Penguins construct huddle temperature

Emperor penguins are the only vertebrate species able to breed during the Antarctic winter. They huddle together to try to keep warm in an icy landscape that can be as cold as 50 degrees Celsius below zero. By huddling together for just two hours, penguin bodies can raise the temperature in the middle of the huddle to as high as 37 degrees above zero. To find out more about how penguins create a warm environment in the Antarctic, read Gilbert et al. (2007).

Earthworms make soil

Despite living on land for millions of years, earthworms have retained the physiology of the freshwater species from which they evolved. For more on how earthworms process soil to suit their aquatic physiology read Turner (2000). A précis can be found in Odling-Smee et al. (2003). For an up-to-date summary of earthworm effects on soil see Frelich et al. (2019). Caro et al. (2014) describe how earthworm niche construction can improve soil quality and reduce earthworm dispersal.

Hermit crabs build homes

Hermit crabs use shells as safe homes to live in. They modify these shells to increase their inner size and reduce their weight. As they grow, they need larger shells. But the only shells big enough are those carried by other hermit crabs. Hermit crabs gather, waiting for other hermit crabs to change shells, and then jump into a suitable vacated one. Laidre 2012, 2019 describes how, by hollowing out the gastropod shells in which they live, hermit crabs create a biological market and drive the evolution of social dependence.

Dung beetles construct dung balls

Female dung beetles manufacture and bury a brood ball of dung and insert into it a faecal pedestal onto which they lay an egg. Through niche construction they provide a safe home, food, and microbiome for their developing young. Developing larvae also processes the brood ball, changing microbiome composition. Experiments show that maternal and offspring niche construction strongly affect offspring size, fitness and trait characteristics. For more on how mother dung beetles construct a brood ball and the role of larval niche construction see Schwab et al. (2016, 2017).

Forest fires construct local ecology

By affecting local fire intensities or the probability of ignition, traits that influence plant flammability may indirectly control selection for fire-related life-history and physiological traits. To learn more about how flammability traits shape natural selection on fire tolerance and resprouting, read Schwilk (2003).

Plants create developmental environments

Even traits such as the timing of germination and flowering can be niche-constructing traits. The timing of germination and flowering determine the seasonal environment experienced by plants and their offspring. This alters many traits, the expression of genetic variation of those traits, and natural selection on those traits. To learn more about how the timing of flowering and germination are niche-constructing traits for seeds, see Donohue’s studies of Arabidopsis (2005, 2013).

Snails construct a desert ecosystem

Euchondrus spp. snails feed on lichens that grow on and under rocks in the Negev desert. Each snail is very small, and has a tiny effect on its environment, and yet their activities have a massive effect on the entire desert ecosystem. For more on how, by breaking down rocks to eat lichen, snails create soil in the desert, and support an entire ecosystem, read Shachak et al. (1987) and Jones & Shachak (1990).

Dairy farming creates a new niche

The domestication of cattle and consumption of dairy products is a compelling example of human niche construction. For more on how the cultural niche-constructing habit of dairy farming generated selection for adult lactose tolerance read Gerbault et al. (2011) and O’Brien & Laland (2012).  For other examples of cultural niche construction see Laland et al. (2010).

Yeast construct a transport system

Buser et al. (2014) demonstrate experimentally how through their niche construction (the modification of fruit) the yeast Saccharomyces cerevisiae attracts Drosophila, and facilitates its own propagation.

Bacteria create new niches

Callahan et al. (2014) demonstrate experimentally that niche construction evolves rapidly, under a broad range of conditions, in microbial populations. San Roman & Wagner (2018) show that bacterial niche construction creates a very large number of new niches for other bacteria.

Rhubarb creates moisture in the desert

More desert plants have small leaves or spines, to conserve water. The desert rhubarb (Rheum palaestinum) survives with huge leaves that are self-irrigating. Its leaves channel water towards its taproot, which grows and​ then shrinks again, producing chemical exudates that line the cavity, where water gathers. To learn how the desert rhubarb constructs a moisture-rich environment in the desert read Lev-Yadun et al. (2009).

Squid and bacteria construct a light organ

To read about how a squid and some bacteria collaborated to create a light organ see Gilbert (2020). Other examples of developmental niche construction can be found in Laland et al. (2008) and Gilbert (2020).

Domestication and origins of agriculture

To learn more about how human niche construction played a vital role in the domestication of plants and animals and the origins of agriculture, read Smith (2007, 2016) and Zeder (2017, 2018).

Killer whale culture

For more on how the cultural dietary habits of killer whales are driving their own evolution read Foote et al. (2016).

Beavers construct local communities

To learn more about how, by cutting down trees and constructing dams, beavers transform rivers and streams into wetlands with a very different community structure, read Naiman et al. (1988) and Wright et al. (2002).

Forbs & grasses construct local ecology

To learn more about how, by affecting process rates and nutrient cycling, forbs and grasses create niches for other alpine plants, see Brathen & Raivolainen (2015).

Plants construct the light

To read about how plants alter the shape and orientation of their leaves to optimize the amount of light they receive, and many other examples of experiential niche construction, see Sultan (2015).

Viral niche construction

To read more about how viruses create diseases by constructing niches for themselves, read Hamblin et al. (2014).

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Science Front Cover

Anton SC, Potts R, Aiello LC. 2014

Evolution of early homo: an integrated biological perspective. Science. 345(6192): 1236828

Adam's Tongue Book Cover

Bickerton D. 2009

Adam’s Tongue: How Humans Made Language, How Language Made Humans. New York: Hill & Wang

PNAS Front cover

Boivin N, et al. 2016

Ecological consequences of human niche construction: examining long-term anthropogenic shaping of global species distributions. PNAS. 113(23): 6388-96

Evolution 59 Front cover

Boni MF, Feldman MW. 2005

Evolution of antibiotic resistance by human and bacterial niche construction. Evolution. 59(3): 477–91

Abstract from Bioscience 56

Boogert NJ, Laland KN, Paterson DM. 2006

The implications of niche construction and ecosystem engineering for conservation biology. Bioscience. 56(7): 570–78

Journal of Ecology front cover

Brathen KA, Raivolainen VT. 2015

Niche construction by growth forms is as strong a predictor of species diversity as environmental gradients. Journal of Ecology. 103(3):701–13

