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Developmental biology

October 10, 2023

For the journal, see Developmental Biology (journal).

Developmental biology is the study of the process by which animals and plants grow and develop. Developmental biology also encompasses the biology of regeneration, asexual reproduction, metamorphosis, and the growth and differentiation of stem cells in the adult organism.

Perspectives Edit

The main processes involved in the embryonic development of animals are: tissue patterning (via regional specification and patterned cell differentiation); tissue growth; and tissue morphogenesis.

  • Regional specification refers to the processes that create the spatial patterns in a ball or sheet of initially similar cells. This generally involves the action of cytoplasmic determinants, located within parts of the fertilized egg, and of inductive signals emitted from signaling centers in the embryo. The early stages of regional specification do not generate functional differentiated cells, but cell populations committed to developing to a specific region or part of the organism. These are defined by the expression of specific combinations of transcription factors.
  • Cell differentiation relates specifically to the formation of functional cell types such as nerve, muscle, secretory epithelia, etc. Differentiated cells contain large amounts of specific proteins associated with cell function.
  • Morphogenesis relates to the formation of a three-dimensional shape. It mainly involves the orchestrated movements of cell sheets and of individual cells. Morphogenesis is important for creating the three germ layers of the early embryo (ectoderm, mesoderm, and endoderm) and for building up complex structures during organ development.
  • Tissue growth involves both an overall increase in tissue size, and also the differential growth of parts (allometry) which contributes to morphogenesis. Growth mostly occurs through cell proliferation but also through changes in cell size or the deposition of extracellular materials.

The development of plants involves similar processes to that of animals. However, plant cells are mostly immotile so morphogenesis is achieved by differential growth, without cell movements. Also, the inductive signals and the genes involved are different from those that control animal development.

Developmental processes Edit

Cell differentiation Edit

 
The Notch-delta system in neurogenesis (Slack Essential Dev Biol Fig 14.12a)

Cell differentiation is the process whereby different functional cell types arise in development. For example, neurons, muscle fibers and hepatocytes (liver cells) are well known types of differentiated cells. Differentiated cells usually produce large amounts of a few proteins that are required for their specific function and this gives them the characteristic appearance that enables them to be recognized under the light microscope. The genes encoding these proteins are highly active. Typically their chromatin structure is very open, allowing access for the transcription enzymes, and specific transcription factors bind to regulatory sequences in the DNA in order to activate gene expression.[1][2] For example, NeuroD is a key transcription factor for neuronal differentiation, myogenin for muscle differentiation, and HNF4 for hepatocyte differentiation. Cell differentiation is usually the final stage of development, preceded by several states of commitment which are not visibly differentiated. A single tissue, formed from a single type of progenitor cell or stem cell, often consists of several differentiated cell types. Control of their formation involves a process of lateral inhibition,[3] based on the properties of the Notch signaling pathway.[4] For example, in the neural plate of the embryo this system operates to generate a population of neuronal precursor cells in which NeuroD is highly expressed.

Regeneration Edit

Regeneration indicates the ability to regrow a missing part.[5] This is very prevalent amongst plants, which show continuous growth, and also among colonial animals such as hydroids and ascidians. But most interest by developmental biologists has been shown in the regeneration of parts in free living animals. In particular four models have been the subject of much investigation. Two of these have the ability to regenerate whole bodies: Hydra, which can regenerate any part of the polyp from a small fragment,[6] and planarian worms, which can usually regenerate both heads and tails.[7] Both of these examples have continuous cell turnover fed by stem cells and, at least in planaria, at least some of the stem cells have been shown to be pluripotent.[8] The other two models show only distal regeneration of appendages. These are the insect appendages, usually the legs of hemimetabolous insects such as the cricket,[9] and the limbs of urodele amphibians.[10] Considerable information is now available about amphibian limb regeneration and it is known that each cell type regenerates itself, except for connective tissues where there is considerable interconversion between cartilage, dermis and tendons. In terms of the pattern of structures, this is controlled by a re-activation of signals active in the embryo. There is still debate about the old question of whether regeneration is a "pristine" or an "adaptive" property.[11] If the former is the case, with improved knowledge, we might expect to be able to improve regenerative ability in humans. If the latter, then each instance of regeneration is presumed to have arisen by natural selection in circumstances particular to the species, so no general rules would be expected.

