Difference between revisions of "Cilium" - New World Encyclopedia
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| − | [[Image:Bronchiolar_epithelium_3_-_SEM.jpg|thumb|250px|right| | + | [[Image:Bronchiolar_epithelium_3_-_SEM.jpg|thumb|250px|right|SEM micrograph of the cilia projecting from [[respiratory system|respiratory]] [[epithelium]] in the [[lung]]s]] |
| − | A '''cilium''' (plural ''cilia'') is | + | A '''cilium''' (plural ''cilia'') is a thin, short, hairlike extension or appendage of a [[eukaryote|eukaryotic]] [[cell (biology)|cell]]s that projects approximately 5–10 micrometers outwards from the cell body. There are two types of cilia: ''motile cilia'', which constantly beat in one direction and result in movement of the cell or of fluids (water, mucus, etc.) around the cell, and ''non-motile cilia'', which typically serve as sensory organelles. |
| + | |||
| + | Cilia are similar to [[eukaryote]] [[flagellum|flagella]]—another structure that extends out from the surface of cell and is used for movement—in that both are composed of nine pairs of microtubules arranged around its circumference and one pair of microtubules running down the center, the ''9 + 2'' structure (Towle 1989). ([[Prokaryote]] flagella have a different structure.) | ||
| + | |||
| + | However, cilia are characteristically shorter and occur in larger numbers than flagella. Flagella typically occur singly or in pairs; on the other hand, the unicellular [[paramecium]] has 17,000 cilia on its surface (Towle 1989). There are also functional differences in terms of type of movement or force exerted. Flagella use a whip-like action to create movement of the whole cell, such as the movement of [[sperm]] in the reproductive tract. Cilia primarily use a waving action to move substances across the cell, such as the ciliary esculator found in the respiratory tract. Cilia may also function as sensory organs. | ||
| + | |||
| + | The structural similarity of cilia and eukaryote flagella is such that some authorities group cilia and eukarote flagella together and consider cilium simply a special type of flagellum—one organized such that many flagella (cilia) may work in synchrony (Patterson 2000). The term '''undulipodium''' is used for an intracellular projection of a eukaryote cell with a microtuble array and includes both flagella and cilia. | ||
| + | |||
| + | The connectedness of [[life]] is reflected in the presence of cilia in [[protozoa]], [[invertebrate]]s, [[vertebrate]]s, [[human]]s, and even some [[plant]]s. | ||
| + | |||
| + | In [[protozoa]]— a diverse group of single-celled, microscopic or near-microscopic [[protist]] eukaryotes that commonly show characteristics usually associated with animals—those organisms with cilia ('''ciliates''') are generally placed in the phylum Ciliophora, while those with flagella (flagellates) are generally placed in the phylum Zoomastigina (or Mastigophora). | ||
== Types and distribution == | == Types and distribution == | ||
| − | Cilia are found in | + | Cilia are found in [[protozoa]]n, [[plant]], and [[animal]] [[cell (biology)|cells]], but are rare in [[plant]]s, occurring most notably in [[cycad]]s. |
| − | + | There are about 8,000 known species of [[protozoa]]n ciliates in phylum Ciliophora, living in both marine and freshwater habitats (Towle 1989). Protozoan ciliates possess motile cilia exclusively and use them for either locomotion or to simply move liquid over their surface. Some ciliates bear groups of cilia that are fused together into large mobile projections called '''cirri''' (''singular'', '''cirrus'''). | |
| − | In contrast to motile cilia, non-motile cilia usually occur one per cell. The outer segment of the rod [[photoreceptor cell]] in the human eye is connected to its cell body with a specialized non-motile cilium. The dendritic knob of the [[olfactory]] neuron, where the odorant receptors are located, is also carrying non-motile cilia (about 10 cilia | + | Among the better known protozoan ciliates is the freshwater genus ''Paramecium''. A [[paramecium]] has a rigid protein covering, the pellicle, that is covered by thousands of cilia arranged in rows (Towle 1989). The cilia beat in waves, moving slantwise across the long axis of the body, causing the paramecium to rotate as it moves forward (Towle 1989). On a paramecium, there also is a funnellike oral groove lined with cilia that create a water current that sweeps bacteria, protists, and other food down the groove to the mouth pore. |
| + | |||
| + | Among animals, [[nematode]]s and [[arthropod]]s only have non-motile cilia on some sensory nerve cells. Larger [[eukaryote]]s, such as [[mammal]]s, have motile cilia as well as non-motile. Motile cilia are rarely found alone, usually present on a cell's surface in large numbers and beating in coordinated waves. In [[human]]s, for example, motile cilia are found in the lining of the [[trachea]] (windpipe), where they sweep mucus, which traps bacteria and dirt, out of the lungs. In humans (and in all female mammals), the beating of cilia in the Fallopian tubes moves the [[ovum]] from the [[ovary]] to the [[uterus]]. | ||
| + | |||
