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Ontogeny

May 08, 2023

This article concerns ontogeny in biology. Not to be confused with the philosophical concept ontology, or the medical terms oncology or odontology.

Ontogeny (also ontogenesis) is the origination and development of an organism (both physical and psychological, e.g., moral development[1]), usually from the time of fertilization of the egg to adult. The term can also be used to refer to the study of the entirety of an organism's lifespan.

The initial stages of human embryogenesis
Parts of a human embryo

Ontogeny is the developmental history of an organism within its own lifetime, as distinct from phylogeny, which refers to the evolutionary history of a species. Another way to think of ontogeny is that it is the process of an organism going through all of the developmental stages over its lifetime. The developmental history includes all the developmental events that occur during the existence of an organism, beginning with the changes in the egg at the time of fertilization and events from the time of birth or hatching and afterward (i.e., growth, remolding of body shape, development of secondary sexual characteristics, etc.).[2] While developmental (i.e., ontogenetic) processes can influence subsequent evolutionary (e.g., phylogenetic) processes[3] (see evolutionary developmental biology and recapitulation theory), individual organisms develop (ontogeny), while species evolve (phylogeny).

Ontogeny, embryology and developmental biology are closely related studies and those terms are sometimes used interchangeably. Aspects of ontogeny are morphogenesis, the development of form and shape of an organism; tissue growth; and cellular differentiation. The term ontogeny has also been used in cell biology to describe the development of various cell types within an organism.[4] Ontogeny is a useful field of study in many disciplines, including developmental biology, cell biology, genetics, developmental psychology, developmental cognitive neuroscience, and developmental psychobiology. Ontogeny is used in anthropology as the process through which each of us embodies the history of our own making.[5]

Etymology

The word ontogeny comes from the Greek on meaning a being, individual; and existence, and from the suffix -geny from the Greek -geniea, meaning genesis, origin, and mode of production.[6]

History

The term ontogeny was coined by Ernst Haeckel, a German zoologist and evolutionist in the 1860s. Haeckel, born in Germany on February 16, 1834, was also a strong supporter of Darwinism. Haeckel suggested that ontogeny briefly and sometimes incompletely recapitulated or repeated phylogeny in his 1866 book, Generelle Morphologie der Organismen ("General Morphology of Organisms"). Even though his book was widely read, the scientific community was not very convinced or interested in his ideas, so he turned to producing more publications to get more attention.[7] In 1866, Haeckel and others imagined development as producing new structures after earlier additions to the developing organism have been established. He proposed that individual development followed developmental stages of previous generations and that the future generations would add something new to this process, and that there was a causal parallelism between an animal's ontogeny and phylogeny. In addition, Haeckel suggested a biogenetic law that ontogeny recapitulates phylogeny, based on the idea that the successive and progressive origin of new species was based on the same laws as the successive and progressive origin of new embryonic structures. According to Haeckel, development produced novelties, and natural selection would eliminate species that had become outdated or obsolete. Though his view of development and evolution wasn't justifiable, future embryologists tweaked and collaborated with Haeckel's proposals and showed how new morphological structures can occur by the hereditary modification of embryonic development.[8][9] Marine biologist Walter Garstang reversed Haeckel's relationship between ontogeny and phylogeny, stating that ontogeny creates phylogeny, not recapitulates it.[10]

A seminal 1963 paper by Nikolaas Tinbergen named ontogeny as one of the four primary questions of biology, along with Julian Huxley's three others: causation, survival value and evolution.[11] Tinbergen emphasized that the change of behavioral machinery during development was distinct from the change in behavior during development. We can conclude that the thrush itself, i.e. its behavioral machinery, has changed only if the behavior change occurred while the environment was held constant...When we turn from description to causal analysis, and ask in what way the observed change in behavior machinery has been brought about, the natural first step is to try and distinguish between environmental influences and those within the animal...In ontogeny the conclusion that a certain change is internally controlled (is 'innate') is reached by elimination.[12] Tinbergen was concerned that the elimination of environmental factors is difficult to establish, and the use of the word innate is often misleading.

Developmental stages

Development of an organism happens through fertilization, cleavage, blastulation, gastrulation, organogenesis, and metamorphosis into an adult. Each species of animal has a slightly different journey through these stages, since some stages might be shorter or longer when compared to other species, and where the offspring develops is different for each animal type (e.g., in a hard egg shell, uterus, soft egg shell, on a plant leaf, etc.).[13]

Fertilization

In humans, the process of fetal development starts after sperm fertilizes an egg and they fuse together, kickstarting embryonic development. The fusion of egg and sperm into a zygote changes the surrounding membrane to not allow any more sperm to penetrate the egg, so multiple fertilizations can be prevented. Fusion of a zygote also activates the egg so it can begin undergoing cell division. Each animal species might not have specifically a sperm and an egg, but two gametes that contain half of the species' typical genetic material and the membranes of these gametes fuse to start creating an offspring.[14]

Cleavage

Not long after successful fertilization by sperm, the zygote undergoes many mitotic divisions, which are also non-sexual cell divisions. Cleavage is the process of cell division, so the starting zygote becomes a collection of identical cells which is a morula and contains cells called blastomeres.[15] Cleavage prepares the zygote to become an embryo, which is from 2 weeks to 8 weeks after conception (fertilization) in humans.[16]