Ecology Letters front cover

Buser CC, Newcomb RD, Gaskett AC, Goddard MR. 2014

Niche construction initiates the evolution of mutualistic interactions. Ecology letters. 17(10): 1257-1264

Evolution 68 issue 11 front cover

Callahan BJ, Fukami T, Fisher DS. 2014

Rapid evolution of adaptive niche construction in experimental microbial populations. Evolution. 68(11): 3307-16

PNAS Front cover

Chisholm RH, et al. 2016

Controlled fire use in early humans might have triggered the evolutionary emergence of tuberculosis. PNAS. 113(32): 9051-6 

Abstract Birth of the Holobiont

Chiu L, Gilbert SF. 2015

The birth of the holobiont: multi-species birthing through mutual scaffolding and niche construction. Biosemiotics. 8(2): 191-210 

Book front cover

Chiu L. 2019

Decoupling, commingling, and the evolutionary significance of experiential niche construction. In Evolutionary Causation: Biological and Philosophical Reflections, ed. T Uller, KN Laland, pp. 127–52. Cambridge, MA: MIT Press

Abstract from Americal Naturalist

Clark AD, et al. 2020

Niche construction affects the variability and strength of natural selection. The American Naturalist. 195(1):16-30

PNAS front cover

Creanza N, Kolodny O, Feldman MW. 2017

Cultural evolutionary theory: how culture evolves and why it matters. PNAS114(30): 7782-9 

Abstract Trends in Ecology & Evolution

Erwin DH . 2008

Macroevolution of ecosystem engineering, niche construction and diversity. Trends in Ecology & Evolution. 23(6): 304–10

Science 308 front cover

Erwin DH. 2005

Seeds of diversity. Science. 308(5729):1752–1753

Abstract from Developmental Science 16

Flynn EG, Laland KN, Kendal RK, Kendal JR. 2013

Developmental niche construction. Developmental Science. 16(2): 296-313 

Fogarty L & Creanza N 2017

The niche construction of cultural complexity: interactions between innovations, population size and the environment. Philosophical Transactions Royal Society B. 372(1735): 20160428 

RSTB 366 front cover

Gerbault P, et al. 2011

Evolution of lactase persistence: an example of human niche construction. Philosophical Transactions of the Royal Society B: Biological Sciences. 366(1566):863–77

Trends in Ecology & Evolution front cover

Hamblin S. 2014

Viral niche construction alters hosts and ecosystems at multiple scales. Trends in Ecology & Evolution. 29(11): 594-9

Abstract from Functional Ecology 7

Hansell MH. 1993

The ecological impact of animal nests and burrows. Functional Ecology. 7(1): 5–12

Abstract from Oikos 69

Jones CG, Lawton JH, Shachak M. 1994

Organisms as ecosystem engineers. Oikos. 69(3): 373-86

RSTB 366 front cover

Kendal JR, Tehrani JJ, Odling-Smee FJ. 2011

Human niche construction. Theme issue of Philosophical transactions of the Royal Society B. 366(1566): 785–792 

American Naturalist front cover

Krakauer DC, Page KM, Erwin DH. 2009

Diversity, dilemmas, and monopolies of niche construction. The American Naturalist. 173(1):26–40

Abstract from Ecology Letters 11

Kylafis G, Loreau M. 2008

Ecological and evolutionary consequences of niche construction for its agent. Ecology Letters. 11(10):1072–81

Ecology Letters 14 front cover

Kylafis G, Loreau M. 2011

Niche construction in the light of niche theory. Ecology Letters. 14(2): 82-90 

Science front cover

Laland KN, et al. 2011

Cause and effect in biology revisited: is Mayr’s proximate-ultimate dichotomy still useful? Science. 334(6062):1512–16

Abstract from PNAS

Laland KN, Odling-Smee FJ, Feldman MW. 1999

Evolutionary consequences of niche construction and their implications for ecology. PNAS. 96(18):10242–47

Book front cover

Laland KN, Odling-Smee FJ, Feldman MW. 2019

Understanding niche construction as an evolutionary process. In Evolutionary Causation: Biological and Philosophical Reflections, ed.T Uller, KN Laland, pp. 127–52. Cambridge, MA: MIT Press

Abstract from Journal of Experimental Zoology, Part B

Laland KN, Odling-Smee FJ, Gilbert SF. 2008

EvoDevo and niche construction: building bridges. Journal of Experimental Zoology Part B: Molecular and Developmental Evolution. 310B(7):549–66

Abstract from Nature Reviews Genetics

Laland KN, Odling-Smee FJ, Myles S. 2010

How culture shaped the human genome: bringing genetics and the human sciences together. Nature Reviews Genetics. 11(2):137–48

Abstract from Evolution

Lehmann L. 2008

The adaptive dynamics of niche constructing traits in spatially subdivided populations: Evolving posthumous extended phenotypes. Evolution. 62(3):549–66

Front cover Biological Journal

Lewens T. 2019

The Extended Evolutionary Synthesis: what is the debate about, and what might success for the extenders look like? Biological Journal of the Linnean Society. 127(4): 707–21

Ecological Monographs front cover

Matthews B, et al. 2014

Under niche construction: an operational bridge between ecology, evolution and ecosystem science. Ecological Monographs. 84(2): 245–263

Abstract from Current Biology 24

Mumby PJ, Van Woesik R. 2014

Consequence of ecological, evolutionary and biogeochemical uncertainty for coral reef responses to climatic stress. Current Biology. 24(10): R413–23 

Abstract from Current Anthropology

O’Brien M, Laland KN. 2012

Genes, culture and agriculture: an example of human niche construction. Current Anthropology. 53(4): 434-70

Quarterly Review of Biology front cover

Odling-Smee FJ, et al. 2013

Niche construction theory: a practical guide for ecologists. The Quarterly Review of Biology. 88(1):3–28

Niche Construction Front Cover

Odling-Smee FJ, Laland KN, Feldman MW. 2003

Niche Construction: The Neglected Process in Evolution. Princeton: Princeton University Press

Book front cover

Oyama S, et al. 2001

Oyama S, Griffiths P, Gray RD, eds. 2001. Cycles of Contingency: Developmental Systems and Evolution. Cambridge: The MIT Press

Book front cover

Oyama S. 1985

The Ontogeny of Information: Developmental Systems and Evolution. Duke University Press. 2nd ed.

