Jump to content

英文维基 | 中文维基 | 日文维基 | 草榴社区

Intestinal epithelium

From Wikipedia, the free encyclopedia
(Redirected from Intestinal epithelial cells)
Intestinal epithelium
Simple columnar epithelial cells
Cell types of the intestinal epithelium
Identifiers
MeSHD007413
FMA15695 17229, 15695
Anatomical terminology

The intestinal epithelium is the single cell layer that forms the luminal surface (lining) of both the small and large intestine (colon) of the gastrointestinal tract. Composed of simple columnar epithelium its main functions are absorption, and secretion. Useful substances are absorbed into the body, and the entry of harmful substances is restricted. Secretions include mucins, and peptides.

Absorptive cells in the small intestine are known as enterocytes, and in the colon they are known as colonocytes. The other cell types are the secretory cells – goblet cells, Paneth cells, enteroendocrine cells, and Tuft cells. Paneth cells are absent in the colon.[1][2]

As part of its protective role, the intestinal epithelium forms an important component of the intestinal mucosal barrier. Certain diseases and conditions are caused by functional defects in the intestinal epithelium. On the other hand, various diseases and conditions can lead to its dysfunction which, in turn, can lead to further complications.

Structure

[edit]
Proliferative stem cells residing at the base of the intestinal glands produce new epithelial cells which migrate upwards and out of the crypt. Eventually, they are shed into the intestinal lumen

The intestinal epithelium is part of the mucosal lining. The epithelium is simple cuboidal epithelium composed of a single layer of cells, while the other two layers of the mucosa, the lamina propria and the muscularis mucosae, support and communicate with the epithelial layer. To securely contain the contents of the intestinal lumen, the cells of the epithelial layer are joined together by tight junctions, thus forming a contiguous and relatively impermeable membrane.

Drawing showing the relationship between villi and microvilli of the small intestine. The luminal surface of the enterocytes have microvilli (1 micrometer long) while the cell layer itself is folded to form villi (0.5-1.6 millimeters long) and crypts. Both serve to increase the total absorption surface of the intestine.

Epithelial cells are continuously renewed every 4–5 days through a process of cell division, maturation, and migration. Renewal relies on proliferative cells (stem cells) that reside at the crypt (base) of the intestinal glands (epithelial invaginations into the underlying connective tissue).[3] After being formed at the base, the new cells migrate upwards and out of the crypt, maturing along the way. Eventually, they undergo apoptosis and are shed off into the intestinal lumen.[4] In this way, the lining of the intestine is constantly renewed while the number of cells making up the epithelial layer remains constant.[5]

In the small intestine, the mucosal layer is specially adapted to provide a large surface area in order to maximize the absorption of nutrients. The expansion of the absorptive surface, 600 times beyond that of a simple cylindrical tube, is achieved by three anatomical features:[6]

  • Circular folds are transverse folds that slow the passage of the luminal contents and serve to expand the total surface area threefold.
  • Villi and intestinal glands serve to increase the mucosal surface area tenfold. (Intestinal villus)
  • Microvilli covering the apical surface of the enterocytes increase the absorptive surface twentyfold. These numerous microscopic (100 nanometers in diameter) finger-like projections form an undulated brush border.

The brush border on the apical surface of the epithelial cells is covered with glycocalyx, which is composed of oligosaccharides attached to membrane glycoproteins and glycolipids.[7]

TEM image of a thin section cut through an epithelial cell showing the luminal surface (apical end) of the cell packed with microvilli that make up the absorbing surface. Each microvillus is approximately 1 micrometers long and 0.1 micrometer in diameter

Cell types

[edit]

Different cell types are produced by the stem cells that reside at the base of the crypts.[4] Each type matures according to its specific differentiation program as it migrates up and out of the crypt. Many of the genes necessary for differentiation into the different epithelial cell types have been identified and characterized. The cell types produced are: enterocytes (small intestine) (known as colonocytes in colon), Goblet cells, enteroendocrine cells, Paneth cells, microfold cells, cup cells and tuft cells. Their functions are listed here:[8]

Throughout the digestive tract, the distribution of the different types of epithelial cells varies according to the function of that region.[5]

Structural components of cellular junctions

[edit]
Types of cell junctions (click to enlarge).