| + | In contrast to motile cilia, non-motile cilia usually occur one per cell. The outer segment of the rod [[photoreceptor cell]] in the human [[eye]] is connected to its cell body with a specialized non-motile cilium. The dendritic knob of the [[olfactory]] neuron, where the odorant receptors are located, is also carrying non-motile cilia (about 10 cilia per dendritic knob). Aside from these specialized examples, almost all mammalian cells have a single, non-motile "''primary cilium''". Though the primary cilium has historically been ignored by scientists, recent findings regarding its physiological roles in chemical sensation, signal transduction, and control of cell growth, have led scientists to re-evaluate its importance. | ||
== Assembly and maintenance == | == Assembly and maintenance == | ||
[[Image:Bronchiolar_area_cilia_cross-sections_2.jpg|thumb|300px|right|Cross-section of two motile cilia, showing the "9+2" structure]] | [[Image:Bronchiolar_area_cilia_cross-sections_2.jpg|thumb|300px|right|Cross-section of two motile cilia, showing the "9+2" structure]] | ||
| − | To grow a cilium, the building blocks of the cilia such as [[tubulins]] and other partially assembled axonemal | + | To grow a cilium, the building blocks of the cilia, such as [[tubulins]]* and other partially assembled axonemal [[protein]]s, are added to the ciliary tips, which point away from the cell body. A bi-directional motility called '''intraciliary/intraflagellar transport''' or '''IFT''' plays an essential role to move these building materials from the cell body to the assembly site. IFT also carries the disassembled material to be recycled from the ciliary tip back to the cell body. By regulating the equilibrium between these two IFT processes, the length of cilia can be maintained dynamically. |
== Cilium-related disease == | == Cilium-related disease == | ||
| − | Ciliary defects can lead to several human | + | Ciliary defects can lead to several human [[disease]]s. Genetic [[mutation]]s compromising the proper functioning of cilia can cause chronic disorders such as [[primary ciliary dyskinesia]] (PCD). In addition, a defect of the primary cilium in the renal tube cells can lead to [[polycystic kidney disease]] (PKD). In another genetic disorder, called [[Bardet-Biedl syndrome]] (BBS), the mutant gene products are the components in the basal body and cilia. |
| − | Lack of functional cilia in mammalian [[Fallopian tubes]] can cause | + | Lack of functional cilia in mammalian [[Fallopian tubes]] can cause ectopic pregnancy (development of a fertilized egg outside of the uterus). A fertilized [[ovum]] may not reach the [[uterus]] if the cilia are unable to move it there. In such a case, the ovum will implant in the Fallopian tubes, causing a tubal pregnancy, the most common form of ectopic pregnancy. |
==References== | ==References== | ||
| − | + | * Cavalier-Smith, T. 1987. The origin of eukaryote and archaebacterial cells. ''Annals of the New York Academy of Sciences'' 503: 17-54. | |
| − | + | * Cavalier-Smith, T. 2002. The phagotrophic origin of eukaryotes and phylogenetic classification of Protozoa''. ''International Journal of Systematic and Evolutionary Microbiology'' 52: 297-354. | |
| − | + | * Gardiner, M. B. 2005. [http://www.hhmi.org/bulletin/sept2005/pdf/Cilia.pdf The importance of being cilia]. ''HHMI Bulletin'' September, 2005. pp. 32-36, 64. | |
| − | + | * Towle, A. 1989. ''Modern Biology''. Austin: Holt, Rinehart and Winston. ISBN 0030139198. | |
| − | |||
| − | + | ==External references== | |
| − | |||
| − | |||
* [http://www.ciliaproteome.org The Ciliary Proteome Web Page at Johns Hopkins] | * [http://www.ciliaproteome.org The Ciliary Proteome Web Page at Johns Hopkins] | ||
| + | {{organelles}} | ||
| − | |||
| − | |||
[[Category:Life sciences]] | [[Category:Life sciences]] | ||
| − | {{ | + | {{credit2|Cilium|105107400|Undulipodium|95244206}} |
Revision as of 23:29, 20 February 2007
A cilium (plural cilia) is a thin, short, hairlike extension or appendage of a eukaryotic cells that projects approximately 5–10 micrometers outwards from the cell body. There are two types of cilia: motile cilia, which constantly beat in one direction and result in movement of the cell or of fluids (water, mucus, etc.) around the cell, and non-motile cilia, which typically serve as sensory organelles.
Cilia are similar to eukaryote flagella—another structure that extends out from the surface of cell and is used for movement—in that both are composed of nine pairs of microtubules arranged around its circumference and one pair of microtubules running down the center, the 9 + 2 structure (Towle 1989). (Prokaryote flagella have a different structure.)
However, cilia are characteristically shorter and occur in larger numbers than flagella. Flagella typically occur singly or in pairs; on the other hand, the unicellular paramecium has 17,000 cilia on its surface (Towle 1989). There are also functional differences in terms of type of movement or force exerted. Flagella use a whip-like action to create movement of the whole cell, such as the movement of sperm in the reproductive tract. Cilia primarily use a waving action to move substances across the cell, such as the ciliary esculator found in the respiratory tract. Cilia may also function as sensory organs.
