead, debate has shifted to whether sym- by Rutgers University Libraries on 09/21/09. For personal use only. 1543-592X/07/1201-0459$20.00 patric speciation is common, and whether models’ assumptions are generally met in nature. The relative frequency of sympatric spe- ciation will be difficult to resolve, because biogeographic changes have obscured geographical patterns underlying many past specia- Annu. Rev. Ecol. Evol. Syst. 2007.38:459-487. Downloaded from arjournals.annualreviews.org tion events. In contrast, progress is being made on evaluating the empirical validity of key theoretical conditions for sympatric spe- ciation. Disruptive selection and direct selection on mating traits, which should facilitate sympatric speciation, are biologically well supported.
    [Show full text]
  • Microevolution and the Genetics of Populations ​ ​ Microevolution Refers to Varieties Within a Given Type
    Chapter 8: Evolution Lesson 8.3: Microevolution and the Genetics of Populations ​ ​ Microevolution refers to varieties within a given type. Change happens within a group, but the descendant is clearly of the same type as the ancestor. This might better be called variation, or adaptation, but the changes are "horizontal" in effect, not "vertical." Such changes might be accomplished by "natural selection," in which a trait ​ ​ ​ ​ within the present variety is selected as the best for a given set of conditions, or accomplished by "artificial selection," such as when dog breeders produce a new breed of dog. Lesson Objectives ● Distinguish what is microevolution and how it affects changes in populations. ● Define gene pool, and explain how to calculate allele frequencies. ● State the Hardy-Weinberg theorem ● Identify the five forces of evolution. Vocabulary ● adaptive radiation ● gene pool ● migration ● allele frequency ● genetic drift ● mutation ● artificial selection ● Hardy-Weinberg theorem ● natural selection ● directional selection ● macroevolution ● population genetics ● disruptive selection ● microevolution ● stabilizing selection ● gene flow Introduction Darwin knew that heritable variations are needed for evolution to occur. However, he knew nothing about Mendel’s laws of genetics. Mendel’s laws were rediscovered in the early 1900s. Only then could scientists fully understand the process of evolution. Microevolution is how individual traits within a population change over time. In order for a population to change, some things must be assumed to be true. In other words, there must be some sort of process happening that causes microevolution. The five ways alleles within a population change over time are natural selection, migration (gene flow), mating, mutations, or genetic drift.
    [Show full text]
  • Genetic Structure and Eco-Geographical Differentiation of Lancea Tibetica in the Qinghai-Tibetan Plateau
    G C A T T A C G G C A T genes Article Genetic Structure and Eco-Geographical Differentiation of Lancea tibetica in the Qinghai-Tibetan Plateau Xiaofeng Chi 1,2 , Faqi Zhang 1,2,* , Qingbo Gao 1,2, Rui Xing 1,2 and Shilong Chen 1,2,* 1 Key Laboratory of Adaptation and Evolution of Plateau Biota, Northwest Institute of Plateau Biology, Chinese Academy of Sciences, Xining 810001, China; [email protected] (X.C.); [email protected] (Q.G.); [email protected] (R.X.) 2 Qinghai Provincial Key Laboratory of Crop Molecular Breeding, Xining 810001, China * Correspondence: [email protected] (F.Z.); [email protected] (S.C.) Received: 14 December 2018; Accepted: 24 January 2019; Published: 29 January 2019 Abstract: The uplift of the Qinghai-Tibetan Plateau (QTP) had a profound impact on the plant speciation rate and genetic diversity. High genetic diversity ensures that species can survive and adapt in the face of geographical and environmental changes. The Tanggula Mountains, located in the central of the QTP, have unique geographical significance. The aim of this study was to investigate the effect of the Tanggula Mountains as a geographical barrier on plant genetic diversity and structure by using Lancea tibetica. A total of 456 individuals from 31 populations were analyzed using eight pairs of microsatellite makers. The total number of alleles was 55 and the number per locus ranged from 3 to 11 with an average of 6.875. The polymorphism information content (PIC) values ranged from 0.2693 to 0.7761 with an average of 0.4378 indicating that the eight microsatellite makers were efficient for distinguishing genotypes.