Important for the barrier function of intestinal epithelium, its cells are joined securely together by four types of cell junction which can be identified at the ultrastructural level:[14][15]

Gap junctions

[edit]

Gap junctions bring the adjacent cells within 2 nanometers of each other. They are formed by several homologous proteins encoded by the connexin gene family coming together to form a multiprotein complex. The molecular structure of this complex is in the form of a hexamer. The complex, which is embedded in the cell membranes of the two joined cells, forms a gap or channel in the middle of the six proteins. This channel allows various molecules, ions and electrical impulses to pass between the two cells.[16]

Desmosomes

[edit]

These complexes, consisting of transmembrane adhesion proteins of the cadherin family, link adjacent cells together through their cytoskeletons.[17] Desmosomes leave a gap of 30 nanometers between cells.[16]

Adherens junctions

[edit]

Adherens junctions, also called zonula adherens, are multiprotein complexes formed by proteins of the catenin and cadherin families. They are located in the membrane at the contact points between the cells. They are formed by interactions between intracellular adapter proteins, transmembrane proteins and the actin cytoskeletons of the cells . Besides their role in linking adjacent cells, these complexes are important for regulating epithelial migration, cell polarity, and the formation of other cell junction complexes.[15]

Tight junctions

[edit]

Tight junctions, also called zonula occludens, are the most important components of the intestinal epithelium for its barrier function.[18] These complexes, formed primarily of members of the claudin and the occludin families, consist of about 35 different proteins,[14] form a ring shaped continuous ribbon around the cells, and are located near the borders of the lateral and apical membranes.[15]

The extracellular domains of the transmembrane proteins in adjacent cells cross connect to form a tight seal. These interactions include those between proteins in the same membrane ("cis") and proteins in adjacent cells ("trans"). In addition, interactions can be homophilic (between identical proteins) or heterophilic (between different proteins).[15]

Similar to adherens junctions, the intracellular domains of tight junctions interact with different scaffold proteins, adapter proteins and signaling complexes to regulate cytoskeletal linking, cell polarity, cell signaling and vesical trafficking.[15]

Tight junctions provide a narrow but modifiable seal between adjacent cells in the epithelial layer and thereby provide selective paracellular transport of solutes.[15] While previously thought to be static structures, tight junctions are now known to be dynamic and can change the size of the opening between cells and thereby adapt to the different states of development, physiologies and pathologies.[18] They function as a selective and semipermeable paracellular barrier between apical and basolateral compartments of the epithelial layer. They function to facilitate the passage of small ions and water-soluble solutes through the paracellular space while preventing the passage of luminal antigens, microorganisms and their toxins.[15]

Physiology

[edit]

The intestinal epithelium has a complex anatomical structure which facilitates motility and coordinated digestive, absorptive, immunological and neuroendocrine functions.[19]

The mucus secreted by goblet cells acts as a lubricant and protects the epithelial cell layer against irritation from mucosal contents.[20]

Traditionally, crypt cells were considered primarily as secretory cells while enterocytes are considered principally absorptive. However, recent studies have challenged this classical functional partitioning and have shown that both the surface and crypt cells can perform both secretory and absorptive functions and that, in fact, these functions can occur simultaneously.[21][22]

Nutrient uptake

[edit]

Overlaying the brush border of the apical surface of the enterocytes is the glycocalyx, which is a loose network composed of the oligosaccharide side chains of integral membrane hydrolases and other enzymes essential for the digestion of proteins and carbohydrates. These glycoproteins, glycolipids, and enzymes catalyze the final digestive stages of luminal carbohydrates and proteins. The monosaccharides and amino acids thus produced are subsequently transported across the intestinal epithelium and eventually into the bloodstream.[7]

The absorption of electrolytes and water is one of the most important functions of the digestive tract. Water absorption is passive and isotonic - depending on the speed and direction of solute flow. Other factors influencing fluid absorption are osmolarity and the specific intestinal region.[19] Regulated selective permeability is performed through two major routes: the transcellular (transepithelial) route and the paracellular route.[15]

Transcellular permeability

[edit]
Scheme of selective permeability routes of epithelial cells (red arrows). The transcellular (through the cells) and paracellular (between the cells) routes control the passage of substances between the intestinal lumen and blood.