Embryonic development of animals Edit

Main article: Embryogenesis
 
Generalized scheme of embryonic development. Slack "Essential Developmental Biology". Fig. 2.8.
 
The initial stages of human embryogenesis

The sperm and egg fuse in the process of fertilization to form a fertilized egg, or zygote.[12] This undergoes a period of divisions to form a ball or sheet of similar cells called a blastula or blastoderm. These cell divisions are usually rapid with no growth so the daughter cells are half the size of the mother cell and the whole embryo stays about the same size. They are called cleavage divisions.

Mouse epiblast primordial germ cells (see Figure: “The initial stages of human embryogenesis”) undergo extensive epigenetic reprogramming.[13] This process involves genome-wide DNA demethylation, chromatin reorganization and epigenetic imprint erasure leading to totipotency.[13] DNA demethylation is carried out by a process that utilizes the DNA base excision repair pathway.[14]

Morphogenetic movements convert the cell mass into a three layered structure consisting of multicellular sheets called ectoderm, mesoderm and endoderm. These sheets are known as germ layers. This is the process of gastrulation. During cleavage and gastrulation the first regional specification events occur. In addition to the formation of the three germ layers themselves, these often generate extraembryonic structures, such as the mammalian placenta, needed for support and nutrition of the embryo,[15] and also establish differences of commitment along the anteroposterior axis (head, trunk and tail).[16]

Regional specification is initiated by the presence of cytoplasmic determinants in one part of the zygote. The cells that contain the determinant become a signaling center and emit an inducing factor. Because the inducing factor is produced in one place, diffuses away, and decays, it forms a concentration gradient, high near the source cells and low further away.[17][18] The remaining cells of the embryo, which do not contain the determinant, are competent to respond to different concentrations by upregulating specific developmental control genes. This results in a series of zones becoming set up, arranged at progressively greater distance from the signaling center. In each zone a different combination of developmental control genes is upregulated.[19] These genes encode transcription factors which upregulate new combinations of gene activity in each region. Among other functions, these transcription factors control expression of genes conferring specific adhesive and motility properties on the cells in which they are active. Because of these different morphogenetic properties, the cells of each germ layer move to form sheets such that the ectoderm ends up on the outside, mesoderm in the middle, and endoderm on the inside.[20][21]

 
Schema of the development of the axial twist in vertebrates.

Morphogenetic movements not only change the shape and structure of the embryo, but by bringing cell sheets into new spatial relationships they also make possible new phases of signaling and response between them. In addition, first morphogenetic movements of embryogenesis, such as gastrulation, epiboly and twisting, directly activate pathways involved in endomesoderm specification through mechanotransduction processes.[22][23] This property was suggested to be evolutionary inherited from endomesoderm specification as mechanically stimulated by marine environmental hydrodynamic flow in first animal organisms (first metazoa).[24] Twisting along the body axis by a left-handed chirality is found in all chordates (including vertebrates) and is addressed by the Axial Twist theory.[25]

Growth in embryos is mostly autonomous.[26] For each territory of cells the growth rate is controlled by the combination of genes that are active. Free-living embryos do not grow in mass as they have no external food supply. But embryos fed by a placenta or extraembryonic yolk supply can grow very fast, and changes to relative growth rate between parts in these organisms help to produce the final overall anatomy.

