Ecological selection

Last updated November 09, 2023

Ecological selection (or environmental selection or survival selection or individual selection or asexual selection) refers to natural selection without sexual selection, i.e. strictly ecological processes that operate on a species' inherited traits without reference to mating or secondary sex characteristics.^{[ citation needed ]} The variant names describe varying circumstances where sexual selection is wholly suppressed as a mating factor.^{[ citation needed ]}

Circumstances in which it occurs

Ecological selection can be said to be taking place in any circumstance where inheritance of specific traits is determined by ecology alone without direct sexual competition, when e.g. sexual competition is strictly ecological or economic, there is little or no mate choice, females do not resist any male who wishes to mate, all traits will be equally propagated regardless of mating, or the species is hermaphroditic or asexually reproducing, an ecological selection is taking place. For example, environmental pressures are largely responsible for the evolution of different life history strategies between the African honey bee, A. m. scutellata, and the European honey bee.^[2]

In sexually reproducing species, it is applicable mostly to situations where ecological pressures prevent most competitors from reaching maturity, or where crowding or pair-bonding or an extreme suppression of sexual selection factors prevents the normal sexual competition rituals and selection from taking place, but which also prevent artificial selection from operating, e.g. arranged marriages, where parents rather than the young select the mate based on economic or even astrological factors, and where the sexual desires of the mated pair are often subordinated to these factors, are artificial unless wholly based on an ecological factor such as control of land which is held by their own force.

In forests, ecological selection can be witnessed involving many factors such as available sunlight, soil quality, and the surrounding biota. During forest growth, tree seedlings in particular, are ecosystem pioneers, and different tree seedlings can often react to a number of members in their ecological community in completely different ways, thus providing a spectrum of ecological occupations.^[3] On the other hand, adult trees can heavily impact their ecological communities, reversing the roles of ecological selection.^[4] Elements of the soil are an extremely influential selective factor in forest growth. Throughout time, every species of tree has evolved to grow under specific soil conditions, whether it is dependent on the pH levels, the mineral contents, or the drainage levels. Each of these is a vehicle for ecological selection to do its work in the course of evolution. However, ecological selection can be much more specific, not only working within species but within populations, even populations in the same region. For example, scientists in Quebec recently examined how tree seedlings react to different nitrate levels. What they found was that areas with higher nitrate levels contained plants that could much more efficiently metabolize nitrogen. Such plants could perform photosynthesis and respiration at a much faster rate than their nitrogen lacking peers, and also had longer root lengths on average, giving them an evolutionary advantage for their habitat. Nitrogen levels that are unexpectedly too high could harm some tree species, but these particular specimens created a niche for themselves, and could outcompete others around them.^[3] A site of tree growth can also be influenced by slope, rockiness, climate, and available sunlight. Space is initially available to everything, but seedlings that can most quickly inhabit the soil and take advantage of the available nutrients are usually most successful. Generally, one of the first factors to control which species grow best in the soil is the amount of sunlight. Soil and water themselves are both very important (For instance, a dry hardwood such as a white oak will not grow in a swamp), but sunlight is the initial decider in forest succession.^[5] Shade intolerant trees can immediately grow impressively. They need the sunlight that is offered by an open canopy found in a bare environment. Selection weeds out the seedlings that can not handle full sun, thus tall, straight trees will eventually grow and develop a full, lush canopy. However, these behaviors will soon be reversed. Seedlings that were once removed by ecological selection now become favored, because the shaded forest floor has become ideal for such shade tolerant species. This is a great example of how ecological selection can create niches for different species by performing the same function with different outcomes.

Vs. sexual selection

In cases where ecological and sexual selection factors are strongly at odds, simultaneously encouraging and discouraging the same traits, it may also be important to distinguish them as sub-processes within natural selection.

For instance, Ceratogaulus, the Oligocene horned gopher, left in the fossil record a series of individuals with successively longer and longer horns, that seemed to be unrelated or maladaptive to its ecological niche. Some modern scientists have theorized that the horns were useful or impressive in mating rituals among males (although other scientists dispute this theory, pointing out that the horns were not sexually dimorphic) and that it was an example of runaway evolution. The species seems to have suddenly died out when horns reached approximately the body length of the animal itself, possibly because it could no longer run or evade predators—thus ecological selection seems to have ultimately trumped sexual. ^{[ citation needed ]}

It is also important to distinguish ecological selection in cases of extreme ecological abundance, e.g. the human built environment, cities or zoos, where sexual selection must generally predominate, as there is no threat of the species or individuals losing their ecological niche. Even in these situations, however, where survival is not in question, the variety and the quality of food, e.g. as presented by male to female monkeys in exchange for sex in some species, still influences reproduction, however it becomes a sexual selection factor. Similar phenomena can be said to exist in humans e.g. the "mail order bride" who primarily mates for economic advantage.