RSTB 364 front cover

Post DM, EP Palkovacs. 2009

Eco-evolutionary feedbacks in community and ecosystem ecology: interactions between the ecological theatre and the evolutionary play. Philosophical Transactions of the Royal Society B: Biological Sciences. 364(1523):1629–40

Abstract from PLOS

San Roman M, Wagner A. 2018

An enormous potential for niche construction through bacterial cross-feeding in a homogeneous environment. PLoS computational biology. 14:(7): e1006340

Abstract from Ecology Letters

Schwab DB, Casasa S, Moczek AP. 2017

Evidence of developmental niche construction in dung beetles: effects on growth, scaling and reproductive success. Ecology Letters. 20(11): 1353–63 

American Naturalist front cover

Schwab DB, Riggs HE, Newton ILG, Moczek AP. 2016

Developmental and ecological benefits of the maternally transmitted microbiota in a dung beetleThe American Naturalist. 188(6): 679-82 

Evolution front cover

Scott-Phillips TC, et al. 2014

The niche construction perspective: a critical appraisal. Evolution. 68(5): 1231-43

Theoretical Pop Bio front cover

Silver M, Di Paolo EA. 2006

Spatial effects favour the evolution of niche construction. Theoretical population Biology. 70(4): 387-400

Abstract from Evolutionary Anthropology 16

Smith B. 2007

Niche construction and the behavioral context of plant and animal domestication. Evolutionary Anthropology. 16(5): 188–99

Organism & Environment Book cover

Sultan SE. 2015

Organism & environment: Ecological Development, Niche Construction, and Adaptation. Oxford: Oxford University Press

Philosophy of Science front cover

Tanaka MM, Godfrey-Smith P, Kerr B. 2020

The dual landscape model of adaptation and niche construction. Philosophy of Science. https://doi.org/10.1086/708692

British journal front cover

Uller T, Helanterä H. 2019

Niche construction and conceptual change in evolutionary biology. British Journal for the Philosophy of Science. 70(2): 351-75

Abstract from Evolution

Van Dyken JD, Wade MJ. 2012

Origins of altruism diversity II: runaway coevolution of altruistic strategies via reciprocal niche construction. Evolution. 66(8): 498–251

Organisms, Agency and Evolution

Walsh DM. 2015

Organism, Agency and Evolution. Cambridge: Cambridge University Press

Oecologia. 132 front cover

Wright JP, et al. 2002

An ecosystem engineer, the beaver, increases species richness at the landscape scale. Oecologia. 132(1): 96-101 

Abstract from Journal of Anthropological Archaeology 31

Zeder. 2012

The broad spectrum revolution at 40: resource diversity, intensification, and an alternative to optimal foraging explanations. Journal of Anthropological Archaeology. 31(3): 241-64

Adaptation (process)

The complementary match between organism and environment arises through interactions between natural selection and internally and externally expressed constructive development. https://doi.org/10.1093/bjps/axz054

Constructive development

The developing organism shapes its own developmental trajectory by responding to environmental inputs and altering internal and external states.

Counteractive niche construction

Organisms either perturb their environments, or move in space, to wholly or partly reverse or neutralise some prior change in their environment.

Cryptic genetic variation

Genetic variation that normally has little or no effect on phenotypic variation but is expressed under atypical conditions.

Developmental bias

The nonrandom generation of phenotypes by developmental systems, with variants sometimes being channeled by the processes of development towards functional goals.

Ecological inheritance

The inheritance, via an external environment, of one or more natural selection pressures previously modified by niche-constructing organisms.

Ecosystem engineering

The modification by organisms of physical surroundings (e.g., light environment, physical habitat structure) so as to modulate the availability of resources or energy fluxes in an ecosystem

Evolution

A transgenerational change in the distribution of heritable traits of a population.

Explanatory gap

The absence of a satisfactory causal chain linking causal inputs to outputs.

Extended evolutionary synthesis

A new evolutionary framework emphasizing that knowledge of how organisms develop, grow, and interact with environments helps to account for adaptation and the diversity of life.

Facilitated variation

Viable, adaptive or functional phenotypic variation, frequently generated through somatic selection processes in development (e.g. adaptive immunity).

Genetic accommodation

Gene frequency change due to selection on variation in the regulation, form, or side-effects of a novel trait.

Genetic assimilation

A form of ‘genetic accommodation’ that occurs when natural selection causes environmentally induced (i.e. plastic) phenotypes to lose their environmental sensitivity over evolutionary time.

Heredity

All causal mechanisms by which offspring come to resemble their parents.

Inceptive niche construction

Organisms either perturb their environments, or move, to introduce a new change in one or more natural selection pressures.

Inclusive inheritance

Parental transference of developmental resources (mediated through genetic, epigenetic, physiological, behavioural and ecological inheritance mechanisms) that enable reconstruction of life cycles.

Niche

The sum of all the natural selection pressures to which the population is exposed.

Niche construction

The process whereby organisms, through their metabolism, their activities, and their choices, modify their own and/or each other’s niches.

Organismal agency

The capacity of living organisms to act on, and in, their world, and to modify their experience of it, including in ways that are neither predetermined, nor random. 

Phenogenotypes

A class of individuals in a human population with a specified combination of a genotype and a variant of a cultural trait.

Phenotypic accommodation

The adaptive mutual adjustment during development of variable parts of an organism, without genetic change.

Phenotypic plasticity

Environmental induction leads to developmental reorganization and production of a novel phenotypic variant.

Plasticity-first evolution

A mechanism of adaptive evolution in which environmental induction leads to developmental reorganization and production of a novel developmental variant that is accommodated by individual phenotypes. If the environmental stimulus is recurrent, the phenotype will be refined and stabilized by genetic accommodation.

Positive niche construction

Niche-constructing acts that, on average, increase the fitness of the niche-constructing organisms. In the short run virtually all niche construction by individual organisms is expected to be positive.

Reciprocal causation

Process A is a cause of process B and, subsequently, process B is a cause of process A. Reciprocal causation captures the idea that developing organisms are not solely products, but are also causes, of evolution.

Relocational niche construction

Organisms actively move in space, as well as choose or bias the direction, the distance in space through which they travel, and the time when they travel, thereby modifying natural selection.