    [Show full text]
  • Allopatric Speciation with Little Niche Divergence Is Common Among
    Journal of Biogeography (J. Biogeogr.) (2016) 43, 591–602 ORIGINAL Allopatric speciation with little niche ARTICLE divergence is common among alpine Primulaceae Florian C. Boucher1*, Niklaus E. Zimmermann2,3 and Elena Conti1 1Institute of Systematic Botany, University of ABSTRACT Zurich,€ 8008 Zurich,€ Switzerland, 2Dynamic Aim Despite the accumulation of cases describing fast radiations of alpine Macroecology, Swiss Federal Research plants, we still have limited understanding of the drivers of speciation in alpine Institute WSL, 8903 Birmensdorf, Switzerland, 3Department of Environmental floras and of the precise the timing of their diversification. Here, we investi- Systems Science, Swiss Federal Institute of gated spatial and temporal patterns of speciation in three groups of alpine Technology ETH, CH-8092 Zurich,€ Primulaceae. Switzerland Location Mountains of the European Alpine System. Methods We built a new phylogeny of Primulaceae including all species in three focal groups: Androsace sect. Aretia, Primula sect. Auricula and Soldanella. Combining phylogenetic information with a detailed climatic data set, we investigated patterns of range and ecological overlap between sister-species using an approach that takes phylogenetic uncertainty into account. Finally, we investigated temporal trajectories of diversification in the three focal groups. Results We found that a large majority of sister-species pairs in the three groups are strictly allopatric and show little differences in substrate and cli- matic preferences, a result that was robust to phylogenetic uncertainty. While rates of diversification have remained constant in Soldanella, both Androsace sect. Aretia and Primula sect. Auricula showed decreased diversification rates in the Pleistocene compared to previous geological epochs. Main conclusions Allopatric speciation with little niche divergence appears to have been by far the most common mode of speciation across the three groups studied.
    [Show full text]
  • Species Change Over Time
    KEY CONCEPT Species change over time. BEFORE, you learned NOW, you will learn • Fossils are evidence of earlier • About early ideas and observa- life tions on evolution • More complex organisms have • How Darwin developed his developed over time theory of natural selection • Mass extinctions contributed to • How new species arise from the development of Earth’s older species history VOCABULARY THINK ABOUT evolution p. 797 How have telephones changed over time? natural selection p. 801 adaptation p. 802 Today people across the world can speciation p. 804 communicate in many different ways. One of the most common ways is over the telephone. Looking at the two pictures, can you describe how this form of communication has changed over time? Scientists explore the concept of evolution. MAIN IDEA AND DETAILS In a general sense, evolution involves a change over time. You could Make a chart for the main say that the way humans communicate has evolved. Certainly idea scientists explore the concept of evolution. telephones have changed over time. The first telephones were the size Include details about scien- of a shoebox. Today a telephone can fit in the palm of your hand and tists’ observations. can send images as well as sound. In biology,evolution refers to the process though which species change over time. The change results from a change in the genetic material of an organism and is passed from one generation to the next. Check Your Reading What is evolution? Chapter 23: History of Life 797 Early Ideas reading tip In the early 1800s, a French scientist named Jean Baptiste de Lamarck The word acquire comes was the first scientist to propose a model of how life evolves.
    [Show full text]
  • Speciation in Geographical Setting
    Speciation Speciation 2019 2019 The degree of reproductive isolation Substantial variation exists in among geographical sets of species - anagenesis populations within an actively 1859 1859 evolving species complex is often Achillea - yarrow tested by crossing experiments — as in the tidy tips of California 100K bp 100K bp back in time back in time back Rubus parviforus K = 4 mean population assignment 2 mya 2 mya ID CO WI_Door 5 mya BC_Hixton BC_MtRob WI_BruleS 5 mya BC_McLeod CA_Klamath MI_Windigo WA_Cascade WA_BridgeCr SD_BlackHills OR_Willamette MI_Drummond Speciation Speciation 2019 Reproductive isolation will ultimately stop all Although simple in concept, the recognition of species and thus the definition genetic connections among sets of populations of what are species have been controversial — more than likely due to the – cladogenesis or speciation continuum nature of the pattern resulting from the process of speciation 1859 Example: mechanical isolation via floral shape changes and pollinators between two parapatric species of California Salvia (sage) 100K bp back in time back 2 mya S. mellifera 5 mya Salvia apiana 1 Speciation Speciation Although simple in concept, the recognition of species and thus the definition Animal examples of speciation often show of what are species have been controversial — more than likely due to the clear reproductive barriers - hence zoologists continuum nature of the pattern resulting from the process of speciation preference (as opposed to botanists) for the Reproductive isolating Biological
    [Show full text]
  • Sympatric Speciation in Ants
    When houseguests become parasites: Sympatric speciation in ants Stewart H. Berlocher* Department of Entomology, University of Illinois at Urbana–Champaign, 320 Morrill Hall, 505 South Goodwin Avenue, Urbana, IL 61801 pecies are part of the common related species, and we are finally, if still argue that sympatric speciation was not coinage of biology. Taxonomists dimly, seeing some of the specific genes limited to a handful of special cases, but name them, developmental biolo- that underlie reproductive isolation (3). was quite common. Bush was driven to gists deconstruct them, physiolo- But fundamental questions remain his stance by the observation that one S unanswered. A critical question is how gists compare them, ecologists count could find many groups of closely re- them, conservation biologists conserve reproductive isolation could evolve in lated, sympatric species that use differ- them, and evolutionary biologists study the face of gene flow; random mating ent ecological niches. Conspicuous their multiplication and extinction. It within a population and gene flow be- among these groups are parasites of ani- may be that only the individual is a tween neighboring populations are enor- mals and plants, which are often highly more important biological unit than the mously powerful homogenizing forces. specialized ecologically and frequently species. It is thus no surprise that Dar- How could selection tear a single popu- mate on the host, a factor that poten- win named his great work On the Origin lation into two reproductively isolated tially links any adaptation to a new host of Species, nor is it a surprise that many with a reduction in gene flow between evolutionary biologists today concen- the new and ancestral populations.