 
Process of zygote to gastrula in development

Blastulation

After the zygote has become an embryo, it continues dividing into a hollow sphere of cells, which is a blastula. These outer cells form a single epithelial layer, the blastoderm, that essentially encases the fluid-filled inside that is the blastocoel. The figure to the right shows the basic process that is modified in different species. Blastulation differs slightly in different species, but in mammals, the eight-cell stage embryo forms into a slightly different type of blastula, called a blastocyst.[17] Other species such as sea stars, frogs, chicks, and mice have all the same structures in this stage, yet the orientation of these features differs, plus these species have additional types of cells in this stage.[18]

 
Blastula to gastrula more detailed

Gastrulation

After blastulation, the single-layered blastula expands and reorganizes into multiple layers, a gastrula (seen in the figure to the right). Reptiles, birds and mammals are triploblastic organisms, meaning the gastrula comprises three germ layers; the endoderm (inner layer), mesoderm (middle layer), and ectoderm (outer layer).[15] As seen in the figure below, each germ layer will become multi-potent stem cells that can become a specific tissue depending on the germ layer and is what happens in humans. This differentiation of germ layers differs slightly, because not all of the organs and tissues below are in all organisms, but corresponding body systems can be substituted in place of these.[19]

Organogenesis

In the figure below, human germ cells are able to differentiate into the specific organs and tissues they become later on in life. Germ cells are able to migrate to their final locations to rearrange themselves and some organs are made of two germ layers; one for the outside, the other for the inside.[20] The endoderm cells become the internal linings of organisms, such as the stomach, colon, small intestine, liver, and pancreas of the digestive system and the lungs. The mesoderm gives rise to other tissues not formed by the ectoderm, such as the heart, muscles, bones, blood, dermis of the skin, bone marrow, and the urogenital system. This germ layer is more specific for species, as it is the distinguishing layer of the three that can identify evolutionarily higher life-forms (e.g., bilateral organisms like humans) from lower-life forms (with radial symmetry). Lastly, the ectoderm is the outer layer of cells that become the epidermis and hair while being the precursor to the mammary glands, central nervous system, and the peripheral nervous systems.[21]

 
Germ layers and what tissues they become in humans
 
Ernst Haeckel, Anthropogenie.

The figure above shows how the development of a pig, cow, rabbit, and human offspring are similar when compared to one another. This figure shows how the germ layers can become different organs and tissues in evolutionarily higher life-forms and how these species essentially develop very similarly. Additionally, it shows how multiple species develop in a parallel manner but branch off to develop more specific features for the organism such as hooves, a tail, or ears.

 
Primary neurulation detailed

Neurulation

In developing vertebrate offspring, a neural tube is formed through either primary or secondary neurulation. Some species develop their spine and nervous system using both primary and secondary neurulation, while others use only primary or secondary neurulation.[22] In human fetal development, primary neurulation occurs during weeks 3 and 4 of gestation to develop the brain and spinal cord. Then during weeks 5 and 6 of gestation, secondary neurulation forms the lower sacral and coccygeal cord.[23]

Primary Neurulation

The diagram to the right illustrates primary neurulation, which is the process of cells surrounding the neural plate interacting with neural plate cells to proliferate, converge, and pinch off to form a hollow tube above the notochord and mesoderm. This process is discontinuous and can start at different points along the cranial-caudal axis necessary for it to close.[23] After the neural crest closes, the neural crest cells and ectoderm cells separate and the ectoderm becomes the epidermis surrounding this complex. The neural crest cells differentiate to become components of most of the peripheral nervous system in animals. Next, the notochord degenerates to become only the nucleus pulposus of the intervertebral discs and the mesoderm cells differentiate to become the somites and skeletal muscle later on. Also during this stage, the neural crest cells become the spinal ganglions, which function as the brain in organisms like earthworms and arthropods.[24] In more advanced organisms like amphibians, birds and mammals;[22] the spinal ganglions consists of a cluster of nerve bodies positioned along the spinal cord at the dorsal and ventral roots of a spinal nerve, which is a pair of nerves that correspond to a vertebra of the spine.[25]

Secondary Neurulation

In secondary neurulation, caudal and sacral regions of the spine are formed after primary neurulation is finished. This process initiates once primary neurulation is finished and the posterior neuropore closes, so the tail bud can proliferate and condense, then create a cavity and fuse with the central canal of the neural tube. Secondary neurulation occurs in the small region starting at the spinal tail bud up to the posterior neuropore, which is the open neural folds near the tail region that don't close through primary neurulation. As canalization progresses over the next few weeks, neurons and ependymal cells (cells that create cerebral spinal fluid[26]) differentiate to become the tail end of the spinal cord. Next, the closed neural tube contains neuroepithelial cells that immediately divide after closure and a second type of cell forms; the neuroblast. Neuroblast cells form the mantle layer, which later becomes the gray matter, which then gives rise to a marginal layer that becomes the white matter of the spinal cord.[23] Secondary neurulation is seen in the neural tube of the lumbar and tail vertebrae of frogs and chicks and in both instances, this process is like a continuation of gastrulation.[22]