Semantic information

Adaptive, or possibly maladaptive “know how” carried by organisms typically, but not exclusively, in genomes.  In biology “know how” seldom carries cognitive connotations (Chaitin, 1987).

Anton SC, Potts R, Aiello LC. 2014. Evolution of early homo: an integrated biological perspective. Science. 345(6192): 1236828 https://doi.org/10.1093/bjps/axz054

Bäckhed F, Ley RE, Sonnenburg JL, Peterson DA, Gordon JI. 2005. Host-bacterial mutualism in the human intestine. Science. 307(5717):1915–20

Badyaev AV, Uller T. 2009. Parental effects in ecology and evolution: mechanisms, processes and implications. Philosophical Transactions of the Royal Society B: Biological Sciences. 364(1520):1169–77

Bateson P. 1988. The active role of behaviour in evolution. In Evolutionary Processes and Metaphors, ed M-W Ho, SW Fox, pp. 191–207. Chichester: John Wiley & Sons

Bickerton D. 2009. Adam’s Tongue: How Humans Made Language, How Language Made Humans. New York: Hill & Wang

Bird A. 2002. DNA methylation patterns and epigenetic memory. Genes & Development. 16(1): 6–21

Boivin NL, Zeder MA, Fuller DQ, Crowther A, Larson G, et al. 2016. Ecological consequences of human niche construction: examining long-term anthropogenic shaping of global species distributions. PNAS. 113(23): 6388-96

Bonduriansky R. 2012. Rethinking heredity, again. Trends in Ecology & Evolution. 27(6):330–36

Bonduriansky R, Day T. 2018. Extended Heredity: A New Understanding of Inheritance and Evolution. Princeton: Princeton University Press 

Boni MF, Feldman MW. 2005. Evolution of antibiotic resistance by human and bacterial niche construction. Evolution. 59(3): 477–91

Boogert NJ, Laland KN, Paterson DM. 2006. The implications of niche construction and ecosystem engineering for conservation biology. Bioscience. 56(7): 570–78

Bråthen KA, Ravolainen VT. 2015. Niche construction by growth forms is as strong a predictor of species diversity as environmental gradients. Journal of Ecology. 103(3):701–13

Brodie ED. 2005. Caution: niche construction ahead. Evolution. 59(1): 249–251

Buser CC, Newcomb RD, Gaskett AC, Goddard MR. 2014. Niche construction initiates the evolution of mutualistic interactions. Ecology letters. 17(10): 1257-1264

Callahan BJ, Fukami T, Fisher DS. 2014. Rapid evolution of adaptive niche construction in experimental microbial populations. Evolution. 68(11): 3307-3316

Caro G, et al. 2014. Impact of soil engineering by two contrasting species of earthworms on their dispersal rates. Applied Soil Ecology. 84: 223-230

Chaitin GJ. 1987. Algorithmic Information Theory: Cambridge Tracts in Theoretical Computer Science 1. Cambridge: Cambridge University Press

Chase JM, Leibold MA. 2003. Ecological Niches. Linking Classical and Contemporary Approaches. Chicago: University of Chicago Press

Chisholm RH, Connelly BD, Kerr B, Tanaka MM. 2018. The role of pleiotropy in the evolutionary maintenance of positive niche construction. American Naturalist. 192(1): 35-48

Chiu L, Gilbert SF. 2015. The birth of the holobiont: multi-species birthing through mutual scaffolding and niche construction. Biosemiotics. 8(2): 191-210 

Clark AD, Deffner D, Laland K, Odling-Smee J, Endler J. 2020. Niche construction affects the variability and strength of natural selection. The American Naturalist. 195(1):16-30

Clements FE. 1916. Plant Succession: An Analysis of the Development of Vegetation. Washington DC: Carnegie Institute

Collard M, Buchanan B, Ruttle A, O’Brien MJ. 2012. Niche construction and the toolkits of hunter–gatherers and food producers. Biology Theory. 6(3): 251–259

Crain CM, Bertness MD. 2006. Ecosystem engineering across environmental gradients: implications for conservation and management. BioScience. 56(3): 211–218

Creanza N, Fogarty L, Feldman MW. 2012. Models of cultural niche construction with selection and assertive mating. PLoS ONE. 7(8):e42744

Creanza N, Kolodny O, Feldman MW. 2017. Cultural evolutionary theory: how culture evolves and why it matters. PNAS. 114:7782-7789

Creanza N, Feldman MW. 2014. Complexity in models of cultural niche construction with selection and homophily. PNAS. 111(Supplement 3):10830–37

Creanza N, Feldman MW. 2016. Worldwide genetic and cultural change in human evolution. Current Opinion in Genetics and development. 41: 85-92 

Crooks JA, Khim HS. 1999. Architectural vs. biological effects of a habitat-altering, exotic mussel Musculista senhousia. Journal of Experimental Marine Biology and Ecology. 240(1): 53–75

Danchin É, Charmantier A, Champagne FA, Mesoudi A, Pujol B, Blanchet S. 2011. Beyond DNA: integrating inclusive inheritance into an extended theory of evolution. Nature Reviews Genetics.12(7):475–86

Darwin C. 1851. The Structure and Distribution of Coral Reefs. California: University of California Press

Darwin C. 1881. The Formation of Vegetable Mould through the Action of Worms, with Observations on their Habits. London: Murray

Dawkins R. 1982. The Extended Phenotype. New York: Freeman Press

Dawkins R. 2004. Extended phenotype – But not too extended. A reply to Laland, Turner and Jablonka. Biology & Physiology. 19(3): 377–96

Day RL, Laland KN, Odling-Smee J. 2003. Rethinking adaptation – the niche-construction perspective. Perspectives in Biology and Medicine. 46(1): 80-95

Dedeine F, Vavre F, Fleury F, Loppin B, Hochberg ME, Boulétreau M. 2001. Removing symbiotic Wolbachia bacteria specifically inhibits oogenesis in a parasitic wasp. PNAS. 98(11):6247–52

Donohue K. 2013. Why ontogeny matters during adaptation: developmental niche construction and pleiotropy across the life cycle in arabidopsis thaliana. Evolution. 68(1): 32-47

Donohue K. 2005. Niche construction through phenological plasticity: life history dynamics and ecological consequences. New Phytologist Trust. 166(1): 83– 92

