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Mesoderm

February 16, 2024

The mesoderm is the middle layer of the three germ layers that develops during gastrulation in the very early development of the embryo of most animals. The outer layer is the ectoderm, and the inner layer is the endoderm.[1][2]

Mesoderm
Tissues derived from mesoderm.
Section through a human embryo
Details
Days16
Identifiers
MeSHD008648
FMA69072
Anatomical terminology
[edit on Wikidata]

The mesoderm forms mesenchyme, mesothelium, non-epithelial blood cells and coelomocytes. Mesothelium lines coeloms. Mesoderm forms the muscles in a process known as myogenesis, septa (cross-wise partitions) and mesenteries (length-wise partitions); and forms part of the gonads (the rest being the gametes).[1][unreliable source?] Myogenesis is specifically a function of mesenchyme.

The mesoderm differentiates from the rest of the embryo through intercellular signaling, after which the mesoderm is polarized by an organizing center.[3] The position of the organizing center is in turn determined by the regions in which beta-catenin is protected from degradation by GSK-3. Beta-catenin acts as a co-factor that alters the activity of the transcription factor tcf-3 from repressing to activating, which initiates the synthesis of gene products critical for mesoderm differentiation and gastrulation. Furthermore, mesoderm has the capability to induce the growth of other structures, such as the neural plate, the precursor to the nervous system.

Definition edit

The mesoderm is one of the three germinal layers that appears in the third week of embryonic development. It is formed through a process called gastrulation. There are four important components, which are the axial, ⁣paraxial, intermediate, and lateral plate mesoderms. The axial mesoderm gives rise to the notochord. The paraxial mesoderm forms the somitomeres, which give rise to mesenchyme of the head, and organize into somites in occipital and caudal segments, and give rise to sclerotomes (cartilage and bone), and dermatomes (subcutaneous tissue of the skin).[1][2] Signals for somite differentiation are derived from surroundings structures, including the notochord, neural tube, and epidermis. The intermediate mesoderm connects the paraxial mesoderm with the lateral plate. Eventually it differentiates into urogenital structures that consist of the kidneys, gonads, their associated ducts, and the adrenal cortex. The lateral plate mesoderm gives rise to the heart, blood vessels, and blood cells of the circulatory system, as well as to the mesodermal components of the limbs.[4]

Some of the mesoderm derivatives include the muscle (smooth, cardiac, and skeletal), the muscles of the tongue (occipital somites), the pharyngeal arches muscle (muscles of mastication, muscles of facial expressions), connective tissue, the dermis and subcutaneous layer of the skin, bone and cartilage, dura mater, the endothelium of blood vessels, red blood cells, white blood cells, microglia, the dentin of teeth, the kidneys, and the adrenal cortex.[5]

Development edit

During the third week, a process called gastrulation creates a mesodermal layer between the endoderm and the ectoderm. This process begins with the formation of a primitive streak on the surface of the epiblast.[6] The cells of the layers move between the epiblast and the hypoblast, and begin to spread laterally and cranially. The cells of the epiblast move toward the primitive streak and slip beneath it, in a process called "invagination". Some of the migrating cells displace the hypoblast and create the endoderm, and other cells migrate between the endoderm and the epiblast to create the mesoderm. The remaining cells form the ectoderm. After that, the epiblast and the hypoblast establish contact with the extraembryonic mesoderm until they cover the yolk sac and amnion. They move onto either side of the prechordal plate. The prechordal cells migrate to the midline to form the notochordal plate. The chordamesoderm is the central region of trunk mesoderm.[4] This forms the notochord, which induces the formation of the neural tube, and establishes the anterior-posterior body axis. The notochord extends beneath the neural tube from the head to the tail. The mesoderm moves to the midline until it covers the notochord. When the mesoderm cells proliferate, they form the paraxial mesoderm. In each side, the mesoderm remains thin, and is known as the lateral plate. The intermediate mesoderm lies between the paraxial mesoderm and the lateral plate. Between days 13 and 15, the proliferation of extraembryonic mesoderm, primitive streak, and embryonic mesoderm take place. The notochord process occurs between days 15 and 17. Eventually, the development of the notochord canal and the axial canal takes place between days 17 and 19, when the first three somites are formed.[7]