 
Acraea zetes caterpillar to pupae to butterfly metamorphosis by Nick Hobgood

Larval and juvenile phases

In most species, the young organism that is just born or hatched is not sexually mature yet and in most animals, this young organism looks quite different than the adult form.[20] This young organism is the larva and is the intermediate form before metamorphosing into an adult.[27][8] A well known example of a larval form of an animal is the caterpillar of butterflies and moths. Caterpillars keep growing and feeding in order for enough energy during the pupal stage, when necessary body parts for metamorphosis are grown.[28] The juvenile phase is different in plants and animals, but in plants juvenility is an early phase of plant growth in which plants can't flower.[29] In animals, the juvenile stage is most commonly found in social mammals, such as wild dogs, monkeys, apes, lions, wolves, and more. In humans, puberty marks the end of this stage and adolescence follows. Some species begin puberty and reproduction before the juvenile stage is over, such as in female non-human primates.[30] The larval and pupal stages can be seen in the figure to the right.

Metamorphosis

The process of an organism's body undergoing structural and physical changes after birth or hatching to become suitable for its adult environment is metamorphosis.[31] For example, amphibian tadpoles have a maturation of liver enzymes, hemoglobin, and eye pigments, in addition to their nervous, digestive, and reproductive systems being remodeled.[32] In all species, molting and juvenile hormones appear to regulate these changes.[31] The figure to the right shows the stages of life in butterflies and their metamorphosis transforms the caterpillar into a butterfly.

Adulthood

Adulthood is the stage of when physical and intellectual maturity have been achieved and this differs between species. In humans, adulthood is thought to be around 20 or 21 years old and is the longest stage of life, but in all species it ends with death.[33] In dogs, small breeds (e.g., Yorkshire Terrier, Chihuahua, Cocker Spaniel, etc.) physically mature faster than large breeds (e.g., Saint Bernard, Great Dane, Golden Retriever, etc.), so adulthood is reached anywhere from 12 to 24 months or 1 to 2 years.[34] In contrast, many insect species have long larval stages and the adult stage is only for reproduction. The silkworm moths don't have mouthparts and don't feed, so they have to consume enough food during the larval stage for energy to survive and mate.[20]

Senescence

Senescence is when cells stop dividing but don't die, but these cells can build up and cause problems in the body. These cells can release substances that cause inflammation and can damage healthy nearby cells.[35] Senescence can be induced by un-repaired DNA damage (e.g., from radiation,[36] old age, etc.) or other cellular stress[37] and also is the state of being old.[38]

Ontogenetic allometry

Most organisms undergo allometric changes in shape as they grow and mature, while others engage in metamorphosis. Even reptiles (non-avian sauropsids, e.g., crocodilians, turtles, snakes,[39] and lizards[40]), in which the offspring are often viewed as miniature adults, show a variety of ontogenetic changes in morphology and physiology.[41]

Applications to other fields

Anthropology

Comparing ourselves to others is something humans do all the time. The chapter "Comparison and ontogeny" from the book Anthropology, by Comparison by Christina Toren states: In doing so we are acknowledging not so much our sameness to others or our difference, but rather the commonality that resides in our difference. In other words, because each one of us is at once remarkably similar to, and remarkably different from, all other humans, it makes little sense to think of comparison in terms of a list of absolute similarities and a list of absolute differences. Rather, in respect of all other humans, we find similarities in the ways we are different from one another and differences in the ways we are the same. That we are able to do this is a function of the genuinely historical process that is human ontogeny.[5]

