An evolutionary landscape is a metaphorWright, Sewall (1932) The Roles of Mutation, Inbreeding, Crossbreeding, and Selection in Evolution. ''Proceedings of the Sixth International Congress of Genetics'' 1: 356–366 or a construct used to think about and visualize the processes of

evolution Evolution is change in the heritable characteristics of biological populations over successive generations. These characteristics are the expressions of genes, which are passed on from parent to offspring during reproduction. Variation ...

(e.g.

natural selection Natural selection is the differential survival and reproduction of individuals due to differences in phenotype. It is a key mechanism of evolution, the change in the heritable traits characteristic of a population over generations. Cha ...

and

genetic drift Genetic drift, also known as allelic drift or the Wright effect, is the change in the frequency of an existing gene variant (allele) in a population due to random chance. Genetic drift may cause gene variants to disappear completely and there ...

) acting on a biological entityWright, Sewall (1988) Surfaces of Selective Value Revisited. ''The American Naturalist'' 131(1):115-123 (e.g. a

gene In biology, the word gene (from , ; "... Wilhelm Johannsen coined the word gene to describe the Mendelian units of heredity..." meaning ''generation'' or ''birth'' or ''gender'') can have several different meanings. The Mendelian gene is a b ...

protein Proteins are large biomolecules and macromolecules that comprise one or more long chains of amino acid residues. Proteins perform a vast array of functions within organisms, including catalysing metabolic reactions, DNA replication, res ...

population Population typically refers to the number of people in a single area, whether it be a city or town, region, country, continent, or the world. Governments typically quantify the size of the resident population within their jurisdiction using a ...

, or

species In biology, a species is the basic unit of classification and a taxonomic rank of an organism, as well as a unit of biodiversity. A species is often defined as the largest group of organisms in which any two individuals of the appropriate s ...

).Lee, Carol E. & Gelebiuk, Gregory W. (2008) Evolutionary origins of invasive populations. "Evolutionary Applications" 1: 427–448. This entity can be viewed as searching or moving through a search space. For example, the search space of a gene would be all possible nucleotide sequences. The search space is only part of an evolutionary landscape. The final component is the "y-axis", which is usually fitness. Each value along the search space can result in a high or low fitness for the entity. If small movements through search space cause changes in fitness that are relatively small, then the landscape is considered smooth. Smooth landscapes happen when most fixed mutations have little to no effect on fitness, which is what one would expect with the

neutral theory of molecular evolution The neutral theory of molecular evolution holds that most evolutionary changes occur at the molecular level, and most of the variation within and between species are due to random genetic drift of mutant alleles that are selectively neutral. The ...

. In contrast, if small movements result in large changes in fitness, then the landscape is said to be rugged. In either case, movement tends to be toward areas of higher fitness, though usually not the global optima. What exactly constitutes an "evolutionary landscape" is frequently confused in the literature; the term is often used interchangeably with "adaptive landscape" and "fitness landscape", although some authors have different definitions of adaptive and fitness landscapes. Additionally, there is a large disagreement whether the concept of an evolutionary landscape should be used as a visual metaphor disconnected from the underlying math, a tool for evaluating models of evolution, or a model in and of itself used to generate hypotheses and predictions.

History

Pre-Wright

According to McCoy (1979), the first evolutionary landscape was presented by Armand Janet of Toulon, France, in 1895.McCoy J. Wynne. 1979. The Origin of the "Adaptive Landscape" Concept. The American Naturalist 113(4):610-613. In Janet's evolutionary landscape, a species is represented as a point or an area on a polydimensional surface of phenotypes, which is reduced to two dimensions for simplicity. The size of the population is proportional to the amount of variation within the population.Dietrich MR & Skipper RA. 2012 "A Shifting Terrain: A Brief History of the Adaptive Landscape." In: The Adaptive Landscape in Evolutionary Biology. eds. Erik Svensson & Ryan Calsbeek Oxford Press. Natural selection (the influence of the exterior features) is represented by a vector. Unlike the evolutionary landscapes of those who would follow, in Janet's concept, natural selection pulls species toward the minima instead of the maxima. This is because the y-axis does not represent fitness but stability. One important aspect of Janet's evolutionary landscape (versus Wright's) is that the landscape changes as the environment changes.