Paraxial mesoderm edit

Main article: Paraxial mesoderm

During the third week, the paraxial mesoderm is organized into segments. If they appear in the cephalic region and grow with cephalocaudal direction, they are called somitomeres. If they appear in the cephalic region but establish contact with the neural plate, they are known as neuromeres, which later will form the mesenchyme in the head. The somitomeres organize into somites which grow in pairs. In the fourth week, the somites lose their organization and cover the notochord and spinal cord to form the backbone. In the fifth week, there are 4 occipital somites, 8 cervical, 12 thoracic, 5 lumbar, 5 sacral and 8 to 10 coccygeal that will form the axial skeleton. Somitic derivatives are determined by local signaling between adjacent embryonic tissues, in particular the neural tube, notochord, surface ectoderm and the somitic compartments themselves.[8] The correct specification of the deriving tissues, skeletal, cartilage, endothelia and connective tissue is achieved by a sequence of morphogenic changes of the paraxial mesoderm, leading to the three transitory somitic compartments: dermomyotome, myotome and sclerotome. These structures are specified from dorsal to ventral and from medial to lateral.[8] Each somite will form its own sclerotome that will differentiate into the tendon cartilage and bone component. Its myotome will form the muscle component and the dermatome that will form the dermis of the back. The myotome and dermatome have a nerve component.[1][2]

Molecular regulation of somite differentiation edit

Surrounding structures such as the notochord, neural tube, epidermis and lateral plate mesoderm send signals for somite differentiation[1][2] Notochord protein accumulates in presomitic mesoderm destined to form the next somite and then decreases as that somite is established. The notochord and the neural tube activate the protein SHH, which helps the somite to form its sclerotome. The cells of the sclerotome express the protein PAX1 that induces the cartilage and bone formation. The neural tube activates the protein WNT1 that expresses PAX 2 so the somite creates the myotome and dermatome. Finally, the neural tube also secretes neurotrophin 3, so that the somite creates the dermis. Boundaries for each somite are regulated by retinoic acid and a combination of FGF8 and WNT3a.[1][2][9] So retinoic acid is an endogenous signal that maintains the bilateral synchrony of mesoderm segmentation and controls bilateral symmetry in vertebrates. The bilaterally symmetric body plan of vertebrate embryos is obvious in somites and their derivates, such as the vertebral column. Therefore, asymmetric somite formation correlates with a left-right desynchronization of the segmentation oscillations.[10]

Many studies with Xenopus and zebrafish have analyzed the factors of this development and how they interact in signaling and transcription. However, there are still some doubts in how the prospective mesodermal cells integrate the various signals they receive and how they regulate their morphogenic behaviours and cell-fate decisions.[8] Human embryonic stem cells for example have the potential to produce all of the cells in the body and they are able to self-renew indefinitely so they can be used for a large-scale production of therapeutic cell lines. They are also able to remodel and contract collagen and were induced to express muscle actin. This shows that these cells are multipotent cells.[11]

Intermediate mesoderm edit

The intermediate mesoderm connects the paraxial mesoderm with the lateral plate mesoderm, and differentiates into urogenital structures.[12] In upper thoracic and cervical regions, this forms the nephrotomes. In caudal regions, it forms the nephrogenic cord. It also helps to develop the excretory units of the urinary system and the gonads.[4]

Lateral plate mesoderm edit

 
Cytology of normal mesothelium, with typical features. Wright's stain.