See also

Notes and references

  1. ^ Tomasello, Michael (27 September 2018). "The Normative Turn in Early Moral Development". Human Development. 61 (4–5): 248–263. doi:10.1159/000492802. S2CID 149612818.
  2. ^ "ontogeny | biology | Britannica". www.britannica.com. Retrieved 18 February 2022.
  3. ^ Gould, S.J. (1977). Ontogeny and Phylogeny. Cambridge, Massachusetts: The Belknap Press of Harvard University Press
  4. ^ Thiery, Jean Paul (1 December 2003). "Epithelial–mesenchymal transitions in development and pathologies". Current Opinion in Cell Biology. 15 (6): 740–746. doi:10.1016/j.ceb.2003.10.006. PMID 14644200.
  5. ^ a b Toren, Christina. "Comparison and ontogeny." Anthropology, by comparison (2002): 187.
  6. ^ "ontogeny | Etymology, origin and meaning of ontogeny by etymonline". www.etymonline.com. Retrieved 5 March 2022.
  7. ^ Robinson, Gloria (12 February 2022). "Ernst Haeckel | German embryologist | Britannica". Encyclopedia Britannica. Retrieved 9 March 2022.
  8. ^ a b Gilbert, Scott F.; Epel, David (2015). Ecological Developmental Biology (2nd ed.). pp. 170–171. ISBN 978-1-60535-344-9.
  9. ^ Barnes, M. (3 May 2014). "Ernst Haeckel's Biogenetic Law (1866) | The Embryo Project Encyclopedia". embryo.asu.edu. Retrieved 7 April 2022.
  10. ^ Gilbert, Scott F.; Epel, David (2015). Ecological Developmental Biology (2nd ed.). Sinauer Associates, Inc. p. 357. ISBN 978-1-60535-344-9.
  11. ^ Niko Tinbergen (1963). "On aims and methods of ethology" (PDF). Zeitschrift für Tierpsychologie. 20 (4): 410–433. doi:10.1111/j.1439-0310.1963.tb01161.x. See page 411.
  12. ^ Foundations of animal behavior : classic papers with commentaries. Lynne D. Houck, Lee C. Drickamer, Animal Behavior Society. Chicago. 1996. ISBN 0-226-35456-3. OCLC 34321442.{{cite book}}: CS1 maint: others (link)
  13. ^ "Animal Life Cycles - Growth and Development of Organisms - Diagram (K-2)". www.exploringnature.org. Retrieved 9 April 2022.
  14. ^ "fertilization | Steps, Process, & Facts | Britannica". www.britannica.com. Retrieved 8 April 2022.
  15. ^ a b Muhr, Jeremy; Ackerman, Kristin M. (2022), "Embryology, Gastrulation", StatPearls, Treasure Island (FL): StatPearls Publishing, PMID 32119281, retrieved 8 April 2022
  16. ^ Gilbert, Scott F. (2000). "An Introduction to Early Developmental Processes". Developmental Biology. 6th Edition.
  17. ^ "blastula | biology | Britannica". www.britannica.com. Retrieved 8 April 2022.
  18. ^ "Blastulation | Cleavage and Early Development | Principles of Development | Continuity and Evolution of Animal Life". biocyclopedia.com. Retrieved 8 April 2022.
  19. ^ Leptin, Maria (1 March 2005). "Gastrulation Movements: the Logic and the Nuts and Bolts". Developmental Cell. 8 (3): 305–320. doi:10.1016/j.devcel.2005.02.007. ISSN 1534-5807. PMID 15737927.
  20. ^ a b c Gilbert, Scott F. (2000). "The Circle of Life: The Stages of Animal Development". Developmental Biology. 6th Edition.
  21. ^ "germ layer | Definition, Primary Layers, & Embryonic Development | Britannica". www.britannica.com. Retrieved 8 April 2022.
  22. ^ a b c Gilbert, Scott F. (2000). "Formation of the Neural Tube". Developmental Biology. 6th Edition.
  23. ^ a b c "Neurulation - an overview | ScienceDirect Topics". www.sciencedirect.com. Retrieved 9 April 2022.
  24. ^ "ganglion | physiology | Britannica". www.britannica.com. Retrieved 9 April 2022.
  25. ^ "spinal nerve | Definition, Function, Diagram, Number, & Facts | Britannica". www.britannica.com. Retrieved 9 April 2022.
  26. ^ "Ependymal Cells". medcell.med.yale.edu. Retrieved 10 April 2022.
  27. ^ "larva | Definition, Forms, & Facts | Britannica". www.britannica.com. Retrieved 25 April 2022.
  28. ^ "Butterfly Life Cycle". ansp.org. Retrieved 26 April 2022.
  29. ^ "Juvenility - an overview | ScienceDirect Topics". www.sciencedirect.com. Retrieved 25 April 2022.
  30. ^ "Juvenile Stage | Center for Academic Research and Training in Anthropogeny (CARTA)". carta.anthropogeny.org. Retrieved 25 April 2022.
  31. ^ a b "metamorphosis | biology | Britannica". www.britannica.com. Retrieved 26 April 2022.
  32. ^ Gilbert, Scott F. (2000). "Metamorphosis: The Hormonal Reactivation of Development". Developmental Biology. 6th Edition.
  33. ^ "adulthood | Britannica". www.britannica.com. Retrieved 28 April 2022.
  34. ^ Reisen, Jan (22 October 2021). "How Long Does Puppyhood Last?". American Kennel Club. Retrieved 28 April 2022.
  35. ^ "senescence". NCI's Dictionary of Cancer Terms. National Cancer Institute. 2 February 2011. Retrieved 28 April 2022.
  36. ^ Borrego-Soto, Gissela; Ortiz-López, Rocío; Rojas-Martínez, Augusto (2015). "Ionizing radiation-induced DNA injury and damage detection in patients with breast cancer". Genetics and Molecular Biology. 38 (4): 420–432. doi:10.1590/S1415-475738420150019. ISSN 1415-4757. PMC 4763322. PMID 26692152.
  37. ^ "Senescence - Latest research and news | Nature". www.nature.com. Retrieved 28 April 2022.
  38. ^ "Definition of SENESCENCE". www.merriam-webster.com. Retrieved 28 April 2022.
  39. ^ Pough, F. H. (1978). "Ontogenetic changes in endurance in water snakes (Natrix sipedon): Physiological correlates and ecological consequences". Copeia. 1978 (1): 69–75. doi:10.2307/1443823. JSTOR 1443823.
  40. ^ Garland, T. Jr. (1985). "Ontogenetic and individual variation in size, shape and speed in the Australian agamid lizard Amphibolurus nuchalis". Journal of Zoology. 207 (3): 425–439. CiteSeerX 10.1.1.211.1730. doi:10.1111/j.1469-7998.1985.tb04941.x.
  41. ^ Garland, T. Jr.; Else, P. L. (1987). "Seasonal, sexual, and individual variation in endurance and activity metabolism in lizards". American Journal of Physiology. Regulatory, Integrative and Comparative Physiology. 252 (3): R439–R449. doi:10.1152/ajpregu.1987.252.3.r439. PMID 3826408. S2CID 15804764.