    [Show full text]
  • Speciation and Recessive Mutations for BMC Biology
    Essay: On the close relationship between speciation, inbreeding and recessive mutations. Etienne Joly, [email protected], Toulouse, September 2010 All the ideas developed in this essay are relatively simple, and most of them are related to many Foreword previously published works. So much work, however, This past year, 2009, was the Darwin year, celebrating has already been published on evolution and speciation the 200th anniversary of Charles Darwin's birth, and 150 that an autodidactic newcomer such as myself could years since the publication of his fabulous milestone not hope to read, let alone understand and remember all book, ‘The Origin of Species’ (to which I will the primary papers published previously on evolution subsequently refer to as ‘The Origin’). At the start of and speciation. If I have failed to acknowledge 2009, I was inhabited by a nagging ethical concern : how previous works developing ideas related to those put would humans deal with a situation where a group of forward here, the reader can be assured that this was individuals found themselves fertile among one another, not done maliciously but simply as a result of my but with limited fertility with the rest of the human race ? relative naivety on the subject. I do, however, hold the In other words, could speciation occur within the human firm conviction that, if some of the ideas developed in race ? This concern sprouted from the idea that this essay prove to be correct and relatively novel, it chromosomal rearrangements seemed to me like a very was only possible because of this naivety.
    [Show full text]
  • Allopatric Speciation
    Lecture 21 Speciation “These facts seemed to me to throw some light on the origin of species — that mystery of mysteries”. C. Darwin – The Origin What is speciation? • in Darwin’s words, speciation is the “multiplication of species”. What is speciation? • in Darwin’s words, speciation is the “multiplication of species”. • according to the BSC, speciation occurs when populations evolve reproductive isolating mechanisms. What is speciation? • in Darwin’s words, speciation is the “multiplication of species”. • according to the BSC, speciation occurs when populations evolve reproductive isolating mechanisms. • these barriers may act to prevent fertilization – this is prezygotic isolation. What is speciation? • in Darwin’s words, speciation is the “multiplication of species”. • according to the BSC, speciation occurs when populations evolve reproductive isolating mechanisms. • these barriers may act to prevent fertilization – this is prezygotic isolation. • may involve changes in location or timing of breeding, or courtship. What is speciation? • in Darwin’s words, speciation is the “multiplication of species”. • according to the BSC, speciation occurs when populations evolve reproductive isolating mechanisms. • these barriers may act to prevent fertilization – this is prezygotic isolation. • may involve changes in location or timing of breeding, or courtship. • barriers also occur if hybrids are inviable or sterile – this is postzygotic isolation. Modes of Speciation Modes of Speciation 1. Allopatric speciation 2. Peripatric speciation 3. Parapatric speciation 4. Sympatric speciation Modes of Speciation 1. Allopatric speciation 2. Peripatric speciation 3. Parapatric speciation 4. Sympatric speciation Modes of Speciation 1. Allopatric speciation Allopatric Speciation ‘‘The phenomenon of disjunction, or complete geographic isolation, is of considerable interest because it is almost universally believed to be a fundamental requirement for speciation.’’ Endler (1977) Modes of Speciation 1.
    [Show full text]
  • How Important Are Structural Variants for Speciation?