The whole process needs to be coordinated in time and how this is controlled is not understood. There may be a master clock able to communicate with all parts of the embryo that controls the course of events, or timing may depend simply on local causal sequences of events.[27]

Metamorphosis Edit

Developmental processes are very evident during the process of metamorphosis. This occurs in various types of animal. Well-known examples are seen in frogs, which usually hatch as a tadpole and metamorphoses to an adult frog, and certain insects which hatch as a larva and then become remodeled to the adult form during a pupal stage.

All the developmental processes listed above occur during metamorphosis. Examples that have been especially well studied include tail loss and other changes in the tadpole of the frog Xenopus,[28][29] and the biology of the imaginal discs, which generate the adult body parts of the fly Drosophila melanogaster.[30][31]

Plant development Edit

Further information: Plant development

Plant development is the process by which structures originate and mature as a plant grows. It is studied in plant anatomy and plant physiology as well as plant morphology.

Plants constantly produce new tissues and structures throughout their life from meristems[32] located at the tips of organs, or between mature tissues. Thus, a living plant always has embryonic tissues. By contrast, an animal embryo will very early produce all of the body parts that it will ever have in its life. When the animal is born (or hatches from its egg), it has all its body parts and from that point will only grow larger and more mature.

The properties of organization seen in a plant are emergent properties which are more than the sum of the individual parts. "The assembly of these tissues and functions into an integrated multicellular organism yields not only the characteristics of the separate parts and processes but also quite a new set of characteristics which would not have been predictable on the basis of examination of the separate parts."[33]

Growth Edit

A vascular plant begins from a single celled zygote, formed by fertilisation of an egg cell by a sperm cell. From that point, it begins to divide to form a plant embryo through the process of embryogenesis. As this happens, the resulting cells will organize so that one end becomes the first root, while the other end forms the tip of the shoot. In seed plants, the embryo will develop one or more "seed leaves" (cotyledons). By the end of embryogenesis, the young plant will have all the parts necessary to begin its life.

Once the embryo germinates from its seed or parent plant, it begins to produce additional organs (leaves, stems, and roots) through the process of organogenesis. New roots grow from root meristems located at the tip of the root, and new stems and leaves grow from shoot meristems located at the tip of the shoot.[34] Branching occurs when small clumps of cells left behind by the meristem, and which have not yet undergone cellular differentiation to form a specialized tissue, begin to grow as the tip of a new root or shoot. Growth from any such meristem at the tip of a root or shoot is termed primary growth and results in the lengthening of that root or shoot. Secondary growth results in widening of a root or shoot from divisions of cells in a cambium.[35]

In addition to growth by cell division, a plant may grow through cell elongation.[36] This occurs when individual cells or groups of cells grow longer. Not all plant cells will grow to the same length. When cells on one side of a stem grow longer and faster than cells on the other side, the stem will bend to the side of the slower growing cells as a result. This directional growth can occur via a plant's response to a particular stimulus, such as light (phototropism), gravity (gravitropism), water, (hydrotropism), and physical contact (thigmotropism).

Plant growth and development are mediated by specific plant hormones and plant growth regulators (PGRs) (Ross et al. 1983).[37] Endogenous hormone levels are influenced by plant age, cold hardiness, dormancy, and other metabolic conditions; photoperiod, drought, temperature, and other external environmental conditions; and exogenous sources of PGRs, e.g., externally applied and of rhizospheric origin.

Morphological variation Edit

Plants exhibit natural variation in their form and structure. While all organisms vary from individual to individual, plants exhibit an additional type of variation. Within a single individual, parts are repeated which may differ in form and structure from other similar parts. This variation is most easily seen in the leaves of a plant, though other organs such as stems and flowers may show similar variation. There are three primary causes of this variation: positional effects, environmental effects, and juvenility.