The lateral plate mesoderm splits into the parietal (somatic) and visceral (splanchnic) layers. The formation of these layers starts with the appearance of intercellular cavities.[12] The somatic layer depends upon a continuous layer with mesoderm that covers the amnion. The splanchnic layer depends upon a continuous layer that covers the yolk sac. The two layers cover the intraembryonic cavity. The parietal layer, together with overlying ectoderm, forms the lateral body wall folds. The visceral layer forms the walls of the gut tube. Mesoderm cells of the parietal layer form the mesothelial membranes or serous membranes, which line the peritoneal, pleural, and pericardial cavities.[1][2]

See also edit

References edit

  1. ^ a b c d e f g Ruppert, E.E.; Fox, R.S.; Barnes, R.D. (2004). "Introduction to Bilateria". Invertebrate Zoology (7th ed.). Brooks/Cole. pp. 217–218. ISBN 978-0-03-025982-1.
  2. ^ a b c d e f Langman's Medical Embryology, 11th edition. 2010.
  3. ^ Kimelman, D. & Bjornson, C. (2004). "Vertebrate Mesoderm Induction: From Frogs to Mice". In Stern, Claudio D. (ed.). Gastrulation: from cells to embryo. CSHL Press. p. 363. ISBN 978-0-87969-707-5.
  4. ^ a b c Scott, Gilbert (2010). Developmental biology (ninth ed.). US: Sinauer Associates.
  5. ^ Dudek, Ronald W. (2009). High-yield. Embryology (4th ed.). Lippincott Williams & Wilkins.
  6. ^ "Paraxial Mesoderm: The Somites and Their Derivatives". National Center for Biotechnology Information. Retrieved April 15, 2013.
  7. ^ Drew, Ulrich (1993). Color atlas of embryology. German: Thieme.
  8. ^ a b c Yusuf, Faisal (2006). "The eventful somite: Patterning, fate determination and cell division in the somite". Anatomy and Embryology. 211 Suppl 1: 21–30. doi:10.1007/s00429-006-0119-8. PMID 17024302. S2CID 24633902. ProQuest 212010706.[permanent dead link]
  9. ^ Cunningham, T.J.; Duester, G. (2015). "Mechanisms of retinoic acid signalling and its roles in organ and limb development". Nat. Rev. Mol. Cell Biol. 16 (2): 110–123. doi:10.1038/nrm3932. PMC 4636111. PMID 25560970.
  10. ^ Vermot, J.; Gallego Llamas, J.; Fraulob, V.; Niederreither, K.; Chambon, P.; Dollé, P. (April 2005). "Retinoic acid controls the bilateral symmetry of somite formation in the mouse embryo" (PDF). Science. 308 (5721): 563–566. Bibcode:2005Sci...308..563V. doi:10.1126/science.1108363. PMID 15731404. S2CID 5713738. Archived (PDF) from the original on 2022-10-09.
  11. ^ Boyd, N.L.; Robbins KR, K.R.; Dhara SK, S.K.; West FD, F.D.; Stice SL., S.L. (August 2009). "Human embryonic stem cell-derived mesoderm-like epithelium transitions to mesenchymal progenitor cells". Tissue Engineering. Part A. 15 (8): 1897–1907. doi:10.1089/ten.tea.2008.0351. PMC 2792108. PMID 19196144.
  12. ^ a b Kumar, Rani (2008). Textbook of human embryology. I.K. International.

Further reading edit

  • Gurdon, J.B. (1995). "The formation of mesoderm and muscle in Xenopus". In Zagris, Nikolas; et al. (eds.). Organization of the early vertebrate embryo. Springer. ISBN 978-0-306-45132-4.
  • Kenderew, John Cowdery; Lawrence, Eleanor, eds. (1994). "Mesoderm Induction". The encyclopedia of molecular biology. John Wiley & Sons. p. 541. ISBN 978-0-632-02182-6.
  • Liu, Shu Q. (2007). "Early Embryonic Organ Development". Bioregenerative engineering: principles and applications. John Wiley & Sons. ISBN 978-0-471-70907-7.
  • McGeady, Thomas A.; et al. (2006). "Establishment of the Basic Body Plan". Veterinary embryology. Wiley-Blackwell. ISBN 978-1-4051-1147-8.
  • Pappaioannou, Virginia, E. (2004). "Early Embryonic Mesoderm Development". In Lanza, Robert Paul (ed.). Handbook of stem cells, Volume 1. Gulf Professional Publishing. ISBN 978-0-12-436642-8.{{cite book}}: CS1 maint: multiple names: authors list (link)
  • Sherman, Lawrence S.; et al., eds. (2001). Human embryology (3rd ed.). Elsevier Health Sciences. ISBN 978-0-443-06583-5.