Wrightian landscapes

Credit for the first evolutionary landscape typically goes to

Sewall Wright Sewall Green Wright FRS(For) Honorary FRSE (December 21, 1889March 3, 1988) was an American geneticist known for his influential work on evolutionary theory and also for his work on path analysis. He was a founder of population genetics alongsi ...

, and his idea has arguably had a much larger audience and greater influence on the field of evolutionary biology than any other comparable understanding of "evolutionary landscape". In his 1932 paper, Wright presents the concept of an evolutionary landscape composed of a polydimensional array of gene (

allele An allele (, ; ; modern formation from Greek ἄλλος ''állos'', "other") is a variation of the same sequence of nucleotides at the same place on a long DNA molecule, as described in leading textbooks on genetics and evolution. ::"The chro ...

) or genotype frequencies and an axis of fitness, which served as a visual metaphor to explain his

shifting balance theory The shifting balance theory is a theory of evolution proposed in 1932 by Sewall Wright, suggesting that adaptive evolution may proceed most quickly when a population divides into subpopulations with restricted gene flow. The name of the theory i ...

. Similarly to Janet, Wright felt the landscape could be reduced to two dimensions for simplicity. (This is one of the greatest criticisms, which are discussed below.) Populations are represented by areas, with the size of the area corresponding to the amount of genetic diversity within the population. Natural selection drives populations toward maxima, while drift represents wandering and could potentially cause a peak shift. Movement across the landscape represented changes in gene frequencies. This landscape was represented as a series of contour lines, much like a topographical map; while selection kept or moved a biological entity to a peak, genetic drift allowed different peaks to be explored. In 1944, Simpson expanded Wright's landscape to include phenotypes.Simpson, GG. 1944. ''Tempo and Mode in Evolution'' Columbia University Press, New York. In Simpson's model, the landscape is a means of visualizing the "relationship between selection, structure, and adaptation." Unlike Wright, Simpson used the landscape to represent both natural selection and genetic drift. Uphill movements are due to positive selection, and downhill movements are due to negative selection. The size and shape of a peak indicated the relative specificity of selection; i.e. a sharp and high peak indicates highly specific selection. Another difference between Simpson's and Wright's landscapes is the level at which evolution is acting. For Wright, a

population geneticist Population genetics is a subfield of genetics that deals with genetic differences within and between populations, and is a part of evolutionary biology. Studies in this branch of biology examine such phenomena as adaptation, speciation, and po ...

, only populations of a species were shown. In Simpson's figures, the circles drawn represent all of Equidae. The most important difference is that in Simpson's model, the landscape could vary through time, while in Wright's model, the landscape was static. Wright reviewed Simpson's work (''Tempo and Mode in Evolution'') and did not object to Simpson's use of evolutionary landscapes. In later writings, Simpson referred to peaks as adaptive zones.Lande, R. (1976) Natural selection and random genetic drift in phenotypic evolution. Evolution 30: 314-334. In a series of papers,

Russell Lande Russell Scott Lande (born 1951) is an American evolutionary biologist and ecologist, and an International Chair Professor at Centre for Biodiversity Dynamics at the Norwegian University of Science and Technology (NTNU). He is a fellow of the Roy ...

developed a mathematical model for Simpson's phenotypic landscape.Lande, R. (1979) Effective Deme Sizes During Long-Term Evolution Estimated from Rates of Chromosomal Rearrangement. Evolution 33:234–251 Lande reconciled Wright's population-level view with Simpson's use of higher taxonomic levels. Lande considers fitness peaks to be determined by the environment and thus represent ecological niches or adaptive zones for a population. Clusters of peaks inhabited by phenotypically similar populations can be viewed as higher taxonomic levels.

Molecular era

The concept of evolutionary landscapes changed once more as the modern understanding of

molecular evolution Molecular evolution is the process of change in the sequence composition of cellular molecules such as DNA, RNA, and proteins across generations. The field of molecular evolution uses principles of evolutionary biology and population genetics ...

emerged. It is claimed that Maynard Smith (1970) was the first to visualize protein evolution as a network of proteins one mutational step away from others. However, for this to be true, there must be pathways between functional proteins. Acknowledging the work of Kimura, King, and Jukes (

the neutral theory of molecular evolution ''The Neutral Theory of Molecular Evolution'' is an influential monograph written in 1983 by Japanese evolutionary biologist Motoo Kimura. While the neutral theory of molecular evolution existed since his article in 1968, Kimura felt the need to ...