Duckworth RA. 2009. The role of behavior in evolution: a search for mechanism. Evolutionary Ecology. 23(4): 513-531

Durham WH. 1991. Coevolution: Genes, Culture and Human Diversity. California: Stanford University Press

Dussourd DE, Ubik K, Harvis C, Resch J, Meinwald J, Eisner T. 1988. Biparental defensive endowment of eggs with acquired plant alkaloid in the moth Utetheisa ornatrix. PNAS. 85(16):5992–96

Ehlers A, Worm B, Reusch TBH. 2008. Importance of genetic diversity in eelgrass Zostera marina for its resilience to global warming. Marine Ecology Progress Series. 355: 1–7

Ellis EC. 2015. Ecology in an anthropogenic biosphere. Ecological Monographs. 85(3):287–331

Ellis EC. 2018. Anthropocene. A Very Short Introduction. Oxford: Oxford University Press 

Erwin DH . 2005. Seeds of diversity. Science. 308(5729):1752–1753

Erwin DH . 2008. Macroevolution of ecosystem engineering, niche construction and diversity.  Trends in Ecology & Evolution. 23(6): 304–310

Cavalli-Sforza LL, Feldman MW. 1989. On the theory of evolution under genetic and cultural transmission, with application to the lactose absorption problem. In Mathematical Evolutionary Theory, ed MW Feldman, pp. 145–73. Princeton: Princeton University Press

Flynn EG, Laland KN, Kendal RK, Kendal JR. 2013. Developmental niche construction. Developmental Science. 16(2): 296-313

Fogarty L, Creanza N. 2017. The niche construction of cultural complexity: interactions between innovations, population size and the environment. Philosophical Transactions Royal Society B. 372(1735): 20160428 

Fogel BM, Crain CM, Bertness MD. 2004. Community level engineering effects of Triglochin maritima (seaside arrowgrass) in a salt marsh in northern New England, USA. Journal of Ecology. 92(4): 589-97

Foote AD, Vijay N, Ávila-Arcos MC, Baird RW, Durban JW, et al. 2016. Genome-culture coevolution promotes rapid divergence of killer whale ecotypes. Nature Communications. 7: 11693

Fortune IS, Paterson DM. 2020. Ecological best practice in decommissioning: a review of scientific research. ICES Journal of Marine Science. 77(3): 1079-91

Frelich LE, et al. 2019. Side-swiped: ecological cascades emanating from earthworm invasions. Frontiers in Ecology and the Environment. 17(9):502-10

Fuentes A. 2009. Evolution of Human Behavior. Oxford, UK: Oxford University Press

Fuentes A. 2017. The Creative Spark. London: Penguin

Gerbault P, Liebert A, Itan Y, Powell A, Currat M, et al. 2011. Evolution of lactase persistence: an example of human niche construction. Philosophical Transactions of the Royal Society B: Biological Sciences. 366(1566):863–77

Gilbert C, Maho YL, Perret M, Ancel A. 2007. Body temperature changes induced by huddling in breeding male emperor penguins. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology. 292(1):R176–85

Gilbert SF, Sapp J, Tauber AI. 2012. A symbiotic view of life: we have never been individuals. Quarterly Review Biology. 87(4): 325-341 

Gilbert SF, Bosch TCG, Ledón-Rettig C. 2015. Eco-Evo-Devo: developmental symbiosis and developmental plasticity as evolutionary agents. Nature Reviews Genetics. 16(10):611–22

Gilbert SF. 2020. Developmental symbiosis facilitates the multiple origins of herbivory. Evolution and Development 22(1-2): 154-64

Gilbert SF, Epel D. 2009. Ecological developmental biology. Integrating Epigenetics, medicine and Evolution. Sunderland, MA
: Sinauer

Godfrey-Smith P. 1996. Complexity and the Function of Mind in Nature. Cambridge: Cambridge University Press

Goldstone JV, Hamdoun A, Cole BJ, et al. 2006. The chemical defensome: environmental sensing and response genes in the Strongylocentrotus purpuratus genome. Developmental Biology. 300(1): 366-84 

Gould SJ, Lewontin R. 1979. The spandrels of San Marco and the Panglossian paradigm: a critique of the adaptationist programme. Proceedings of the Royal Society of London. Series B. Biological Sciences. 205(1161):581–98

 

Griffiths PE, Gray RD. 2001. Darwinism and developmental systems. In Cycles of Contingency: Developmental Systems and Evolution, ed S Oyama, P Griffiths, RD Gray, pp. 195–218. Cambridge, Massachusetts: The MIT Press

Griffiths PE, Gray RD. 2004. The developmental systems perspective. In Phenotypic Integration: Studying the Ecology and Evolution of Complex Phenotypes, ed M Pigliucci, K Preston, pp. 409–30. Oxford, New York: Oxford University Press

Gurney WSC, Lawton JH. 1996. The population dynamics of ecosystem engineers. Oikos. 76(2): 273–283

Hall BK. 2012. Evolutionary developmental biology Evo-Devo: past, present and future. Evolution Education and Outreach. 5(2): 184-93 
 

Hamblin SR, White PA, Tanaka MM. 2014. Viral niche construction alters hosts and ecosystems at multiple scales. Trends in Ecology & Evolution. 29(11): 594-9

Hansell MH. 1993. The ecological impact of animal nests and burrows. Functional Ecology. 7(1): 5–12

Helanterä H, Uller T. 2019. The causes of a major transition: how social insects traverse Darwinian space. In Evolutionary Causation: Biological and Philosophical Reflections, ed. T Uller, KN Laland, pp. 173- 96. Cambridge, MA: MIT Press

Hooper LV, Wong MH, et al. 2001. Molecular analysis of commensal host–microbial relationships in the intestine. Science. 291(5505): 881–84

Hoppitt W, Laland KN.  2013. Social learning: An Introduction to Mechanisms, Methods, and Models. Princeton: Princeton University Press

Hutchinson GE 1957 Concluding remarks. Cold Spring Harbor Symposia on Quantitative Biology. 22:415-27

Ihara Y, Feldman MW. 2004. Cultural niche construction and the evolution of small family size. Theoretical Popular Biology. 65(1):101–111 