External links

  •   Media related to Morphogenesis at Wikimedia Commons
  •   The dictionary definition of ontogeny at Wiktionary

May 08, 2023
ontogeny, this, article, concerns, ontogeny, biology, confused, with, philosophical, concept, ontology, medical, terms, oncology, odontology, also, ontogenesis, origination, development, organism, both, physical, psychological, moral, development, usually, fro. This article concerns ontogeny in biology Not to be confused with the philosophical concept ontology or the medical terms oncology or odontology Ontogeny also ontogenesis is the origination and development of an organism both physical and psychological e g moral development 1 usually from the time of fertilization of the egg to adult The term can also be used to refer to the study of the entirety of an organism s lifespan The initial stages of human embryogenesis Parts of a human embryo Ontogeny is the developmental history of an organism within its own lifetime as distinct from phylogeny which refers to the evolutionary history of a species Another way to think of ontogeny is that it is the process of an organism going through all of the developmental stages over its lifetime The developmental history includes all the developmental events that occur during the existence of an organism beginning with the changes in the egg at the time of fertilization and events from the time of birth or hatching and afterward i e growth remolding of body shape development of secondary sexual characteristics etc 2 While developmental i e ontogenetic processes can influence subsequent evolutionary e g phylogenetic processes 3 see evolutionary developmental biology and recapitulation theory individual organisms develop ontogeny while species evolve phylogeny Ontogeny embryology and developmental biology are closely related studies and those terms are sometimes used interchangeably Aspects of ontogeny are morphogenesis the development of form and shape of an organism tissue growth and cellular differentiation The term ontogeny has also been used in cell biology to describe the development of various cell types within an organism 4 Ontogeny is a useful field of study in many disciplines including developmental biology cell biology genetics developmental psychology developmental cognitive neuroscience and developmental psychobiology Ontogeny is used in anthropology as the process through which each of us embodies the history of our own making 5 Contents 1 Etymology 2 History 3 Developmental stages 3 1 Fertilization 3 2 Cleavage 3 3 Blastulation 3 4 Gastrulation 3 5 Organogenesis 3 5 1 Neurulation 3 5 1 1 Primary Neurulation 3 5 1 2 Secondary Neurulation 3 6 Larval and juvenile phases 3 7 Metamorphosis 3 8 Adulthood 3 8 1 Senescence 3 9 Ontogenetic allometry 4 Applications to other fields 4 1 Anthropology 5 See also 6 Notes and references 7 External linksEtymology EditThe word ontogeny comes from the Greek on meaning a being individual and existence and from the suffix geny from the Greek geniea meaning genesis origin and mode of production 6 History EditThe term ontogeny was coined by Ernst Haeckel a German zoologist and evolutionist in the 1860s Haeckel born in Germany on February 16 1834 was also a strong supporter of Darwinism Haeckel suggested that ontogeny briefly and sometimes incompletely recapitulated or repeated phylogeny in his 1866 book Generelle Morphologie der Organismen General Morphology of Organisms Even though his book was widely read the scientific community was not very convinced or interested in his ideas so he turned to producing more publications to get more attention 7 In 1866 Haeckel and others imagined development as producing new structures after earlier additions to the developing organism have been established He proposed that individual development followed developmental stages of previous generations and that the future generations would add something new to this process and that there was a causal parallelism between an animal s ontogeny and phylogeny In addition Haeckel suggested a biogenetic law that ontogeny recapitulates phylogeny based on the idea that the successive and progressive origin of new species was based on the same laws as the successive and progressive origin of new embryonic structures According to Haeckel development produced novelties and natural selection would eliminate species that had become outdated or obsolete Though his view of development and evolution wasn t justifiable future embryologists tweaked and collaborated with Haeckel s proposals and showed how new morphological structures can occur by the hereditary modification of embryonic development 8 9 Marine biologist Walter Garstang reversed Haeckel s relationship between ontogeny and phylogeny stating that ontogeny creates phylogeny not recapitulates it 10 A seminal 1963 paper by Nikolaas Tinbergen named ontogeny as one of the four primary questions of biology along with Julian Huxley s three others causation survival value and evolution 11 Tinbergen emphasized that the change of behavioral machinery during development was distinct from the change in behavior during development We can conclude that the thrush itself i e its behavioral machinery has changed only if the behavior change occurred while the environment was held constant When we turn from description to causal analysis and ask in what way the observed change in behavior machinery has been brought about the natural first step is to try and distinguish between environmental influences and those within the animal In ontogeny the conclusion that a certain change is internally controlled is innate is reached by elimination 12 Tinbergen was concerned that the elimination of environmental factors is difficult to establish and the use of the word innate is often misleading Developmental stages EditDevelopment of an organism