), Maynard Smith realized the proteins along such pathways could have equal functionality or be neutral. In other words, not all moves in evolution are "uphill". In 1984, Gillespie adapted the concept of evolutionary landscapes to nucleotide sequences and so visualized the "mutational landscape" whereby all nucleotide sequences are one mutational step away from another, which is remarkably similar and yet fundamentally different from Wright's original concept. This conceptual shift, along with the development of vast computational power, has allowed evolutionary landscapes to move from being a simple visual metaphor to a working model of evolution. As one might expect, this has drawn heavy criticism and generated much research.The Adaptive Landscape in Evolutionary Biology. Eds. Erik Svensson & Ryan Calsbeek. 2012 EvoLandscape1

Criticisms

One of the first criticisms (or at least difficulty) with evolutionary landscapes is their dimensionality. Wright recognized that true landscapes can have thousands of dimensions, but he also felt reducing those dimensions to two was acceptable since his point in doing so was simply to convey a complex idea. As a visual metaphor, this might be a valid reduction; however, the work of Gavrilets has shown that taking the high dimensionality of evolutionary landscapes into consideration may matter. In a high-dimensional framework, the peaks and valleys disappear and are replaced with hypervolume areas of high fitness and low fitness, which can be visualized as curved surfaces and holes in a three-dimensional landscape. While this does not affect visualization of the landscape ''per se'' (i.e. holes are equivalent to valleys), it does affect the underlying mathematical model and the predicted outcomes. File:EvoLandscape2.png, A hypothetical evolutionary landscape. The horizontal axes represent the biological parameters being measured (i.e. component of phenotype, genotype, nucleotide sequence combinations) and the vertical axis represents fitness. This particular landscape is an exaggerated example of Gavrilets' holey landscape. The work of Gavrilets, along with other issues, has prompted Kaplan (2008) to propose abandoning the metaphor of evolutionary landscapes (which he calls adaptive or fitness landscapes). Kaplan (2008) has six main criticisms of the metaphor: (1) it has no explanatory power; (2) it lacks a relevant mathematical model; (3) it has no heuristic role; (4) it is imprecise; (5) it confuses more than it explains; and (6) there is no longer a reason to keep thinking in 2D or 3D when we have the computational power to consider higher dimensionality. Others feel Kaplan's criticisms are not warranted because he (and others) want evolutionary landscapes to meet the standards of a mathematical model; however, the landscape metaphor is just that, a metaphor. It has heuristic value as a metaphorical tool allowing one to visualize and evaluate the common core of assumptions in an evolutionary model.Skipper RA & Dietrich MR. 2012 "Sewall Wright's adaptive landscape: Philosophical reflections on heuristic value." In: The Adaptive Landscape in Evolutionary Biology. eds. Erik Svensson & Ryan Calsbeek Oxford Press. While Kaplan (2008) wishes to discard the idea of landscapes all together,

Massimo Pigliucci Massimo Pigliucci (; born January 16, 1964) is Professor of Philosophy at the City College of New York, former co-host of the '' Rationally Speaking Podcast'', and former editor in chief for the online magazine ''Scientia Salon''. He is a critic o ...

is less drastic. He acknowledges four categories of landscapes: fitness landscapes, adaptive landscapes, fitness surfaces, and morphospaces. Fitness landscapes are those similar to what Wright (1932) proposed (called adaptive and fitness landscapes below). Adaptive landscapes are the phenotypic landscapes proposed by Simpson (1944), and fitness surfaces are the phenotypic landscapes with Lande's mathematical models applied to them. Morphospaces, pioneered by Raup (1966), are phenotypic landscapes developed ''a priori'' using mathematical models onto which observed measurements are mapped. They lack a fitness axis, and are used to show the occupied areas within the potential phenotypic space. Pigliucci suggests we abandon Wrightian fitness landscapes. Adaptive landscapes and fitness surfaces can be used with caution, i.e. with the understanding that they are not phenotypic versions of Wright's original concept and that they are fraught with potentially misleading assumptions. Finally, Pigliucci calls for further research into morphospaces due to their heuristic value but also their ability to generate understandable and testable hypotheses.