This consists of specific transport of solutes across the epithelial cells. It is predominantly regulated by the activities of specialised transporters that translocate specific electrolytes, amino acids, sugars, short chain fatty acids and other molecules into or out of the cell.[15]

Paracellular permeability

[edit]

Paracellular permeability depends on transport through the spaces that exist between epithelial cells. It is regulated by cellular junctions that are localized in the laminal membranes of the cells.[15] This is the main route of passive flow of water and solutes across the intestinal epithelium. Regulation depends on the intercellular tight junctions which have the most influence on paracellular transport.[23] Studies using the electron microscope showed that the electrical resistance of epithelial layers depends on the complexity and number of filaments within the tight junction transmembrane protein complexes.[19] Also, the plasma membrane resistance and variable transmembrane conductance of the epithelial cells can also modulate paracellular pathway function.[19]

Functions

[edit]

The barrier formed by the intestinal epithelium separates the external environment (the contents of the intestinal lumen) from the body[15] and is the most extensive and important mucosal surface of body.[18]

The intestinal epithelium serves several crucial functions, exhibiting both innate and adaptive immune features. It closely monitors its intracellular and extracellular environment, communicates messages to neighbouring cells and rapidly initiates active defensive and repair measures, if necessary.[24] On the one hand, it acts as a barrier, preventing the entry of harmful substances such as foreign antigens, toxins and microorganisms.[14][15] On the other hand, it acts as a selective filter which facilitates the uptake of dietary nutrients, electrolytes, water and various other beneficial substances from the intestinal lumen.[15]

When barrier integrity is lost, intestinal permeability increases and uncontrolled passage of harmful substances can occur. This can lead to, depending on the genetic predisposition of the individual, the development of inflammation, infection, allergies, autoimmune diseases or cancer - within the intestine itself or other organs.[19]

Although they primarily function as part of the digestive system, enterocytes of the intestinal epithelium also express toll-like receptors and nucleotide oligomerization domain proteins that recognize diverse types of microbes and contribute to immune system function.[25][26] Thus the intestinal epithelium not only serves as a physical barrier separating the intestinal lumen from the body proper but also carries out pathogen recognition functions as part of the intrinsic immune system.

Importance for human health

[edit]

Loss of integrity of the intestinal epithelium plays a key pathogenic role in inflammatory bowel disease (IBD).[27] Changes in the composition of the intestinal microbiota are an important environmental factor in the development of IBD. Detrimental changes in the intestinal microbiota induce an inappropriate (uncontrolled) immune response that results in damage to the intestinal epithelium. Breaches in this critical barrier (the intestinal epithelium) allow further infiltration of microbiota that, in turn, elicit further immune responses. IBD is a multifactorial disease that is nonetheless driven in part by an exaggerated immune response to gut microbiota that causes defects in epithelial barrier function.[28]

Bile acids are normal components of the luminal contents of the gastrointestinal tract where they can act as physiologic detergents and regulators of intestinal epithelial homeostasis.[29] Excessive long term exposure of intestinal epithelial cells to bile acids may cause oxidative stress leading to oxidative DNA damage and carcinogenic mutation.[30]

See also

[edit]