Differentiating ecological selection from sexual is useful especially in such extreme cases; Above examples demonstrate exceptions rather than a typical selection in the wild. In general, ecological selection is assumed to be the dominant process in natural selection, except in highly cognitive species that do not, or do not always, pair bond, e.g. walrus, gorilla, human. But even in these species, one would distinguish cases where isolated populations had no real choice of mates, or where the vast majority of individuals died before sexual maturity, leaving only the ecologically selected survivor to mate—regardless of its sexual fitness under normal sexual selection processes for that species.

For example, if only a few closely related males survive a natural disaster, and all are able to mate very widely due to lack of males, sexual selection has been suppressed by an ecological selection (the disaster). Such situations are usually temporary, characteristic of populations under extreme stress, for relatively short terms. However, they can drastically affect populations in that short time, sometimes eliminating all individuals susceptible to a pathogen, and thereby rendering all survivors immune. A few such catastrophic events where ecological selection predominates can lead to a population with specific advantages, e.g. in colonization when invading populations from more crowded disease-prone conditions arrive with antibodies to diseases, and the diseases themselves, which proceed to wipe out natives, clearing the way for the colonists.

In humans, the intervention of artificial devices such as ships or blankets may be enough to make some consider this an example of artificial selection. However it is clearly observed in other species, it seems unreasonable to differentiate colonization by ship from colonization by walking, and even the word "colony" is not specific to humans but refers generically to an intrusion of one species on an ecology to which it has not wholly adapted. So, despite the potential controversy, it may be better to consider all examples of colonist-borne diseases to be ecological selection.

For another example, in a region devastated by nuclear radiation, such as the Bikini Atoll, capacity to survive gamma rays to sexual maturity and (for the female) to term is a key ecological selection factor, although it is neither "natural" nor sexual. Some would call this too artificial selection, not natural or ecological, as the radiation does not enter the ecology as a factor save due to man's effort. Ambiguous artificial-plus-ecological factors may reasonably be called "environmental", and the term environmental selection may be preferable in these cases.

Related Research Articles

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In ecology, a niche is the match of a species to a specific environmental condition. It describes how an organism or population responds to the distribution of resources and competitors and how it in turn alters those same factors. "The type and number of variables comprising the dimensions of an environmental niche vary from one species to another [and] the relative importance of particular environmental variables for a species may vary according to the geographic and biotic contexts".

This glossary of ecology is a list of definitions of terms and concepts in ecology and related fields. For more specific definitions from other glossaries related to ecology, see Glossary of biology, Glossary of evolutionary biology, and Glossary of environmental science.

In biology, polymorphism is the occurrence of two or more clearly different morphs or forms, also referred to as alternative phenotypes, in the population of a species. To be classified as such, morphs must occupy the same habitat at the same time and belong to a panmictic population.

Disruptive selection, also called diversifying selection, describes changes in population genetics in which extreme values for a trait are favored over intermediate values. In this case, the variance of the trait increases and the population is divided into two distinct groups. In this more individuals acquire peripheral character value at both ends of the distribution curve.

Forest ecology is the scientific study of the interrelated patterns, processes, flora, fauna and ecosystems in forests. The management of forests is known as forestry, silviculture, and forest management. A forest ecosystem is a natural woodland unit consisting of all plants, animals, and micro-organisms in that area functioning together with all of the non-living physical (abiotic) factors of the environment.

Human behavioral ecology (HBE) or human evolutionary ecology applies the principles of evolutionary theory and optimization to the study of human behavioral and cultural diversity. HBE examines the adaptive design of traits, behaviors, and life histories of humans in an ecological context. One aim of modern human behavioral ecology is to determine how ecological and social factors influence and shape behavioral flexibility within and between human populations. Among other things, HBE attempts to explain variation in human behavior as adaptive solutions to the competing life-history demands of growth, development, reproduction, parental care, and mate acquisition. HBE overlaps with evolutionary psychology, human or cultural ecology, and decision theory. It is most prominent in disciplines such as anthropology and psychology where human evolution is considered relevant for a holistic understanding of human behavior.