The structural similarity of cilia and eukaryote flagella is such that some authorities group cilia and eukarote flagella together and consider cilium simply a special type of flagellum—one organized such that many flagella (cilia) may work in synchrony (Patterson 2000). The term undulipodium is used for an intracellular projection of a eukaryote cell with a microtuble array and includes both flagella and cilia.
The connectedness of life is reflected in the presence of cilia in protozoa, invertebrates, vertebrates, humans, and even some plants.
In protozoa— a diverse group of single-celled, microscopic or near-microscopic protist eukaryotes that commonly show characteristics usually associated with animals—those organisms with cilia (ciliates) are generally placed in the phylum Ciliophora, while those with flagella (flagellates) are generally placed in the phylum Zoomastigina (or Mastigophora).
Types and distribution
Cilia are found in protozoan, plant, and animal cells, but are rare in plants, occurring most notably in cycads.
There are about 8,000 known species of protozoan ciliates in phylum Ciliophora, living in both marine and freshwater habitats (Towle 1989). Protozoan ciliates possess motile cilia exclusively and use them for either locomotion or to simply move liquid over their surface. Some ciliates bear groups of cilia that are fused together into large mobile projections called cirri (singular, cirrus).
Among the better known protozoan ciliates is the freshwater genus Paramecium. A paramecium has a rigid protein covering, the pellicle, that is covered by thousands of cilia arranged in rows (Towle 1989). The cilia beat in waves, moving slantwise across the long axis of the body, causing the paramecium to rotate as it moves forward (Towle 1989). On a paramecium, there also is a funnellike oral groove lined with cilia that create a water current that sweeps bacteria, protists, and other food down the groove to the mouth pore.
Among animals, nematodes and arthropods only have non-motile cilia on some sensory nerve cells. Larger eukaryotes, such as mammals, have motile cilia as well as non-motile. Motile cilia are rarely found alone, usually present on a cell's surface in large numbers and beating in coordinated waves. In humans, for example, motile cilia are found in the lining of the trachea (windpipe), where they sweep mucus, which traps bacteria and dirt, out of the lungs. In humans (and in all female mammals), the beating of cilia in the Fallopian tubes moves the ovum from the ovary to the uterus.
In contrast to motile cilia, non-motile cilia usually occur one per cell. The outer segment of the rod photoreceptor cell in the human eye is connected to its cell body with a specialized non-motile cilium. The dendritic knob of the olfactory neuron, where the odorant receptors are located, is also carrying non-motile cilia (about 10 cilia per dendritic knob). Aside from these specialized examples, almost all mammalian cells have a single, non-motile "primary cilium". Though the primary cilium has historically been ignored by scientists, recent findings regarding its physiological roles in chemical sensation, signal transduction, and control of cell growth, have led scientists to re-evaluate its importance.
Assembly and maintenance
To grow a cilium, the building blocks of the cilia, such as tubulins and other partially assembled axonemal proteins, are added to the ciliary tips, which point away from the cell body. A bi-directional motility called intraciliary/intraflagellar transport or IFT plays an essential role to move these building materials from the cell body to the assembly site. IFT also carries the disassembled material to be recycled from the ciliary tip back to the cell body. By regulating the equilibrium between these two IFT processes, the length of cilia can be maintained dynamically.
Ciliary defects can lead to several human diseases. Genetic mutations compromising the proper functioning of cilia can cause chronic disorders such as primary ciliary dyskinesia (PCD). In addition, a defect of the primary cilium in the renal tube cells can lead to polycystic kidney disease (PKD). In another genetic disorder, called Bardet-Biedl syndrome (BBS), the mutant gene products are the components in the basal body and cilia.
Lack of functional cilia in mammalian Fallopian tubes can cause ectopic pregnancy (development of a fertilized egg outside of the uterus). A fertilized ovum may not reach the uterus if the cilia are unable to move it there. In such a case, the ovum will implant in the Fallopian tubes, causing a tubal pregnancy, the most common form of ectopic pregnancy.
ReferencesISBN links support NWE through referral fees
- Cavalier-Smith, T. 1987. The origin of eukaryote and archaebacterial cells. Annals of the New York Academy of Sciences 503: 17-54.
- Cavalier-Smith, T. 2002. The phagotrophic origin of eukaryotes and phylogenetic classification of Protozoa. International Journal of Systematic and Evolutionary Microbiology 52: 297-354.
- Gardiner, M. B. 2005. The importance of being cilia. HHMI Bulletin September, 2005. pp. 32-36, 64.
- Towle, A. 1989. Modern Biology. Austin: Holt, Rinehart and Winston. ISBN 0030139198.
External references
| Organelles of the cell |
|---|
| Acrosome | Chloroplast | Cilium/Flagellum | Centriole | Endoplasmic reticulum | Golgi apparatus | Lysosome | Melanosome | Mitochondrion | Myofibril | Nucleus | Parenthesome | Peroxisome | Plastid | Ribosome | Vacuole | Vesicle |
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