References

[edit]
  1. ^ Noah, TK; Donahue, B; Shroyer, NF (15 November 2011). "Intestinal development and differentiation". Experimental Cell Research. 317 (19): 2702–10. doi:10.1016/j.yexcr.2011.09.006. PMC 3210330. PMID 21978911.
  2. ^ Litvak, Y; Byndloss, MX; Bäumler, AJ (30 November 2018). "Colonocyte metabolism shapes the gut microbiota". Science. 362 (6418). Bibcode:2018Sci...362.9076L. doi:10.1126/science.aat9076. PMC 6296223. PMID 30498100.
  3. ^ Clevers H (2013). "The intestinal crypt, a prototype stem cell compartment". Cell. 154 (2): 274–84. doi:10.1016/j.cell.2013.07.004. PMID 23870119.
  4. ^ a b Laurens G. van der Flier; Hans Clevers (2009). "Stem Cells, Self-Renewal, and Differentiation in the Intestinal Epithelium". Annual Review of Physiology. 71 (1): 241–260. doi:10.1146/annurev.physiol.010908.163145. PMID 18808327.
  5. ^ a b Lodish, Harvey; Berk, Arnold; Zipursky, S. Lawrence; Matsudaira, Paul; Baltimore, David; Darnell, James (2000). "Intestinal Architecture and Development". Molecular Cell Biology (4th ed.). W. H. Freeman. ISBN 978-0-7167-3136-8.
  6. ^ Khurana (2005). Textbook Of Medical Physiology. Elsevier India. p. 641. ISBN 978-81-8147-850-4.
  7. ^ a b Lodish H, Berk A, Zipursky SL, Matsudaira P, Baltimore D, Darnell J (2000). "Transport across epithelia". Molecular Cell Biology (4th ed.). W.H. Freeman. ISBN 0-7167-3136-3. OCLC 48553325.
  8. ^ Sarmento, Bruno (30 September 2015). Concepts and Models for Drug Permeability Studies: Cell and Tissue based In Vitro Culture Models. Woodhead. pp. 57–58. ISBN 978-0-08-100114-1.
  9. ^ Bohórquez, Diego; Liddle, Rodger (2015). "Neuroepithelial circuit formed by innervation of sensory enteroendocrine cells". Journal of Clinical Investigation. 125 (2): 782–6. doi:10.1172/JCI78361. PMC 4319442. PMID 25555217.
  10. ^ Kaelberer, M. Maya; Bohórquez, Diego (2018). "A gut-brain neural circuit for nutrient sensory transduction". Science. 361 (6408): eaat5236. doi:10.1126/science.aat5236. PMC 6417812. PMID 30237325.
  11. ^ van Es, Johan H.; Clevers, Hans (16 June 2014). "Paneth cells". Current Biology. 24 (12): R547–8. Bibcode:2014CBio...24.R547V. doi:10.1016/j.cub.2014.04.049. PMID 24937274.
  12. ^ Santaolalla R, Abreu MT (2012). "Innate immunity in the small intestine". Curr Opin Gastroenterol. 28 (2): 124–9. doi:10.1097/MOG.0b013e3283506559. PMC 3502878. PMID 22241076.
  13. ^ a b Gerbe, F; Legraverend, C; Jay, P (September 2012). "The intestinal epithelium tuft cells: specification and function". Cellular and Molecular Life Sciences. 69 (17): 2907–17. doi:10.1007/s00018-012-0984-7. PMC 3417095. PMID 22527717.
  14. ^ a b c Khan, Niamat; Asif, Abdul R. (1 January 2015). "Transcriptional Regulators of Claudins in Epithelial Tight Junctions". Mediators of Inflammation. 2015: 219843. doi:10.1155/2015/219843. PMC 4407569. PMID 25948882.
  15. ^ a b c d e f g h i j k l m Groschwitz, Katherine R.; Hogan, Simon P. (1 July 2009). "Intestinal Barrier Function: Molecular Regulation and Disease Pathogenesis". The Journal of Allergy and Clinical Immunology. 124 (1): 3–22. doi:10.1016/j.jaci.2009.05.038. PMC 4266989. PMID 19560575.
  16. ^ a b Bennett, M. V.; Barrio, L. C.; Bargiello, T. A.; Spray, D. C.; Hertzberg, E.; Sáez, J. C. (1 March 1991). "Gap junctions: new tools, new answers, new questions". Neuron. 6 (3): 305–320. doi:10.1016/0896-6273(91)90241-q. PMID 1848077. S2CID 33441056.