    G C A T T A C G G C A T genes Review How Important Are Structural Variants for Speciation? Linyi Zhang 1,*, Radka Reifová 2, Zuzana Halenková 2 and Zachariah Gompert 1 1 Department of Biology, Utah State University, Logan, UT 84322, USA; [email protected] 2 Department of Zoology, Faculty of Science, Charles University, 12800 Prague, Czech Republic; [email protected] (R.R.); [email protected] (Z.H.) * Correspondence: [email protected] Abstract: Understanding the genetic basis of reproductive isolation is a central issue in the study of speciation. Structural variants (SVs); that is, structural changes in DNA, including inversions, translocations, insertions, deletions, and duplications, are common in a broad range of organisms and have been hypothesized to play a central role in speciation. Recent advances in molecular and statistical methods have identified structural variants, especially inversions, underlying ecologically important traits; thus, suggesting these mutations contribute to adaptation. However, the contribu- tion of structural variants to reproductive isolation between species—and the underlying mechanism by which structural variants most often contribute to speciation—remain unclear. Here, we review (i) different mechanisms by which structural variants can generate or maintain reproductive isolation; (ii) patterns expected with these different mechanisms; and (iii) relevant empirical examples of each. We also summarize the available sequencing and bioinformatic methods to detect structural variants. Lastly, we suggest empirical approaches and new research directions to help obtain a more complete assessment of the role of structural variants in speciation. Citation: Zhang, L.; Reifová, R.; Keywords: reproductive isolation; hybridization; suppressed recombination Halenková, Z.; Gompert, Z.
    [Show full text]
  • A Theory of Evolution Above the Species Level (Paleontology/Paleobiology/Speciation) STEVEN M
    Proc. Nat. Acad. Sci. USA Vol. 72, No. 2, pp. 646-650, February 1975 A Theory of Evolution Above the Species Level (paleontology/paleobiology/speciation) STEVEN M. STANLEY Department of Earth and Planetary Sciences, The Johns Hopkins University, Baltimore, Maryland 21218 Communicated by Hanm P. Eugster, December 11, 1974 ABSTRACT Gradual evolutionary change by natural lished species are seen as occasionally becoming separated by selection operates so slowly within established species to form new species. Most isolates become that it cannot account for the major features of evolution. geographic barriers Evolutionary change tends to be concentrated within extinct, but occasionally one succeeds in blossoming into a speciation events. The direction of transpecific evolution is new species by evolving adaptations to its marginal environ- determined by the process of species selection, which is ment and diverging to a degree that interbreeding with the analogous to natural selection but acts upon species within original population is no longer possible. Mayr has empha- higher taxa rather than upon individuals within popula- tions. Species selection operates on variation provided sized the stability of the genotype of a typical established by the largely random process of speciation and favors species. Most species occupy heterogeneous environments species that speciate at high rates or survive for long within which selection pressures differ from place to place and periods and therefore tend to leave many daughter species. oppose each other through gene flow. Furthermore, biochemi- Rates of speciation can be estimated for living taxa by cal systems interact in complex ways. Most genes affect means of the equation for exponential increase, and are clearly higher for mammals than for bivalve mollusks.
    [Show full text]
  • The Temporal Dimension of Marine Speciation
    Evol Ecol DOI 10.1007/s10682-011-9488-4 ORIGINAL PAPER The temporal dimension of marine speciation Richard D. Norris • Pincelli M. Hull Received: 2 September 2010 / Accepted: 7 May 2011 Ó Springer Science+Business Media B.V. 2011 Abstract Speciation is a process that occurs over time and, as such, can only be fully understood in an explicitly temporal context. Here we discuss three major consequences of speciation’s extended duration. First, the dynamism of environmental change indicates that nascent species may experience repeated changes in population size, genetic diversity, and geographic distribution during their evolution. The present characteristics of species therefore represents a static snapshot of a single time point in a species’ highly dynamic history, and impedes inferences about the strength of selection or the geography of spe- ciation. Second, the process of speciation is open ended—ecological divergence may evolve in the space of a few generations while the fixation of genetic differences and traits that limit outcrossing may require thousands to millions of years to occur. As a result, speciation is only fully recognized long after it occurs, and short-lived species are difficult to discern. Third, the extinction of species or of clades provides a simple, under-appre- ciated, mechanism for the genetic, biogeographic, and behavioral ‘gaps’ between extant species. Extinction also leads to the systematic underestimation of the frequency of spe- ciation and the overestimation of the duration of species formation. Hence, it is no surprise that a full understanding of speciation has been difficult to achieve. The modern synthe- sis—which united genetics, development, ecology, biogeography, and paleontology— greatly advanced the study of evolution.
    [Show full text]