Evolution of plant morphology Edit

Transcription factors and transcriptional regulatory networks play key roles in plant morphogenesis and their evolution. During plant landing, many novel transcription factor families emerged and are preferentially wired into the networks of multicellular development, reproduction, and organ development, contributing to more complex morphogenesis of land plants.[38]

Most land plants share a common ancestor, multicellular algae. An example of the evolution of plant morphology is seen in charophytes. Studies have shown that charophytes have traits that are homologous to land plants. There are two main theories of the evolution of plant morphology, these theories are the homologous theory and the antithetic theory. The commonly accepted theory for the evolution of plant morphology is the antithetic theory. The antithetic theory states that the multiple mitotic divisions that take place before meiosis, cause the development of the sporophyte. Then the sporophyte will development as an independent organism.[39]

Developmental model organisms Edit

Much of developmental biology research in recent decades has focused on the use of a small number of model organisms. It has turned out that there is much conservation of developmental mechanisms across the animal kingdom. In early development different vertebrate species all use essentially the same inductive signals and the same genes encoding regional identity. Even invertebrates use a similar repertoire of signals and genes although the body parts formed are significantly different. Model organisms each have some particular experimental advantages which have enabled them to become popular among researchers. In one sense they are "models" for the whole animal kingdom, and in another sense they are "models" for human development, which is difficult to study directly for both ethical and practical reasons. Model organisms have been most useful for elucidating the broad nature of developmental mechanisms. The more detail is sought, the more they differ from each other and from humans.

Plants Edit

Vertebrates Edit

  • Frog: Xenopus[40] (X. laevis and X. tropicalis).[41][42] Good embryo supply. Especially suitable for microsurgery.
  • Zebrafish: Danio rerio.[43] Good embryo supply. Well developed genetics.
  • Chicken: Gallus gallus.[44] Early stages similar to mammal, but microsurgery easier. Low cost.
  • Mouse: Mus musculus.[45] A mammal[40] with well developed genetics.

Invertebrates Edit

Unicellular Edit

Others Edit

Also popular for some purposes have been sea urchins[48][40] and ascidians.[49] For studies of regeneration urodele amphibians such as the axolotl Ambystoma mexicanum are used,[50] and also planarian worms such as Schmidtea mediterranea.[7] Organoids have also been demonstrated as an efficient model for development.[51] Plant development has focused on the thale cress Arabidopsis thaliana as a model organism.[52]...

See also Edit

References Edit

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Further reading Edit

  • Gilbert SF (2013). Developmental Biology. Sunderland, Mass.: Sinauer Associates Inc.
  • Slack JM (2013). Essential Developmental Biology. Oxford: Wiley-Blackwell.
  • Wolpert L, Tickle C (2011). Principles of Development. Oxford and New York: Oxford University Press.