happens through fertilization cleavage blastulation gastrulation organogenesis and metamorphosis into an adult Each species of animal has a slightly different journey through these stages since some stages might be shorter or longer when compared to other species and where the offspring develops is different for each animal type e g in a hard egg shell uterus soft egg shell on a plant leaf etc 13 Fertilization Edit In humans the process of fetal development starts after sperm fertilizes an egg and they fuse together kickstarting embryonic development The fusion of egg and sperm into a zygote changes the surrounding membrane to not allow any more sperm to penetrate the egg so multiple fertilizations can be prevented Fusion of a zygote also activates the egg so it can begin undergoing cell division Each animal species might not have specifically a sperm and an egg but two gametes that contain half of the species typical genetic material and the membranes of these gametes fuse to start creating an offspring 14 Cleavage Edit Not long after successful fertilization by sperm the zygote undergoes many mitotic divisions which are also non sexual cell divisions Cleavage is the process of cell division so the starting zygote becomes a collection of identical cells which is a morula and contains cells called blastomeres 15 Cleavage prepares the zygote to become an embryo which is from 2 weeks to 8 weeks after conception fertilization in humans 16 Process of zygote to gastrula in development Blastulation Edit After the zygote has become an embryo it continues dividing into a hollow sphere of cells which is a blastula These outer cells form a single epithelial layer the blastoderm that essentially encases the fluid filled inside that is the blastocoel The figure to the right shows the basic process that is modified in different species Blastulation differs slightly in different species but in mammals the eight cell stage embryo forms into a slightly different type of blastula called a blastocyst 17 Other species such as sea stars frogs chicks and mice have all the same structures in this stage yet the orientation of these features differs plus these species have additional types of cells in this stage 18 Blastula to gastrula more detailed Gastrulation Edit After blastulation the single layered blastula expands and reorganizes into multiple layers a gastrula seen in the figure to the right Reptiles birds and mammals are triploblastic organisms meaning the gastrula comprises three germ layers the endoderm inner layer mesoderm middle layer and ectoderm outer layer 15 As seen in the figure below each germ layer will become multi potent stem cells that can become a specific tissue depending on the germ layer and is what happens in humans This differentiation of germ layers differs slightly because not all of the organs and tissues below are in all organisms but corresponding body systems can be substituted in place of these 19 Organogenesis Edit In the figure below human germ cells are able to differentiate into the specific organs and tissues they become later on in life Germ cells are able to migrate to their final locations to rearrange themselves and some organs are made of two germ layers one for the outside the other for the inside 20 The endoderm cells become the internal linings of organisms such as the stomach colon small intestine liver and pancreas of the digestive system and the lungs The mesoderm gives rise to other tissues not formed by the ectoderm such as the heart muscles bones blood dermis of the skin bone marrow and the urogenital system This germ layer is more specific for species as it is the distinguishing layer of the three that can identify evolutionarily higher life forms e g bilateral organisms like humans from lower life forms with radial symmetry Lastly the ectoderm is the outer layer of cells that become the epidermis and hair while being the precursor to the mammary glands central nervous system and the peripheral nervous systems 21 Germ layers and what tissues they become in humans Ernst Haeckel Anthropogenie The figure above shows how the development of a pig cow rabbit and human offspring are similar when compared to one another This figure shows how the germ layers can become different organs and tissues in evolutionarily higher life forms and how these species essentially develop very similarly Additionally it shows how multiple species develop in a parallel manner but branch off to develop more specific features for the organism such as hooves a tail or ears Primary neurulation detailed Neurulation Edit In developing vertebrate offspring a neural tube is formed through either primary or secondary neurulation Some species develop their spine and nervous system using both primary and secondary neurulation while others use only primary or secondary neurulation 22 In human fetal development primary neurulation occurs during weeks 3 and 4 of gestation to develop the brain and spinal cord Then during weeks 5 and 6 of gestation secondary neurulation forms the lower sacral and coccygeal cord 23 Primary Neurulation Edit The diagram to the right illustrates primary neurulation which is the process of cells surrounding the neural plate interacting with neural plate cells to proliferate converge and pinch off to form a hollow tube above the notochord and mesoderm This process is discontinuous and can start at different points along the cranial caudal axis necessary for it to close 23 After the neural crest closes the neural crest cells and ectoderm cells separate and the ectoderm becomes the epidermis surrounding this complex The neural crest cells differentiate to become components of most of the peripheral nervous system in animals Next the notochord degenerates to become only the nucleus pulposus of the intervertebral discs and the mesoderm cells differentiate