Types of evolutionary landscapes

Adaptive landscapes

Adaptive landscapes represent populations (of biological entities) as a single point, and the axes correspond to frequencies of

alleles An allele (, ; ; modern formation from Greek ἄλλος ''állos'', "other") is a variation of the same sequence of nucleotides at the same place on a long DNA molecule, as described in leading textbooks on genetics and evolution. ::"The chrom ...

genotypes The genotype of an organism is its complete set of genetic material. Genotype can also be used to refer to the alleles or variants an individual carries in a particular gene or genetic location. The number of alleles an individual can have in a ...

and the mean population fitness.Kaplan J. (2008) The end of the adaptive landscape metaphor? ''Bio Philos'' 23:625-638 Visualization of two dimensions of a NK fitness landscape

Visualization of two dimensions of a NK fitness landscape

Fitness landscapes

Fitness landscape Fitness may refer to: * Physical fitness, a state of health and well-being of the body * Fitness (biology), an individual's ability to propagate its genes * Fitness (cereal), a brand of breakfast cereals and granola bars * ''Fitness'' (magazine), ...

s represent populations (of biological entities) as clusters of points with each point representing a unique genotype. The axes correspond to the loci of those genotypes and the resulting mean population fitness.

Phenotypic landscapes

Phenotypic landscapes represent populations or species as clusters of points with each point representing a

phenotype In genetics, the phenotype () is the set of observable characteristics or traits of an organism. The term covers the organism's morphology or physical form and structure, its developmental processes, its biochemical and physiological pr ...

. The axes correspond to frequencies of phenotypes and the mean population fitness. See the visualizations below for examples of phenotypic landscapes. Visualization of a population evolving in a static fitness landscape

Visualization of a population evolving in a static fitness landscape

Visualization of a population evolving in a dynamic fitness landscape

Selection-weighted attraction graphing

Selection-weighted attraction graphing (SWAG) uses force-directed network graphing to visualize fitness landscapes. In this visualization, genotypes are represented by nodes which are attracted to each other in proportion to the relative change in fitness between them (nodes will tend to be closer if there is stronger selection strength between them on average). Additionally, fitness values may be assigned to the z-axis to create an empirical three-dimensional model of the landscape and depict fitness peaks and valleys. Clusters in this depiction may represent local fitness peaks.

Phenotypic plasticity landscapes

Phenotypic plasticity landscapes depart from the other landscapes in that they do not use the mean population fitness. Instead, that axis represents characters (phenotypic traits) and other axes represent the underlying factors affecting the character.

Epigenetic landscapes

Epigenetic landscapes are "used to describe modal developmental tendency and major deviations" with a "space of abstract variables."

Morphospaces

Morphospaces also lack a dimension of fitness. Instead, their axes are mathematical models of phenotypic traits developed ''a priori'' to observational measurements. Observational measurements are then mapped onto the resulting surface to indicate areas of possible phenotypic space occupied by the species under consideration.Pigliucci M 2012. "Landscapes, surfaces, and morphospaces: What are they good for?" In: The Adaptive Landscape in Evolutionary Biology. eds. Erik Svensson & Ryan Calsbeek Oxford Press.

Applications to genomics

Recent increases in computational power and ease of sequencing have allowed the concept of evolutionary landscapes to be taken from a purely conceptual metaphor to something that can be modeled and explored. This is especially true of the field of genomics. One good example is the research article "The Evolutionary Landscape of Cytosolic Microbial Sensors in Humans."Vasseur E, M Boniotto, E Patin, G Laval, H Quach, J Manry, B Crouau-Roy, & L Quintana-Murci. 2012. The Evolutionary Landscape of Cytosolic Microbial Sensors in Humans. The American Journal of Human Genetics 91:27-37. In their study, Vasseur et al. were interested in the evolution of the innate immune system; specifically, they wished to map the genetic diversity—the occupied evolutionary landscape—and patterns of selection and diversification—the movements made and being made along that landscape—of the NOD-like receptor (NLR) family of the pattern-recognition receptors (PRRs) that drive the innate immune response. These genes are responsible for detecting patterns/chemicals (e.g. chitin,

oxidative stress Oxidative stress reflects an imbalance between the systemic manifestation of reactive oxygen species and a biological system's ability to readily detoxify the reactive intermediates or to repair the resulting damage. Disturbances in the normal ...