External links Edit

 
Wikibooks has more on the topic of: Developmental biology
 
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October 10, 2023
developmental, biology, journal, developmental, biology, journal, study, process, which, animals, plants, grow, develop, also, encompasses, biology, regeneration, asexual, reproduction, metamorphosis, growth, differentiation, stem, cells, adult, organism, cont. For the journal see Developmental Biology journal Developmental biology is the study of the process by which animals and plants grow and develop Developmental biology also encompasses the biology of regeneration asexual reproduction metamorphosis and the growth and differentiation of stem cells in the adult organism Contents 1 Perspectives 2 Developmental processes 2 1 Cell differentiation 2 2 Regeneration 3 Embryonic development of animals 3 1 Metamorphosis 4 Plant development 4 1 Growth 4 2 Morphological variation 4 3 Evolution of plant morphology 5 Developmental model organisms 5 1 Plants 5 2 Vertebrates 5 3 Invertebrates 5 4 Unicellular 5 5 Others 6 See also 7 References 8 Further reading 9 External linksPerspectives EditThe main processes involved in the embryonic development of animals are tissue patterning via regional specification and patterned cell differentiation tissue growth and tissue morphogenesis Regional specification refers to the processes that create the spatial patterns in a ball or sheet of initially similar cells This generally involves the action of cytoplasmic determinants located within parts of the fertilized egg and of inductive signals emitted from signaling centers in the embryo The early stages of regional specification do not generate functional differentiated cells but cell populations committed to developing to a specific region or part of the organism These are defined by the expression of specific combinations of transcription factors Cell differentiation relates specifically to the formation of functional cell types such as nerve muscle secretory epithelia etc Differentiated cells contain large amounts of specific proteins associated with cell function Morphogenesis relates to the formation of a three dimensional shape It mainly involves the orchestrated movements of cell sheets and of individual cells Morphogenesis is important for creating the three germ layers of the early embryo ectoderm mesoderm and endoderm and for building up complex structures during organ development Tissue growth involves both an overall increase in tissue size and also the differential growth of parts allometry which contributes to morphogenesis Growth mostly occurs through cell proliferation but also through changes in cell size or the deposition of extracellular materials The development of plants involves similar processes to that of animals However plant cells are mostly immotile so morphogenesis is achieved by differential growth without cell movements Also the inductive signals and the genes involved are different from those that control animal development Developmental processes EditCell differentiation Edit nbsp The Notch delta system in neurogenesis Slack Essential Dev Biol Fig 14 12a Cell differentiation is the process whereby different functional cell types arise in development For example neurons muscle fibers and hepatocytes liver cells are well known types of differentiated cells Differentiated cells usually produce large amounts of a few proteins that are required for their specific function and this gives them the characteristic appearance that enables them to be recognized under the light microscope The genes encoding these proteins are highly active Typically their chromatin structure is very open allowing access for the transcription enzymes and specific transcription factors bind to regulatory sequences in the DNA in order to activate gene expression 1 2 For example NeuroD is a key transcription factor for neuronal differentiation myogenin for muscle differentiation and HNF4 for hepatocyte differentiation Cell differentiation is usually the final stage of development preceded by several states of commitment which are not visibly differentiated A single tissue formed from a single type of progenitor cell or stem cell often consists of several differentiated cell types Control of their formation involves a process of lateral inhibition 3 based on the properties of the Notch signaling pathway 4 For example in the neural plate of the embryo this system operates to generate a population of neuronal precursor cells in which NeuroD is highly expressed Regeneration Edit Regeneration indicates the ability to regrow a missing part 5 This is very prevalent amongst plants which show continuous growth and also among colonial animals such as hydroids and ascidians But most interest by developmental biologists has been shown in the regeneration of parts in free living animals In particular four models have been the subject of much investigation Two of these have the ability to regenerate whole bodies Hydra which can regenerate any part of the polyp from a small fragment 6 and planarian worms which can usually regenerate both heads and tails 7 Both of these examples have continuous cell turnover fed by stem cells and at least in planaria at least some of the stem