to become the somites and skeletal muscle later on Also during this stage the neural crest cells become the spinal ganglions which function as the brain in organisms like earthworms and arthropods 24 In more advanced organisms like amphibians birds and mammals 22 the spinal ganglions consists of a cluster of nerve bodies positioned along the spinal cord at the dorsal and ventral roots of a spinal nerve which is a pair of nerves that correspond to a vertebra of the spine 25 Secondary Neurulation Edit In secondary neurulation caudal and sacral regions of the spine are formed after primary neurulation is finished This process initiates once primary neurulation is finished and the posterior neuropore closes so the tail bud can proliferate and condense then create a cavity and fuse with the central canal of the neural tube Secondary neurulation occurs in the small region starting at the spinal tail bud up to the posterior neuropore which is the open neural folds near the tail region that don t close through primary neurulation As canalization progresses over the next few weeks neurons and ependymal cells cells that create cerebral spinal fluid 26 differentiate to become the tail end of the spinal cord Next the closed neural tube contains neuroepithelial cells that immediately divide after closure and a second type of cell forms the neuroblast Neuroblast cells form the mantle layer which later becomes the gray matter which then gives rise to a marginal layer that becomes the white matter of the spinal cord 23 Secondary neurulation is seen in the neural tube of the lumbar and tail vertebrae of frogs and chicks and in both instances this process is like a continuation of gastrulation 22 Acraea zetes caterpillar to pupae to butterfly metamorphosis by Nick Hobgood Larval and juvenile phases Edit In most species the young organism that is just born or hatched is not sexually mature yet and in most animals this young organism looks quite different than the adult form 20 This young organism is the larva and is the intermediate form before metamorphosing into an adult 27 8 A well known example of a larval form of an animal is the caterpillar of butterflies and moths Caterpillars keep growing and feeding in order for enough energy during the pupal stage when necessary body parts for metamorphosis are grown 28 The juvenile phase is different in plants and animals but in plants juvenility is an early phase of plant growth in which plants can t flower 29 In animals the juvenile stage is most commonly found in social mammals such as wild dogs monkeys apes lions wolves and more In humans puberty marks the end of this stage and adolescence follows Some species begin puberty and reproduction before the juvenile stage is over such as in female non human primates 30 The larval and pupal stages can be seen in the figure to the right Metamorphosis Edit The process of an organism s body undergoing structural and physical changes after birth or hatching to become suitable for its adult environment is metamorphosis 31 For example amphibian tadpoles have a maturation of liver enzymes hemoglobin and eye pigments in addition to their nervous digestive and reproductive systems being remodeled 32 In all species molting and juvenile hormones appear to regulate these changes 31 The figure to the right shows the stages of life in butterflies and their metamorphosis transforms the caterpillar into a butterfly Adulthood Edit Adulthood is the stage of when physical and intellectual maturity have been achieved and this differs between species In humans adulthood is thought to be around 20 or 21 years old and is the longest stage of life but in all species it ends with death 33 In dogs small breeds e g Yorkshire Terrier Chihuahua Cocker Spaniel etc physically mature faster than large breeds e g Saint Bernard Great Dane Golden Retriever etc so adulthood is reached anywhere from 12 to 24 months or 1 to 2 years 34 In contrast many insect species have long larval stages and the adult stage is only for reproduction The silkworm moths don t have mouthparts and don t feed so they have to consume enough food during the larval stage for energy to survive and mate 20 Senescence Edit Senescence is when cells stop dividing but don t die but these cells can build up and cause problems in the body These cells can release substances that cause inflammation and can damage healthy nearby cells 35 Senescence can be induced by un repaired DNA damage e g from radiation 36 old age etc or other cellular stress 37 and also is the state of being old 38 Ontogenetic allometry Edit Most organisms undergo allometric changes in shape as they grow and mature while others engage in metamorphosis Even reptiles non avian sauropsids e g crocodilians turtles snakes 39 and lizards 40 in which the offspring are often viewed as miniature adults show a variety of ontogenetic changes in morphology and physiology 41 Applications to other fields EditAnthropology Edit Comparing ourselves to others is something humans do all the time The chapter Comparison and ontogeny from the book Anthropology by Comparison by Christina Toren states In doing so we are acknowledging not so much our sameness to others or our difference but rather the commonality that resides in our difference In other words because each one of us is at once remarkably similar to and remarkably different from all other humans it makes little sense to think of comparison in terms of a list of absolute similarities and a list of absolute differences Rather in respect of all other humans we find similarities in the ways we are different from one another and differences in the ways we are the same That we are able to do this is a function of the genuinely historical process that is human ontogeny 5 See also EditDevelopmental biology Ernst Haeckel Genetics Recapitulation theory the idea