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The following outline is provided as an overview of and topical guide to ecology:

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Reinforcement is a process of speciation where natural selection increases the reproductive isolation between two populations of species. This occurs as a result of selection acting against the production of hybrid individuals of low fitness. The idea was originally developed by Alfred Russel Wallace and is sometimes referred to as the Wallace effect. The modern concept of reinforcement originates from Theodosius Dobzhansky. He envisioned a species separated allopatrically, where during secondary contact the two populations mate, producing hybrids with lower fitness. Natural selection results from the hybrid's inability to produce viable offspring; thus members of one species who do not mate with members of the other have greater reproductive success. This favors the evolution of greater prezygotic isolation. Reinforcement is one of the few cases in which selection can favor an increase in prezygotic isolation, influencing the process of speciation directly. This aspect has been particularly appealing among evolutionary biologists.

This glossary of genetics and evolutionary biology is a list of definitions of terms and concepts used in the study of genetics and evolutionary biology, as well as sub-disciplines and related fields, with an emphasis on classical genetics, quantitative genetics, population biology, phylogenetics, speciation, and systematics. Overlapping and related terms can be found in Glossary of cellular and molecular biology, Glossary of ecology, and Glossary of biology.

References

↑ McCoughlin, Phillip D.; Morris, Douglas W.; Fortin, Daniel; Vander Wal, Eric; Contasti, Adrienne L. (January 1, 2010). "Considering ecological dynamics in resource selection functions". Journal of Animal Ecology. 79 (1): 4–12. doi: 10.1111/j.1365-2656.2009.01613.x . PMID 19732211.^{[ permanent dead link ]}
↑ Fewell, Jennifer H.; Susan M. Bertram (2002). "Evidence for genetic variation in worker task performance by African and European honeybees". Behavioral Ecology and Sociobiology. 52 (4): 318–25. doi:10.1007/s00265-002-0501-3. S2CID 22128779.
1 2 Marks, C.O.; Conti, E. (2007). "The causes of variation in tree seedling traits: the roles of environmental selection versus chance". Evolution. 61 (2): 455–469. doi: 10.1111/j.1742-4658.2007.00021.x . PMID 17348954. S2CID 23528064.
↑ Barnes, B.V.; Spurr, S.H. (1980). Forest Ecology. New York: Wiley.
↑ Park, A.; Van, B.M.; Ashton, M.S.; Wishnie, M.; Mariscal, E.; Deago, J.; Ibarra, D.; Hall, J.S. (2012). "Local and regional environmental variation influences the growth of tropical trees in selection trials in the Republic of Panama". Forest Ecology and Management. 260 (1): 12–21. doi:10.1016/j.foreco.2010.03.021. S2CID 86520815.

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[1] McCoughlin, Phillip D.; Morris, Douglas W.; Fortin, Daniel; Vander Wal, Eric; Contasti, Adrienne L. (January 1, 2010). "Considering ecological dynamics in resource selection functions". Journal of Animal Ecology. 79 (1): 4–12. doi: 10.1111/j.1365-2656.2009.01613.x . PMID 19732211.^{[ permanent dead link ]}

[Fewell_and_Bertram,_2002-2] Fewell, Jennifer H.; Susan M. Bertram (2002). "Evidence for genetic variation in worker task performance by African and European honeybees". Behavioral Ecology and Sociobiology. 52 (4): 318–25. doi:10.1007/s00265-002-0501-3. S2CID 22128779.

[ReferenceA-3] 1 2 Marks, C.O.; Conti, E. (2007). "The causes of variation in tree seedling traits: the roles of environmental selection versus chance". Evolution. 61 (2): 455–469. doi: 10.1111/j.1742-4658.2007.00021.x . PMID 17348954. S2CID 23528064.

[4] Barnes, B.V.; Spurr, S.H. (1980). Forest Ecology. New York: Wiley.