cells have been shown to be pluripotent 8 The other two models show only distal regeneration of appendages These are the insect appendages usually the legs of hemimetabolous insects such as the cricket 9 and the limbs of urodele amphibians 10 Considerable information is now available about amphibian limb regeneration and it is known that each cell type regenerates itself except for connective tissues where there is considerable interconversion between cartilage dermis and tendons In terms of the pattern of structures this is controlled by a re activation of signals active in the embryo There is still debate about the old question of whether regeneration is a pristine or an adaptive property 11 If the former is the case with improved knowledge we might expect to be able to improve regenerative ability in humans If the latter then each instance of regeneration is presumed to have arisen by natural selection in circumstances particular to the species so no general rules would be expected Embryonic development of animals EditMain article Embryogenesis nbsp Generalized scheme of embryonic development Slack Essential Developmental Biology Fig 2 8 nbsp The initial stages of human embryogenesisThe sperm and egg fuse in the process of fertilization to form a fertilized egg or zygote 12 This undergoes a period of divisions to form a ball or sheet of similar cells called a blastula or blastoderm These cell divisions are usually rapid with no growth so the daughter cells are half the size of the mother cell and the whole embryo stays about the same size They are called cleavage divisions Mouse epiblast primordial germ cells see Figure The initial stages of human embryogenesis undergo extensive epigenetic reprogramming 13 This process involves genome wide DNA demethylation chromatin reorganization and epigenetic imprint erasure leading to totipotency 13 DNA demethylation is carried out by a process that utilizes the DNA base excision repair pathway 14 Morphogenetic movements convert the cell mass into a three layered structure consisting of multicellular sheets called ectoderm mesoderm and endoderm These sheets are known as germ layers This is the process of gastrulation During cleavage and gastrulation the first regional specification events occur In addition to the formation of the three germ layers themselves these often generate extraembryonic structures such as the mammalian placenta needed for support and nutrition of the embryo 15 and also establish differences of commitment along the anteroposterior axis head trunk and tail 16 Regional specification is initiated by the presence of cytoplasmic determinants in one part of the zygote The cells that contain the determinant become a signaling center and emit an inducing factor Because the inducing factor is produced in one place diffuses away and decays it forms a concentration gradient high near the source cells and low further away 17 18 The remaining cells of the embryo which do not contain the determinant are competent to respond to different concentrations by upregulating specific developmental control genes This results in a series of zones becoming set up arranged at progressively greater distance from the signaling center In each zone a different combination of developmental control genes is upregulated 19 These genes encode transcription factors which upregulate new combinations of gene activity in each region Among other functions these transcription factors control expression of genes conferring specific adhesive and motility properties on the cells in which they are active Because of these different morphogenetic properties the cells of each germ layer move to form sheets such that the ectoderm ends up on the outside mesoderm in the middle and endoderm on the inside 20 21 nbsp Schema of the development of the axial twist in vertebrates Morphogenetic movements not only change the shape and structure of the embryo but by bringing cell sheets into new spatial relationships they also make possible new phases of signaling and response between them In addition first morphogenetic movements of embryogenesis such as gastrulation epiboly and twisting directly activate pathways involved in endomesoderm specification through mechanotransduction processes 22 23 This property was suggested to be evolutionary inherited from endomesoderm specification as mechanically stimulated by marine environmental hydrodynamic flow in first animal organisms first metazoa 24 Twisting along the body axis by a left handed chirality is found in all chordates including vertebrates and is addressed by the Axial Twist theory 25 Growth in embryos is mostly autonomous 26 For each territory of cells the growth rate is controlled by the combination of genes that are active Free living embryos do not grow in mass as they have no external food supply But embryos fed by a placenta or extraembryonic yolk supply can grow very fast and changes to relative growth rate between parts in these organisms help to produce the final overall anatomy The whole process needs to be coordinated in time and how this is controlled is not understood There may be a master clock able to communicate with all parts of the embryo that controls the course of events or timing may depend simply on local