Jablonka E, Lamb MJ. 2005. Evolution In Four Dimensions. Cambridge, MA: MIT Press

Jablonka E, Lamb MJ. 2014. Evolution In Four Dimensions. Revised edition. Cambridge, MA: MIT Press

Jackson ISC. 2020. Developmental bias in the fossil record. Evolution & Development. 22(1-2): 88-102 

Jones CG, Lawton JH, Shachak M. 1994. Organisms as ecosystem engineers. Oikos. 69(3): 373-86

Jones CG, Lawton JH. 1995. Linking Species and Ecosystems. New York: Chapman and Hall

Jones CG, Lawton JH, Shachak M. 1997. Positive and negative effects of organisms as physical ecosystem engineers. Ecology. 78: 1946-1957

Jones CG, Shachak M. 1990. Fertilization of desert soil by rock-eating snails. Nature. 346(6287):839–841

Kamra DN. 2005. Rumen microbial ecosystem. Current Science .89(1):124–35  

Kendal J, Tehrani JJ, Odling-Smee FJ. 2011. Human niche construction in interdisciplinary focus. Philosophical Transactions of the Royal Society B: Biological Sciences. 366(1566):785–92

Kirschner MW, Gerhart JC. 2005. The Plausibility of Life: Resolving Darwin’s Dilemma. New Haven, CT: Yale University Press

Krakauer DC, Page KM, Erwin DH. 2009. Diversity, dilemmas, and monopolies of niche construction. The American Naturalist. 173(1):26–40

Kylafis G, Loreau M. 2011. Niche construction in the light of niche theory. Ecology Letters. 14(2): 82–90

Kylafis G, Loreau M. 2008. Ecological and evolutionary consequences of niche construction for its agent. Ecology Letters. 11(10):1072–81

La Reau AJ, Suen G. 2018. The Ruminococci: key symbionts
of the gut ecosystem. Journal of Microbiology. 56(3): 199–208

Laidre ME. 2012. Niche construction drives social dependence in hermit crabs. Current Biology. 22(20): R861-R863

Laidre ME. 2019. Architectural modification of shells by terrestrial hermit crabs alters social dynamics in later generations. Ecology. 100(9): e02767

Laland KN. 2017. Darwin’s Unfinished Symphony. How Culture Made the Human Mind. Princeton: Princeton University Press

Laland KN, Odling-Smee FJ, Feldman MW. 1996. The evolutionary consequences of niche construction: a theoretical investigation using two‐locus theory. Journal of Evolutionary Biology. 9(3): 293–316

Laland KN, Odling-Smee FJ, Feldman MW. 1999. Evolutionary consequences of niche construction and their implications for ecology. PNAS. 96(18):10242–47

Laland KN, Odling‐Smee J, Feldman MW. 2001. Cultural niche construction and human evolution. Journal of Evolutionary Biology. 14(1):22–33

 

Laland KN, Odling-Smee FJ, Gilbert SF. 2008. EvoDevo and niche construction: building bridges. Journal of Experimental Zoology Part B: Molecular and Developmental Evolution. 310B(7):549–66

 

Laland KN, Odling-Smee J, Myles S. 2010. How culture shaped the human genome: bringing genetics and the human sciences together. Nature Reviews Genetics. 11(2):137–48

Laland KN, Sterelny K, Odling-Smee FJ, Hoppitt W, Uller T. 2011. Cause and effect in biology revisited: is Mayr’s proximate-ultimate dichotomy still useful? Science. 334(6062):1512–16

Laland KN, Odling-Smee FJ, Hoppitt W, Uller T. 2012. More on how and why: cause and effect in biology revisited. Biology & Philosophy. 28(5):719–45

Laland KN, Uller T, Feldman MW, et al. 2014. Does evolutionary theory need a rethink? Yes, urgently. Nature. 514(7521): 161–164

Laland KN, Uller T, Feldman MW, Sterelny K, Müller GB, et al. 2015. The extended evolutionary synthesis: its structure, assumptions and predictions. Proc. R. Soc. B. 282(1813):20151019

Laland KN, Odling-Smee FJ, Feldman MW. 2019. Understanding niche construction as an evolutionary process. In Evolutionary Causation: Biological and Philosophical Reflections, ed. T Uller, KN Laland, pp. 127–52. Cambridge, MA: MIT Press

Laland KN, Toyokawa W, Oudman T. 2020. Animal learning as a source of developmental bias. Evolution & Development. 22(1–2):126–42

Laland KN, Boogert NJ. 2010. Niche construction, co-evolution and biodiversity. Ecological Economics. 69(4): 731–736

Laland KN, Sterelny K. 2006. Seven reasons (not) to neglect niche construction. Evolution. 60(9):1751–62

Lansing JS, Cox MP, Downey SS, Janssen M, Schoenfelder J. 2009. A robust budding model of Balinese water temple networks. World archaeology. 41(1):112–33

Lansing JS, Fox KM. 2011. Niche construction on Bali: the gods of the countryside. Philosophical Transactions of the Royal Society B: Biological Sciences. 366(1566):927–34

 

Lehmann L. 2007. The evolution of trans-generational altruism: kin selection meets niche construction. Journal of Evolutionary Biology. 20(1):181–189

Lehmann L. 2008. The adaptive dynamics of niche constructing traits in spatially subdivided populations: Evolving posthumous extended phenotypes. Evolution. 62(3):549–66

Lev-Yadun S, Katzir G, Ne’eman G. 2009. Rheum palaestinum, a self-irrigating desert plant. Naturwissenschaften 96(3): 393-397

Levins R, Lewontin RC. 1985. The Dialectical Biologist. Cambridge: Harvard University Press

Levis NA, Pfennig DW. 2020. Plasticity-led evolution: A survey of developmental mechanisms and empirical tests. Evolution & Development. 22(1–2):71–87

 

Lewontin R. 1970. The units of selection. Annual Review of Ecology and Systematics. 1(1):1–18

Lewontin R. 1982. Organism and environment. In Learning, Development and Culture, ed HC Plotkin, pp. 151–170. Chichester: Wiley

Lewontin R. 1983. Gene, organism, and environment. In Evolution: From Molecules to Men, ed DS Bendall, pp. 273–85. Cambridge: Cambridge University Press

Lewontin RC. 2000. The Triple Helix: Gene, Organism, and Environment. Cambridge: Harvard University Press