External links edit

 
Look up mesoderm in Wiktionary, the free dictionary.

February 16, 2024
mesoderm, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, 2022, learn, when. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Mesoderm news newspapers books scholar JSTOR May 2022 Learn how and when to remove this template message The mesoderm is the middle layer of the three germ layers that develops during gastrulation in the very early development of the embryo of most animals The outer layer is the ectoderm and the inner layer is the endoderm 1 2 MesodermTissues derived from mesoderm Section through a human embryoDetailsDays16IdentifiersMeSHD008648FMA69072Anatomical terminology edit on Wikidata The mesoderm forms mesenchyme mesothelium non epithelial blood cells and coelomocytes Mesothelium lines coeloms Mesoderm forms the muscles in a process known as myogenesis septa cross wise partitions and mesenteries length wise partitions and forms part of the gonads the rest being the gametes 1 unreliable source Myogenesis is specifically a function of mesenchyme The mesoderm differentiates from the rest of the embryo through intercellular signaling after which the mesoderm is polarized by an organizing center 3 The position of the organizing center is in turn determined by the regions in which beta catenin is protected from degradation by GSK 3 Beta catenin acts as a co factor that alters the activity of the transcription factor tcf 3 from repressing to activating which initiates the synthesis of gene products critical for mesoderm differentiation and gastrulation Furthermore mesoderm has the capability to induce the growth of other structures such as the neural plate the precursor to the nervous system Contents 1 Definition 2 Development 3 Paraxial mesoderm 4 Molecular regulation of somite differentiation 5 Intermediate mesoderm 6 Lateral plate mesoderm 7 See also 8 References 9 Further reading 10 External linksDefinition editThe mesoderm is one of the three germinal layers that appears in the third week of embryonic development It is formed through a process called gastrulation There are four important components which are the axial paraxial intermediate and lateral plate mesoderms The axial mesoderm gives rise to the notochord The paraxial mesoderm forms the somitomeres which give rise to mesenchyme of the head and organize into somites in occipital and caudal segments and give rise to sclerotomes cartilage and bone and dermatomes subcutaneous tissue of the skin 1 2 Signals for somite differentiation are derived from surroundings structures including the notochord neural tube and epidermis The intermediate mesoderm connects the paraxial mesoderm with the lateral plate Eventually it differentiates into urogenital structures that consist of the kidneys gonads their associated ducts and the adrenal cortex The lateral plate mesoderm gives rise to the heart blood vessels and blood cells of the circulatory system as well as to the mesodermal components of the limbs 4 Some of the mesoderm derivatives include the muscle smooth cardiac and skeletal the muscles of the tongue occipital somites the pharyngeal arches muscle muscles of mastication muscles of facial expressions connective tissue the dermis and subcutaneous layer of the skin bone and cartilage dura mater the endothelium of blood vessels red blood cells white blood cells microglia the dentin of teeth the kidneys and the adrenal cortex 5 Development editDuring the third week a process called gastrulation creates a mesodermal layer between the endoderm and the ectoderm This process begins with the formation of a primitive streak on the surface of the epiblast 6 The cells of the layers move between the epiblast and the hypoblast and begin to spread laterally and cranially The cells of the epiblast move toward the primitive streak and slip beneath it in a process called invagination Some of the migrating cells displace the hypoblast and create the endoderm and other cells migrate between the endoderm and the epiblast to create the mesoderm The remaining cells form the ectoderm After that the epiblast and the hypoblast establish contact with the extraembryonic mesoderm until they cover the yolk sac and amnion They move onto either side of the prechordal plate The prechordal cells migrate to the midline to form the