causal sequences of events 27 Metamorphosis Edit Developmental processes are very evident during the process of metamorphosis This occurs in various types of animal Well known examples are seen in frogs which usually hatch as a tadpole and metamorphoses to an adult frog and certain insects which hatch as a larva and then become remodeled to the adult form during a pupal stage All the developmental processes listed above occur during metamorphosis Examples that have been especially well studied include tail loss and other changes in the tadpole of the frog Xenopus 28 29 and the biology of the imaginal discs which generate the adult body parts of the fly Drosophila melanogaster 30 31 Plant development EditFurther information Plant development Plant development is the process by which structures originate and mature as a plant grows It is studied in plant anatomy and plant physiology as well as plant morphology Plants constantly produce new tissues and structures throughout their life from meristems 32 located at the tips of organs or between mature tissues Thus a living plant always has embryonic tissues By contrast an animal embryo will very early produce all of the body parts that it will ever have in its life When the animal is born or hatches from its egg it has all its body parts and from that point will only grow larger and more mature The properties of organization seen in a plant are emergent properties which are more than the sum of the individual parts The assembly of these tissues and functions into an integrated multicellular organism yields not only the characteristics of the separate parts and processes but also quite a new set of characteristics which would not have been predictable on the basis of examination of the separate parts 33 Growth Edit A vascular plant begins from a single celled zygote formed by fertilisation of an egg cell by a sperm cell From that point it begins to divide to form a plant embryo through the process of embryogenesis As this happens the resulting cells will organize so that one end becomes the first root while the other end forms the tip of the shoot In seed plants the embryo will develop one or more seed leaves cotyledons By the end of embryogenesis the young plant will have all the parts necessary to begin its life Once the embryo germinates from its seed or parent plant it begins to produce additional organs leaves stems and roots through the process of organogenesis New roots grow from root meristems located at the tip of the root and new stems and leaves grow from shoot meristems located at the tip of the shoot 34 Branching occurs when small clumps of cells left behind by the meristem and which have not yet undergone cellular differentiation to form a specialized tissue begin to grow as the tip of a new root or shoot Growth from any such meristem at the tip of a root or shoot is termed primary growth and results in the lengthening of that root or shoot Secondary growth results in widening of a root or shoot from divisions of cells in a cambium 35 In addition to growth by cell division a plant may grow through cell elongation 36 This occurs when individual cells or groups of cells grow longer Not all plant cells will grow to the same length When cells on one side of a stem grow longer and faster than cells on the other side the stem will bend to the side of the slower growing cells as a result This directional growth can occur via a plant s response to a particular stimulus such as light phototropism gravity gravitropism water hydrotropism and physical contact thigmotropism Plant growth and development are mediated by specific plant hormones and plant growth regulators PGRs Ross et al 1983 37 Endogenous hormone levels are influenced by plant age cold hardiness dormancy and other metabolic conditions photoperiod drought temperature and other external environmental conditions and exogenous sources of PGRs e g externally applied and of rhizospheric origin Morphological variation Edit Plants exhibit natural variation in their form and structure While all organisms vary from individual to individual plants exhibit an additional type of variation Within a single individual parts are repeated which may differ in form and structure from other similar parts This variation is most easily seen in the leaves of a plant though other organs such as stems and flowers may show similar variation There are three primary causes of this variation positional effects environmental effects and juvenility Evolution of plant morphology Edit Transcription factors and transcriptional regulatory networks play key roles in plant morphogenesis and their evolution During plant landing many novel transcription factor families emerged and are preferentially wired into the networks of multicellular development reproduction and organ development contributing to more complex morphogenesis of land plants 38 Most land plants share a common ancestor multicellular algae An example of the evolution of plant morphology is seen in charophytes Studies have shown that charophytes have traits that are homologous to land plants There are two main theories of the evolution of plant morphology these theories are the homologous theory and the antithetic theory The commonly accepted theory for the