Ley RE, Peterson DA, Gordon JI. 2006. Ecological and evolutionary forces shaping microbial diversity in the human intestine. Cell. 124(4): 837–48

Lill JT, Marquis RJ. 2003. Ecosystem engineering by caterpillars increases insect herbivore diversity on white oak. Ecology. 84(3): 682–690

Matthews B, De Meester L, Jones CG, Iberlings BW, et al. 2014. Under niche construction: an operational bridge between ecology, evolution and ecosystem science. Ecological Monographs. 84(2): 245–263

Mayr E. 1961. Cause and effect in biology: kinds of causes, predictability, and teleology are viewed by a practicing biologist. Science. 134(3489):1501–6

Mayr E. 1980. Prologue: some thoughts on the history of the evolutionary synthesis. In The Evolutionary Synthesis: Perspectives on the Unification of Biology, ed E Mayr, W Provine, pp. 1–48. Cambridge: Harvard University Press

Mayr E. 1984. The triumph of the evolutionary synthesis. Times Literary Supplement 2 November, pp. 1261–1262

McFall‐Ngai MJ, Ruby EG. 1991. Symbiont recognition and subsequent morphogenesis as early events in an animal‐bacterial mutualism. Science. 254(5037): 1491–94

Montgomery MK, McFall‐Ngai M. 1994. Bacterial symbionts induce host organ morphogenesis during early postembryonic development of the squid Euprymna scolopes. Development. 120(7):1719–29

Morgan LH. 1868. The American Beaver and His Works. Philadelphia, PA: JB Lippincott

Naiman RJ, Johnston CA, Kelley JC. 1988. Alteration of North American streams by beaver. BioScience. 38(11): 753-62

Nyholm SV, Stabb EV, Ruby EG, et al. 2000. Establishment of an animal‐bacterial association: recruiting symbiotic vibrios from the environment. PNAS. 97(18): 10231–35

O’Brien M, Laland KN. 2012. Genes, culture and agriculture: an example of human niche construction. Current Anthropology. 53(4): 434-70

Odling-Smee FJ. 1988. Niche-constructing phenotypes. In The Role of Behavior in Evolution, ed HC Plotkin, pp. 73–132. Cambridge: The MIT Press

Odling-Smee FJ. 2010. Niche inheritance. In Evolution: The Extended Synthesis, ed M Pigliucci, G Müller, pp. 175–208. Cambridge: The MIT Press

Odling-Smee FJ, Laland KN, Feldman MW. 1996. Niche construction. The American Naturalist. 147(4):641–48

Odling-Smee FJ, Laland KN, Feldman MW. 2003. Niche Construction: The Neglected Process in Evolution. Princeton: Princeton University Press

Odling-Smee FJ, Erwin DH, Palkovacs EP, Feldman MW, Laland KN. 2013. Niche construction theory: a practical guide for ecologists. The Quarterly Review of Biology. 88(1):3–28

Odling-Smee J, Laland KN. 2012. Ecological inheritance and cultural inheritance: what are they and how do they differ? Biological Theory 6(3): 220–230

Oyama S. 1985. The Ontogeny of Information: Developmental Systems and Evolution. Duke University Press. 2nd ed.

Oyama S, Griffiths P, Gray RD, eds. 2001. Cycles of Contingency: Developmental Systems and Evolution. Cambridge: The MIT Press

Pigliucci M, Müller G, eds. 2010. Evolution: The Extended Synthesis. Cambridge: The MIT Press

Piperno DR. 2017. Assessing elements of an extended evolutionary synthesis for plant. PNAS. 114(25): 6429-6437

Post DM, Palkovacs EP. 2009. Eco-evolutionary feedbacks in community and ecosystem ecology: interactions between the ecological theatre and the evolutionary play. Philosophical Transactions of the Royal Society B: Biological Sciences. 364(1523):1629–40

 

Pringle RM. 2008. Elephants as agents of habitat creation for small vertebrates at the patch scale. Ecology. 89(1): 26–33

 

Quintus S, Cochrane EE. 2018. The prevalence and importance of niche construction in agricultural development in Polynesia. Journal of Anthropological Archaeology. 51:173–86

 

Roughgarden J, Gilbert SF, Rosenberg E, Zilber-Rosenberg I, Lloyd EA. 2018. Holobionts as units of selection and a model of their population dynamics and evolution. Biological Theory. 13(1): 44-65 

Round JL, Mazmanian SK. 2009. The gut microbiota shapes intestinal immune responses during health and disease. Nature Reviews Immunology. 9(5): 313–23

San Roman M, Wagner A. 2018. An enormous potential for niche construction through bacterial cross-feeding in a homogeneous environment. PLoS computational biology. 14:(7): e1006340

Schrödinger E. 1944. Reprinted 1967. What is Life? and Mind and Matter. Cambridge: Cambridge University Press 

Schwab DB, Riggs HE, Newton ILG, Moczek AP. 2016. Developmental and ecological benefits of the maternally transmitted microbiota in a dung beetle. The American Naturalist. 188(6): 679-82 

Schwab DB, Casasa S, Moczek AP. 2017. Evidence of developmental niche construction in dung beetles: effects on growth, scaling and reproductive success. Ecology Letters. 20(11): 1353–63
 

Schwilk D. 2003. Flammability is a niche construction trait: canopy architecture affects fire intensity. The American Naturalist. 162(6): 725-33 

Scott-Phillips TC, Laland KN, Shuker DM, Dickins TE, West SA. 2014. The niche construction perspective: a critical appraisal. Evolution. 68(5): 1231-43

Sender R, Fuchs S, Milo R. 2016. Revised estimates for the number of human and bacteria cells in the body. PLoS Biology. 14(8): e1002533

Shachak M, Jones CG, Granot Y. 1987. Herbivory in rocks and weathering of a desert. Science. 236(4805): 1098-99

Shaler N. 1892. Effects of animals and plants on soils. In Origin and Nature of Soils. 12th Annual Report, Director US Geol. Survey, Part J. Geology Annual Report, Sector of the Interior. Washington: Government Printing Office 

Silver M, Di Paolo EA. 2006. Spatial effects favour the evolution of niche construction. Theoretical population Biology. 70(4): 387-400 