notochordal plate The chordamesoderm is the central region of trunk mesoderm 4 This forms the notochord which induces the formation of the neural tube and establishes the anterior posterior body axis The notochord extends beneath the neural tube from the head to the tail The mesoderm moves to the midline until it covers the notochord When the mesoderm cells proliferate they form the paraxial mesoderm In each side the mesoderm remains thin and is known as the lateral plate The intermediate mesoderm lies between the paraxial mesoderm and the lateral plate Between days 13 and 15 the proliferation of extraembryonic mesoderm primitive streak and embryonic mesoderm take place The notochord process occurs between days 15 and 17 Eventually the development of the notochord canal and the axial canal takes place between days 17 and 19 when the first three somites are formed 7 Paraxial mesoderm editMain article Paraxial mesoderm During the third week the paraxial mesoderm is organized into segments If they appear in the cephalic region and grow with cephalocaudal direction they are called somitomeres If they appear in the cephalic region but establish contact with the neural plate they are known as neuromeres which later will form the mesenchyme in the head The somitomeres organize into somites which grow in pairs In the fourth week the somites lose their organization and cover the notochord and spinal cord to form the backbone In the fifth week there are 4 occipital somites 8 cervical 12 thoracic 5 lumbar 5 sacral and 8 to 10 coccygeal that will form the axial skeleton Somitic derivatives are determined by local signaling between adjacent embryonic tissues in particular the neural tube notochord surface ectoderm and the somitic compartments themselves 8 The correct specification of the deriving tissues skeletal cartilage endothelia and connective tissue is achieved by a sequence of morphogenic changes of the paraxial mesoderm leading to the three transitory somitic compartments dermomyotome myotome and sclerotome These structures are specified from dorsal to ventral and from medial to lateral 8 Each somite will form its own sclerotome that will differentiate into the tendon cartilage and bone component Its myotome will form the muscle component and the dermatome that will form the dermis of the back The myotome and dermatome have a nerve component 1 2 Molecular regulation of somite differentiation editSurrounding structures such as the notochord neural tube epidermis and lateral plate mesoderm send signals for somite differentiation 1 2 Notochord protein accumulates in presomitic mesoderm destined to form the next somite and then decreases as that somite is established The notochord and the neural tube activate the protein SHH which helps the somite to form its sclerotome The cells of the sclerotome express the protein PAX1 that induces the cartilage and bone formation The neural tube activates the protein WNT1 that expresses PAX 2 so the somite creates the myotome and dermatome Finally the neural tube also secretes neurotrophin 3 so that the somite creates the dermis Boundaries for each somite are regulated by retinoic acid and a combination of FGF8 and WNT3a 1 2 9 So retinoic acid is an endogenous signal that maintains the bilateral synchrony of mesoderm segmentation and controls bilateral symmetry in vertebrates The bilaterally symmetric body plan of vertebrate embryos is obvious in somites and their derivates such as the vertebral column Therefore asymmetric somite formation correlates with a left right desynchronization of the segmentation oscillations 10 Many studies with Xenopus and zebrafish have analyzed the factors of this development and how they interact in signaling and transcription However there are still some doubts in how the prospective mesodermal cells integrate the various signals they receive and how they regulate their morphogenic behaviours and cell fate decisions 8 Human embryonic stem cells for example have the potential to produce all of the cells in the body and they are able to self renew indefinitely so they can be used for a large scale production of therapeutic cell lines They are also able to remodel and contract collagen and were induced to express muscle actin This shows that these cells are multipotent cells 11 Intermediate mesoderm