evolution of plant morphology is the antithetic theory The antithetic theory states that the multiple mitotic divisions that take place before meiosis cause the development of the sporophyte Then the sporophyte will development as an independent organism 39 Developmental model organisms EditMuch of developmental biology research in recent decades has focused on the use of a small number of model organisms It has turned out that there is much conservation of developmental mechanisms across the animal kingdom In early development different vertebrate species all use essentially the same inductive signals and the same genes encoding regional identity Even invertebrates use a similar repertoire of signals and genes although the body parts formed are significantly different Model organisms each have some particular experimental advantages which have enabled them to become popular among researchers In one sense they are models for the whole animal kingdom and in another sense they are models for human development which is difficult to study directly for both ethical and practical reasons Model organisms have been most useful for elucidating the broad nature of developmental mechanisms The more detail is sought the more they differ from each other and from humans Plants Edit Thale cress Arabidopsis thaliana 40 Vertebrates Edit Frog Xenopus 40 X laevis and X tropicalis 41 42 Good embryo supply Especially suitable for microsurgery Zebrafish Danio rerio 43 Good embryo supply Well developed genetics Chicken Gallus gallus 44 Early stages similar to mammal but microsurgery easier Low cost Mouse Mus musculus 45 A mammal 40 with well developed genetics Invertebrates Edit Fruit fly Drosophila melanogaster 46 Good embryo supply Well developed genetics Nematode Caenorhabditis elegans 47 Good embryo supply Well developed genetics Low cost Unicellular Edit Algae Chlamydomonas 40 Yeast Saccharomyces 40 Others Edit Also popular for some purposes have been sea urchins 48 40 and ascidians 49 For studies of regeneration urodele amphibians such as the axolotl Ambystoma mexicanum are used 50 and also planarian worms such as Schmidtea mediterranea 7 Organoids have also been demonstrated as an efficient model for development 51 Plant development has focused on the thale cress Arabidopsis thaliana as a model organism 52 See also EditBlastocyst Body plan Cell signaling Cell signaling networks Embryology Enhancer Fish development Gene regulatory network Ontogeny Plant evolutionary developmental 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laevis Daudin North Holland Amsterdam a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Harland RM Grainger RM December 2011 Xenopus research metamorphosed by genetics and genomics Trends in Genetics 27 12 507 15 doi 10 1016 j tig 2011 08 003 PMC 3601910 PMID 21963197 Lawson ND Wolfe SA July 2011 Forward and reverse genetic approaches for the analysis of vertebrate development in the zebrafish Developmental Cell 21 1 48 64 doi 10 1016 j devcel 2011 06 007 PMID 21763608 Rashidi H Sottile V April 2009 The chick embryo hatching a model for contemporary biomedical research BioEssays 31 4 459 65 doi 10 1002 bies 200800168 PMID 19274658 S2CID 5489431 Behringer R Gertsenstein M Vintersten K Nagy M 2014 Manipulating the Mouse Embryo A Laboratory Manual Fourth ed Cold Spring Harbor NY Cold Spring Harbor Laboratory Press St Johnston D March 2002 The art and design of genetic screens Drosophila melanogaster Nature Reviews Genetics 3 3 176 88 doi 10 1038 nrg751 PMID 11972155 S2CID 195368351 Riddle DL Blumenthal T Meyer BJ Priess JR 1997 C elegans II Cold Spring Harbor NY Cold Spring Harbor Laboratory Press Ettensohn CA Sweet HC 2000 Patterning the early sea urchin embryo Current Topics in Developmental Biology Volume 50 pp 1 44 doi 10 1016 S0070 2153 00 50002 7 ISBN 9780121531508 PMID 10948448 a href Template Cite book html title Template Cite book cite book a journal ignored help Lemaire P June 2011 Evolutionary crossroads in developmental biology the tunicates Development 138 11 2143 52 doi 10 1242 dev 048975 PMID 21558365 Nacu E Tanaka EM 2011 Limb regeneration a new development Annual Review of Cell and Developmental Biology 27 409 40 doi 10 1146 annurev cellbio 092910 154115 PMID 21801016 Ader M Tanaka EM December 2014 Modeling human development in 3D culture Current Opinion in Cell Biology 31 23 8 doi 10 1016 j ceb 2014 06 013 PMID 25033469 Weigel D Glazebrook J 2002 Arabidopsis A Laboratory Manual Cold Spring Harbor NY Cold Spring Harbor Laboratory Press Further reading EditGilbert SF 2013 Developmental Biology Sunderland Mass Sinauer Associates Inc Slack JM 2013 Essential Developmental Biology Oxford Wiley Blackwell Wolpert L Tickle C 2011 Principles of Development Oxford and New York Oxford University Press External links Edit nbsp Wikibooks has more on the topic of Developmental biology nbsp Wikimedia Commons has media related to Developmental biology Society for Developmental Biology Collaborative resources Developmental Biology 10th edition Essential Developmental Biology 3rd edition Retrieved from https en wikipedia org w index php title Developmental biology amp oldid 1178409203, wikipedia, wiki, book, books, library,

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