) associated with invading

microbes A microorganism, or microbe,, ''mikros'', "small") and ''organism'' from the el, ὀργανισμός, ''organismós'', "organism"). It is usually written as a single word but is sometimes hyphenated (''micro-organism''), especially in olde ...

, tissue damage, and stress. To achieve this, they sequenced 21 genes from 185 humans and used several statistical methods to examine patterns of selection and diversification. The NLR family can be divided into two subfamilies—the NALP subfamily and the NOD/IPAF subfamily. The authors found that the NALP family was under strong

purifying selection In natural selection, negative selection or purifying selection is the selective removal of alleles that are deleterious. This can result in stabilising selection through the purging of deleterious genetic polymorphisms that arise through random ...

and exhibited low genetic and functional diversity. They hypothesize this is because these genes have vital, non-redundant roles. Evidence in favor of this hypothesis comes from the independent discovery of rare alleles with mutations in two of the genes leading to a severe inflammatory disease and pregnancy complications. The NOD/IPAF subfamily seems to have evolved under relaxed selection and exhibits a fair amount of genetic and functional diversity. The authors also found evidence of positive selection. The gene with the strongest positive selection was NLRP1, which has two

haplotypes A haplotype (haploid genotype) is a group of alleles in an organism that are inherited together from a single parent. Many organisms contain genetic material ( DNA) which is inherited from two parents. Normally these organisms have their DNA org ...

undergoing selective sweeps. The first haplotype is seven amino acids in strong

linkage disequilibrium In population genetics, linkage disequilibrium (LD) is the non-random association of alleles at different loci in a given population. Loci are said to be in linkage disequilibrium when the frequency of association of their different alleles is h ...

. This haplotype is global and seems to be moving toward fixation, which started in Asia and is still occurring in Europe and Africa. The second haplotype is restricted to Europe and is not in linkage disequilibrium with the global haplotype. This European haplotype carries with it a mutation associated with autoimmune diseases. The authors hypothesize another mutation in the haplotype is what selection is acting on and this deleterious mutation is simply hitchhiking along with it. The second example comes from a paper titled "Synonymous Genes Explore Different Evolutionary Landscapes."Cambray G & D Mazel. 2008. Synonymous Genes Explore Different Evolutionary Landscapes. PLoS Genetics 4(11). The authors of this paper are broadly interested in the ability of a protein to evolve. They specifically wanted to know how synonymous substitutions affected the evolutionary landscape of a protein. To do this, they used a program called the Evolutionary Landscape Printer to design a synonymous version of the antibiotic resistance gene ''aac(6')-IB''. A synonymous protein has the same amino acid sequence but different nucleotide sequences. Thus, a synonymous protein has the same function and fitness value but a different surrounding evolutionary landscape. Basically, this is a way to jump peaks without actually moving. The landscape of the original protein and the synonymous copy were explored computationally with Monte Carlo simulations and error-prone PCR. The PCR products were then inserted into competent ''E. coli'' cells and screened for novel antibiotic resistance. They found that each of the two proteins gives rise to a very different novel phenotype that, theoretically, is unreachable from the other. From their results, the authors concluded that synonymous codons allow for a wider exploration of the local evolutionary landscape, and that the method they used increases the odds of finding an advantageous mutation, which is useful for predicting how a population might change and for designing better organisms for industry.

References

External links

Examples of visualized evolutionary landscapes:
Video: Using fitness landscapes to visualize evolution in action

BEACON Blog--Evolution 101: Fitness Landscapes

* ttp://news.ucdavis.edu/search/news_detail.lasso?id=10451 Pup Fish Evolution--UC Davis
Evolution 101--Shifting Balance Theory (Figure at bottom of page)
{{DEFAULTSORT:Evolutionary Landscape Evolutionary biology