editThe intermediate mesoderm connects the paraxial mesoderm with the lateral plate mesoderm and differentiates into urogenital structures 12 In upper thoracic and cervical regions this forms the nephrotomes In caudal regions it forms the nephrogenic cord It also helps to develop the excretory units of the urinary system and the gonads 4 Lateral plate mesoderm edit nbsp Cytology of normal mesothelium with typical features Wright s stain The lateral plate mesoderm splits into the parietal somatic and visceral splanchnic layers The formation of these layers starts with the appearance of intercellular cavities 12 The somatic layer depends upon a continuous layer with mesoderm that covers the amnion The splanchnic layer depends upon a continuous layer that covers the yolk sac The two layers cover the intraembryonic cavity The parietal layer together with overlying ectoderm forms the lateral body wall folds The visceral layer forms the walls of the gut tube Mesoderm cells of the parietal layer form the mesothelial membranes or serous membranes which line the peritoneal pleural and pericardial cavities 1 2 See also editHistogenesis Organogenesis Triploblastic List of human cell types derived from the germ layersReferences edit a b c d e f g Ruppert E E Fox R S Barnes R D 2004 Introduction to Bilateria Invertebrate Zoology 7th ed Brooks Cole pp 217 218 ISBN 978 0 03 025982 1 a b c d e f Langman s Medical Embryology 11th edition 2010 Kimelman D amp Bjornson C 2004 Vertebrate Mesoderm Induction From Frogs to Mice In Stern Claudio D ed Gastrulation from cells to embryo CSHL Press p 363 ISBN 978 0 87969 707 5 a b c Scott Gilbert 2010 Developmental biology ninth ed US Sinauer Associates Dudek Ronald W 2009 High yield Embryology 4th ed Lippincott Williams amp Wilkins Paraxial Mesoderm The Somites and Their Derivatives National Center for Biotechnology Information Retrieved April 15 2013 Drew Ulrich 1993 Color atlas of embryology German Thieme a b c Yusuf Faisal 2006 The eventful somite Patterning fate determination and cell division in the somite Anatomy and Embryology 211 Suppl 1 21 30 doi 10 1007 s00429 006 0119 8 PMID 17024302 S2CID 24633902 ProQuest 212010706 permanent dead link Cunningham T J Duester G 2015 Mechanisms of retinoic acid signalling and its roles in organ and limb development Nat Rev Mol Cell Biol 16 2 110 123 doi 10 1038 nrm3932 PMC 4636111 PMID 25560970 Vermot J Gallego Llamas J Fraulob V Niederreither K Chambon P Dolle P April 2005 Retinoic acid controls the bilateral symmetry of somite formation in the mouse embryo PDF Science 308 5721 563 566 Bibcode 2005Sci 308 563V doi 10 1126 science 1108363 PMID 15731404 S2CID 5713738 Archived PDF from the original on 2022 10 09 Boyd N L Robbins KR K R Dhara SK S K West FD F D Stice SL S L August 2009 Human embryonic stem cell derived mesoderm like epithelium transitions to mesenchymal progenitor cells Tissue Engineering Part A 15 8 1897 1907 doi 10 1089 ten tea 2008 0351 PMC 2792108 PMID 19196144 a b Kumar Rani 2008 Textbook of human embryology I K International Further reading editGurdon J B 1995 The formation of mesoderm and muscle in Xenopus In Zagris Nikolas et al eds Organization of the early vertebrate embryo Springer ISBN 978 0 306 45132 4 Kenderew John Cowdery Lawrence Eleanor eds 1994 Mesoderm Induction The encyclopedia of molecular biology John Wiley amp Sons p 541 ISBN 978 0 632 02182 6 Liu Shu Q 2007 Early Embryonic Organ Development Bioregenerative engineering principles and applications John Wiley amp Sons ISBN 978 0 471 70907 7 McGeady Thomas A et al 2006 Establishment of the Basic Body Plan Veterinary embryology Wiley Blackwell ISBN 978 1 4051 1147 8 Pappaioannou Virginia E 2004 Early Embryonic Mesoderm Development In Lanza Robert Paul ed Handbook of stem cells Volume 1 Gulf Professional Publishing ISBN 978 0 12 436642 8 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Sherman Lawrence S et al eds 2001 Human embryology 3rd ed Elsevier Health Sciences ISBN 978 0 443 06583 5 External links edit nbsp Look up mesoderm in Wiktionary the free dictionary Embryology at UNSW Notes skmus6 Embryology at Temple EMBIII97 sld039 Retrieved from https en wikipedia org w index php title Mesoderm amp oldid 1191834610, wikipedia, wiki, book, books, library,

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