[5] Park, A.; Van, B.M.; Ashton, M.S.; Wishnie, M.; Mariscal, E.; Deago, J.; Ibarra, D.; Hall, J.S. (2012). "Local and regional environmental variation influences the growth of tropical trees in selection trials in the Republic of Panama". Forest Ecology and Management. 260 (1): 12–21. doi:10.1016/j.foreco.2010.03.021. S2CID 86520815.

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v t e Evolutionary biology
Introduction Outline Timeline of evolution History of life Index
Evolution	Abiogenesis Adaptation Adaptive radiation Altruism Cheating Reciprocal Baldwin effect Cladistics Coevolution Mutualism Common descent Convergence Divergence Earliest known life forms Evidence of evolution Evolutionary pressure Exaptation Extinction Event Homology Last universal common ancestor Macroevolution Microevolution Mismatch Non-adaptive radiation Origin of life Panspermia Parallel evolution Signalling theory Handicap principle Speciation Species Species complex Species problem Taxonomy Unit of selection Gene-centered view of evolution
Population genetics	Artificial selection Biodiversity Evolutionarily stable strategy Fisher's principle Fitness Inclusive Gene flow Genetic drift Kin selection Parental investment Parent–offspring conflict Mutation Population Natural selection Sexual dimorphism Sexual selection Mate choice Social selection Trivers–Willard hypothesis Variation
Development	Canalisation Evolutionary developmental biology Genetic assimilation Inversion Modularity Phenotypic plasticity
Of taxa	Bacteria Birds origin Brachiopods Molluscs Cephalopods Dinosaurs Fish Fungi Insects butterflies Life Mammals cats canids wolves dogs hyenas dolphins and whales horses Kangaroos primates humans lemurs sea cows Plants pollinator-mediated Reptiles Spiders Tetrapods Viruses
Of organs	Cell DNA Flagella Eukaryotes symbiogenesis chromosome endomembrane system mitochondria nucleus plastids In animals eye hair auditory ossicle nervous system brain
Of processes	Aging Death Programmed cell death Avian flight Biological complexity Cooperation Color vision in primates Emotion Empathy Ethics Eusociality Immune system Metabolism Monogamy Morality Mosaic evolution Multicellularity Sexual reproduction Gamete differentiation/sexes Life cycles/nuclear phases Mating types Meiosis Sex-determination Snake venom
Tempo and modes	Gradualism/Punctuated equilibrium/Saltationism Micromutation/Macromutation Uniformitarianism/Catastrophism
Speciation	Allopatric Anagenesis Catagenesis Cladogenesis Cospeciation Ecological Hybrid Non-ecological Parapatric Peripatric Reinforcement Sympatric
History	Renaissance and Enlightenment Transmutation of species David Hume Dialogues Concerning Natural Religion Charles Darwin On the Origin of Species History of paleontology Transitional fossil Blending inheritance Mendelian inheritance The eclipse of Darwinism Neo-Darwinism Modern synthesis History of molecular evolution Extended evolutionary synthesis
Philosophy	Darwinism Alternatives Catastrophism Lamarckism Orthogenesis Mutationism Saltationism Structuralism Spandrel Theistic Vitalism Teleology in biology
Related	Biogeography Ecological genetics Evolutionary medicine Group selection Cultural evolution Cultural group selection Dual inheritance theory Hologenome theory of evolution Missing heritability problem Molecular evolution Astrobiology Phylogenetics Tree Polymorphism Protocell Systematics Transgenerational epigenetic inheritance
Category Portal Commons WikiProject

v t e Population genetics
Key concepts	Hardy–Weinberg principle Genetic linkage Identity by descent Linkage disequilibrium Fisher's fundamental theorem Neutral theory Shifting balance theory Price equation Coefficient of inbreeding Coefficient of relationship Selection coefficient Fitness Heritability Population structure Constructive neutral evolution
Selection	Natural Artificial Sexual Ecological
Effects of selection on genomic variation	Genetic hitchhiking Background selection
Genetic drift	Small population size Population bottleneck Founder effect Coalescence Balding–Nichols model
Founders	R. A. Fisher J. B. S. Haldane Sewall Wright
Related topics	Biogeography Evolution Evolutionary game theory Fitness landscape Genetic genealogy Landscape genetics and genomics Microevolution Population genomics Phylogeography Quantitative genetics
Index of evolutionary biology articles

Ecological selection

Contents

Circumstances in which it occurs

Vs. sexual selection

See also

Related Research Articles

References