  17. ^ Nekrasova, Oxana; Green, Kathleen J. (1 November 2013). "Desmosome assembly and dynamics". Trends in Cell Biology. 23 (11): 537–546. doi:10.1016/j.tcb.2013.06.004. PMC 3913269. PMID 23891292.
  18. ^ a b c Rao JN, Wang JY (2010). "Intestinal Architecture and Development". Regulation of Gastrointestinal Mucosal Growth. Morgan & Claypool Life Sciences. OCLC 1117907811. PMID 21634069. NBK54098.
  19. ^ a b c d e Fasano, Alessio (1 January 2011). "Zonulin and Its Regulation of Intestinal Barrier Function: The Biological Door to Inflammation, Autoimmunity, and Cancer". Physiological Reviews. 91 (1): 151–175. doi:10.1152/physrev.00003.2008. PMID 21248165. S2CID 1375779.
  20. ^ Allen, Adrian; Flemström, Gunnar (1 January 2005). "Gastroduodenal mucus bicarbonate barrier: protection against acid and pepsin". American Journal of Physiology. Cell Physiology. 288 (1): C1–19. doi:10.1152/ajpcell.00102.2004. PMID 15591243. S2CID 6668280.
  21. ^ Geibel, John P. (1 January 2005). "Secretion and absorption by colonic crypts". Annual Review of Physiology. 67: 471–490. doi:10.1146/annurev.physiol.67.031103.153530. PMID 15709966.
  22. ^ Binder, Henry J.; Rajendran, Vazhaikkurichi; Sadasivan, Vidyasagar; Geibel, John P. (1 April 2005). "Bicarbonate secretion: a neglected aspect of colonic ion transport". Journal of Clinical Gastroenterology. 39 (4 Suppl 2): S53–8. doi:10.1097/01.mcg.0000155521.81382.3a. PMID 15758660.
  23. ^ Näslund, Erik; Hellström, Per M. (10 September 2007). "Appetite signaling: from gut peptides and enteric nerves to brain". Physiology & Behavior. 92 (1–2): 256–262. doi:10.1016/j.physbeh.2007.05.017. PMID 17582445. S2CID 230872.
  24. ^ Cario, E (2010). "Heads up! How the intestinal epithelium safeguards mucosal barrier immunity through the inflammasome and beyond". Current Opinion in Gastroenterology. 26 (6): 583–590. doi:10.1097/MOG.0b013e32833d4b88. PMID 20664345. S2CID 12976253.
  25. ^ Cario, E (2005). "Bacterial interactions with cells of the intestinal mucosa: Toll-like receptors and NOD2". Gut. 54 (8): 1182–93. doi:10.1136/gut.2004.062794. PMC 1774880. PMID 15840688.
  26. ^ Abreu, Maria T.; Fukata, Masayuki; Arditi, Moshe (15 April 2005). "TLR signaling in the gut in health and disease". Journal of Immunology. 174 (8): 4453–60. doi:10.4049/jimmunol.174.8.4453. PMID 15814663.
  27. ^ Maloy, Kevin J.; Powrie, Fiona (16 June 2011). "Intestinal homeostasis and its breakdown in inflammatory bowel disease". Nature. 474 (7351): 298–306. doi:10.1038/nature10208. PMID 21677746. S2CID 205225483. Archived from the original on 29 October 2019. Retrieved 8 December 2019.
  28. ^ Coskun, Mehmet (25 August 2014). "Intestinal Epithelium in Inflammatory Bowel Disease". Frontiers in Medicine. 1: 24. doi:10.3389/fmed.2014.00024. PMC 4292184. PMID 25593900.
  29. ^ Ajouz H, Mukherji D, Shamseddine A (May 2014). "Secondary bile acids: an underrecognized cause of colon cancer". World J Surg Oncol. 12: 164. doi:10.1186/1477-7819-12-164. PMC 4041630. PMID 24884764.
  30. ^ Bernstein H, Bernstein C (January 2023). "Bile acids as carcinogens in the colon and at other sites in the gastrointestinal system". Exp Biol Med (Maywood). 248 (1): 79–89. doi:10.1177/15353702221131858. PMC 9989147. PMID 36408538.