that ontogeny recapitulates phylogeny Embryology Organogenesis Ontogeny psychoanalysis Phylogenetics Phylogeny psychoanalysis Apoptosis Evo devo evolutionary developmental biology Cellular differentiation Cell biology Nikolaas Tinbergen Metamorphosis Morphology Physiology Eco evo devo ecological evolutionary developmental biology Darwinism Fertilization Cleavage Blastulation Gastrulation Germ layers Neurulation Spinal cord Metamorphosis Larva Adulthood SenescenceNotes and references Edit Tomasello Michael 27 September 2018 The Normative Turn in Early Moral Development Human Development 61 4 5 248 263 doi 10 1159 000492802 S2CID 149612818 ontogeny biology Britannica www britannica com Retrieved 18 February 2022 Gould S J 1977 Ontogeny and Phylogeny Cambridge Massachusetts The Belknap Press of Harvard University Press Thiery Jean Paul 1 December 2003 Epithelial mesenchymal transitions in development and pathologies Current Opinion in Cell Biology 15 6 740 746 doi 10 1016 j ceb 2003 10 006 PMID 14644200 a b Toren Christina Comparison and ontogeny Anthropology by comparison 2002 187 ontogeny Etymology origin and meaning of ontogeny by etymonline www etymonline com Retrieved 5 March 2022 Robinson Gloria 12 February 2022 Ernst Haeckel German embryologist Britannica Encyclopedia Britannica Retrieved 9 March 2022 a b Gilbert Scott F Epel David 2015 Ecological Developmental Biology 2nd ed pp 170 171 ISBN 978 1 60535 344 9 Barnes M 3 May 2014 Ernst Haeckel s Biogenetic Law 1866 The Embryo Project Encyclopedia embryo asu edu Retrieved 7 April 2022 Gilbert Scott F Epel David 2015 Ecological Developmental Biology 2nd ed Sinauer Associates Inc p 357 ISBN 978 1 60535 344 9 Niko Tinbergen 1963 On aims and methods of ethology PDF Zeitschrift fur Tierpsychologie 20 4 410 433 doi 10 1111 j 1439 0310 1963 tb01161 x See page 411 Foundations of animal behavior classic papers with commentaries Lynne D Houck Lee C Drickamer Animal Behavior Society Chicago 1996 ISBN 0 226 35456 3 OCLC 34321442 a href Template Cite book html title Template Cite book cite book a CS1 maint others link Animal Life Cycles Growth and Development of Organisms Diagram K 2 www exploringnature org Retrieved 9 April 2022 fertilization Steps Process amp Facts Britannica www britannica com Retrieved 8 April 2022 a b Muhr Jeremy Ackerman Kristin M 2022 Embryology Gastrulation StatPearls Treasure Island FL StatPearls Publishing PMID 32119281 retrieved 8 April 2022 Gilbert Scott F 2000 An Introduction to Early Developmental Processes Developmental Biology 6th Edition blastula biology Britannica www britannica com Retrieved 8 April 2022 Blastulation Cleavage and Early Development Principles of Development Continuity and Evolution of Animal Life biocyclopedia com Retrieved 8 April 2022 Leptin Maria 1 March 2005 Gastrulation Movements the Logic and the Nuts and Bolts Developmental Cell 8 3 305 320 doi 10 1016 j devcel 2005 02 007 ISSN 1534 5807 PMID 15737927 a b c Gilbert Scott F 2000 The Circle of Life The Stages of Animal Development Developmental Biology 6th Edition germ layer Definition Primary Layers amp Embryonic Development Britannica www britannica com Retrieved 8 April 2022 a b c Gilbert Scott F 2000 Formation of the Neural Tube Developmental Biology 6th Edition a b c Neurulation an overview ScienceDirect Topics www sciencedirect com Retrieved 9 April 2022 ganglion physiology Britannica www britannica com Retrieved 9 April 2022 spinal nerve Definition Function Diagram Number amp Facts Britannica www britannica com Retrieved 9 April 2022 Ependymal Cells medcell med yale edu Retrieved 10 April 2022 larva Definition Forms amp Facts Britannica www britannica com Retrieved 25 April 2022 Butterfly Life Cycle ansp org Retrieved 26 April 2022 Juvenility an overview ScienceDirect Topics www sciencedirect com Retrieved 25 April 2022 Juvenile Stage Center for Academic Research and Training in Anthropogeny CARTA carta anthropogeny org Retrieved 25 April 2022 a b metamorphosis biology Britannica www britannica com Retrieved 26 April 2022 Gilbert Scott F 2000 Metamorphosis The Hormonal Reactivation of Development Developmental Biology 6th Edition adulthood Britannica www britannica com Retrieved 28 April 2022 Reisen Jan 22 October 2021 How Long Does Puppyhood Last American Kennel Club Retrieved 28 April 2022 senescence NCI s Dictionary of Cancer Terms National Cancer Institute 2 February 2011 Retrieved 28 April 2022 Borrego Soto Gissela Ortiz Lopez Rocio Rojas Martinez Augusto 2015 Ionizing radiation induced DNA injury and damage detection in patients with breast cancer Genetics and Molecular Biology 38 4 420 432 doi 10 1590 S1415 475738420150019 ISSN 1415 4757 PMC 4763322 PMID 26692152 Senescence Latest research and news Nature www nature com Retrieved 28 April 2022 Definition of SENESCENCE www merriam webster com Retrieved 28 April 2022 Pough F H 1978 Ontogenetic changes in endurance in water snakes Natrix sipedon Physiological correlates and ecological consequences Copeia 1978 1 69 75 doi 10 2307 1443823 JSTOR 1443823 Garland T Jr 1985 Ontogenetic and individual variation in size shape and speed in the Australian agamid lizard Amphibolurus nuchalis Journal of Zoology 207 3 425 439 CiteSeerX 10 1 1 211 1730 doi 10 1111 j 1469 7998 1985 tb04941 x Garland T Jr Else P L 1987 Seasonal sexual and individual variation in endurance and activity metabolism in lizards American Journal of Physiology Regulatory Integrative and Comparative Physiology 252 3 R439 R449 doi 10 1152 ajpregu 1987 252 3 r439 PMID 3826408 S2CID 15804764 External links Edit Media related to Morphogenesis at Wikimedia Commons The dictionary definition of ontogeny at Wiktionary Portal Biology Retrieved from https en wikipedia org w index php title Ontogeny amp oldid 1148454417, wikipedia, wiki, book, books, library,

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