Smith BD. 2007a. Niche construction and the behavioral context of plant and animal domestication. Evolutionary Anthropology. 16(5): 188–99

Smith BD. 2007b. The ultimate ecosystem engineers. Science. 315(5820): 1797-98

Smith BD. 2016. Neo-Darwinism, niche construction theory, and the initial domestication of plants and animals. Evolutionary Ecology. 30(2): 307–24 

Smith BD,  Zeder MA. 2013. The onset of the anthropocene. Anthropocene. 2013(4): 8-13

Sober E. 1984. The Nature of Selection: Evolutionary Theory in Philosophical Focus. Cambridge: MIT Press  

Spencer TE, Burhardt RC, Johnson GA, Bazer FW. 2004. Conceptus signals for establishment and maintenance of pregnancy. Animal Reproductive Science. 82(1): 537–50

Stappenbeck TS, Hooper LV, Gordon JI. 2002. Developmental regulation of intestinal angiogenesis by indigenous microbes via Paneth cells. PNAS. 99(24): 15451–55

Sterelny K. 2001. Niche construction, developmental systems, and the extended replicator. In Cycles of Contingency: Developmental Systems and Evolution, ed. Oyama, et al eds. Cambridge: MIT Press 

Sultan SE. 2015. Organism & environment: Ecological Development, Niche Construction, and Adaptation. Oxford: Oxford University Press

Tanaka MM, Godfrey-Smith P, Kerr B. 2020. The dual landscape model of adaptation and niche construction. Philosophy of Science. https://doi.org/10.1086/708692

Ten Cate C. 2000. How learning mechanisms might affect evolutionary processes. Trends in Ecology & Evolution.15(5): 179–81 

Thorogood R, Davies NB. 2012. Cuckoos combat socially transmitted defenses of reed warbler hosts with a plumage polymorphism. Science. 337(6094): 578–80  

Ticconi C, Belmonte A, Piccione E, Rao CH. 2006. Feto-placental communication system with the myometrium inpregnancy and parturition: the role of hormones, neuro- hormones, inflammatory mediators, and locally active factors. The Journal of Maternal Fetal and Neonatal Medicine. 19(3): 125–33

Tomlinson G. 2018. Culture and The Course of Human Evolution. Chicago: Chicago University Press 

Tomlinson G. 2015. A Million Years of Music: The Emergence of Human Modernity. The Emergence of Human Modernity. New York: Zone books 

Turner JS. 2000. The Extended Organism: The Physiology of Animal-built Structures. Cambridge: Harvard University Press  

Uller T, Feiner N, Radersma R, Jackson ISC, Rago A. 2020. Developmental plasticity and evolutionary explanations. Evolution and Development. 22(1-2): 47-55 

Uller T, Helanterä H. 2019. Niche construction and conceptual change in evolutionary biology. British Journal for the Philosophy of Science. 70(2): 351-75

Dyken JDV, Wade MJ. 2012. Origins of altruism diversity II: runaway coevolution of altruistic strategies via reciprocal niche construction. Evolution. 66(8): 498–2513

Waddington CH. 1957. The Strategy of the Genes: A Discussion of Some Aspects of Theoretical Biology. Oxon: Routledge 

Waddington CH. 1959. Evolutionary systems: animal and human. Nature. 183:1634-38

Walsh DM. 2015. Organism, Agency and Evolution. Cambridge: Cambridge University Press
 
 

Walsh DM. 2019. The Paradox of Population Thinking: First Order Causes and Higher Order Effects.In Evolutionary Causation: Biological and Philosophical Reflections, ed. T Uller, KN Laland, pp.227-46. Cambridge, MA: MIT Press

Ware IM, Fitzpatrick CR, Senthilnathan A, Bayliss SLJ, Beals KK, et al. 2019. Feedbacks link ecosystem ecology and evolution across spatial and temporal scales: Empirical evidence and future directions. Functional Ecology. 33(1):31–42

Waters CN, Zalasiewicz J, Summerhayes C, Barnosky AD, Poirier C, et al. 2016. The Anthropocene is functionally and stratigraphically distinct from the Holocene. Science. 351(6269): aad2622

West-Eberhard MJ. 2003. Developmental Plasticity and Evolution. Oxford: Oxford University Press 

Whitehead H, Laland KN, Rendell L, Thorogood R, Whiten A. 2019. The reach of gene-culture coevolution in animals. Nature Communications. 10: 2405 

Williams GC. 1966. Adaptation and Natural Selection: A Critique of Some Current Evolutionary Thought. Princeton: Princeton University Press 

Williams GC. 1992. Gaia, nature worship, and biocentric fallacies. Quarterly Review of Biology. 67(4): 479-86 

Williams JB, Lee Jr RE. 2005. Plant senescence cues entry into diapause in the gall fly Eurosta solidaginis: resulting metabolic depression is critical for water conservation. Journal of Experimental Biology. 208:4437–44

Wolf JB, Brodie III ED, Cheverud JM, Moore AJ, Wade MJ. 1998. Evolutionary consequences of indirect genetic effects. Trends in Ecology & Evolution. 13(2): 64–69

Wray GA, Hoekstra HE, Futuyma DJ, Lenski RE, et al. 2014. Does evolutionary theory need a rethink? No, all is well. Nature. 514(7521): 161-64 

Wright JP, Jones CJ, Flecker AS. 2002. An ecosystem engineer, the beaver, increases species richness at the landscape scale. Oecologia. 132(1): 96-101 

Xue C, Liu Z, Goldenfeld N. 2020. Scale-invariant topology and bursty branching of evolutionary trees emerge from niche construction. PNAS. 117(14): 7879–87

Xu J, Gordon JI. 2003. Honor thy symbionts. PNAS. 100(18):10452–59

Zeder MA. 2012. The broad spectrum revolution at 40: resource diversity, intensification, and an alternative to optimal foraging explanations. Journal of Anthropological Archaeology. 31(3): 241-64

Zeder MA. 2015. Core questions in domestication research. PNAS. 112(11): 3191-98 

Zeder MA. 2017. Domestication as a model system for the extended evolutionary synthesis. Interface Focus. 7(5): 2016013

Zeder MA. 2018. Why evolutionary biology needs anthropology: evaluating core assumptions of the extended evolutionary synthesis. Evolutionary Anthropology. 27(6): 267-84