In
cell biology, an 'organelle' is a discrete structure of a
cell having specialized functions, and is separately enclosed in its own lipid membrane. There are many types of organelles, particularly in the
eukaryotic cells of higher organisms. An organelle is to the cell what an
organ is to the
body (hence the name ''organelle,'' the suffix ''-elle'' being a
diminutive). Organelles were historically identified through the use of
microscopy, and were also identified through the use of
cell fractionation.
Examples and disputes
Some cell biologists consider the term 'organelle' to be synonymous with "cell compartment", other cell biologists strictly limit the term's definition to DNA-containing, formerly autonomous organisms acquired via primary, secondary, or tertiary endosymbiosis. A few of such large organelles having originated from
endosymbiont bacteria:
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mitochondria (in almost all eukaryotes)
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plastids (in plants and algae)
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chloroplasts (mature forms of
etioplasts)
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chromoplasts
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leucoplasts
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amyloplasts
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statoliths
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elaioplasts
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proteinoplasts
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rhodoplasts (in
red algae)
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apicoplasts (in the
malaria parasite, ''
Plasmodium falciparum'')
Further organelles are suggested to have had endosymbiotic origins (notably the flagellum; see
evolution of flagella), but these theories are neither widely accepted nor phylogenetically verified.
Not all parts of the cell qualify as organelles, and the use of the term to refer to some is disputed. Contested cell structures, which are likely ''not'' organelles, include:
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ribosome
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cytoskeleton
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flagellum
Eukaryotic organelles
Eukaryotes are the most structurally complex known cell type, and by definition are in part organized by smaller interior compartments, that are themselves enclosed by lipid membranes that resemble the outermost
cell membrane. The larger organelles, such as the
nucleus and
vacuoles, are easily visible with moderate magnification (although sometimes a clear view requires the application of chemicals that selectively stain parts of the cells); they were among the first biological discoveries made after the invention of the
microscope.
Not all
eukaryotic cells have all of the organelles listed below, and occasionally, exceptional species of cells are missing organelles which might otherwise be considered universal to
eukaryotic cells (such as
mitochondria). There are also occasional exceptions to the number of membranes surrounding organelles, listed in the tables below (e.g. some which are listed as double-membraned are sometimes found with single or triple membranes). In addition to this, the amount of the individual organelles varies depending upon the function of the specific cell to which it is found (example, muscle cells have more smooth endoplasmic reticulum which helps in muscle contraction)
'''Major eukaryotic organelles'''| Organelle | Main function | Structure | Organisms | Notes |
|---|
| chloroplast (plastid) | photosynthesis | double-membrane compartment | plants, protists | has some genes |
| endoplasmic reticulum | modification and folding of new proteins (rough endoplasmic reticulum) and lipids (smooth endoplasmic reticulum) | single-membrane compartment | all eukaryotes | rough endoplasmic reticulum is devoid with ribosomes, folds are flat sacs; smooth endoplasmic reticulum has folds which are tubular | |
| Golgi apparatus | sorting and modification of proteins | single-membrane compartment | all eukaryotes | cis face (convex) nearest to rough endoplasmic reticum; trans face (concave) farthest to rough endoplasmic reticulum | |
| mitochondrion | energy production | double-membrane compartment | most eukaryotes | has some genes |
| vacuole | storage & homeostasis | single-membrane compartment | eukaryotes |
| nucleus | DNA maintenance & transcription to RNA | double-membrane compartment | all eukaryotes | has bulk of genome |
Organelles which have double-membranes and their own
DNA are believed by many
biologists of having originally come from incompletely consumed or invading
prokaryotic cells, which were adopted as a part of the invaded cell through
endosymbiosis. Originally, the word organelle referred to large
lipid-encased formerly autonomous endosymbiont within cells. As other intracellular compartments were discovered, the meaning was generalized (in the United States, mainly) to include any lipid-encased intracellular component with a specialized biochemical function.
'''Other eukaryotic organelles and cell components'''| Organelle/Macromolecule | Main function | Structure | Organisms |
|---|
| acrosome | helps spermatoza fuse with ovum | single-membrane compartment | many animals |
| autophagosome | vesicle which sequesters cytoplasmic material and organelles for degradation | double-membrane compartment | all eukaryotic cells |
| centriole | anchor for cytoskeleton | Microtubule protein | animals |
| cilium | movement in or of external medium | Microtubule protein | animals, protists, few plants |
| glyoxysome | conversion of fat into sugars | single-membrane compartment | plants |
| hydrogenosome | energy & hydrogen production | double-membrane compartment | a few unicellular eukaryotes |
| lysosome | breakdown of large molecules | single-membrane compartment | most eukaryotes |
| melanosome | pigment storage | single-membrane compartment | animals |
| mitosome | not characterized | double-membrane compartment | a few unicellular eukaryotes |
| myofibril | muscular contraction | bundled filaments | animals |
| nucleolus | ribosome production | protein-DNA-RNA | most eukaryotes |
| parenthesome | not characterized | not characterized | fungi |
| peroxisome | oxidation of protein | single-membrane compartment | all eukaryotes |
| ribosome | translation of RNA into proteins | RNA-protein | eukaryotes & prokaryotes |
| vesicle | miscellaneous | single-membrane compartment | all eukaryotes |
Other related structures:
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cytosol
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endomembrane system
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nucleosome
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microtubule
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cell membrane
Prokaryotic organelles
Prokaryotes are not as structurally complex as eukaryotes, and were thought not to have any compartments enclosed by
lipid membranes. In the past they were often viewed as having little internal organization, but slowly details are emerging about prokaryotic internal structures. One contributing discovery was that at least some prokaryotes have ''
microcompartments'', which are compartments enclosed by proteins. Even more striking is the description of prokaryotic organelles, such as magnetosomes (see Komeili et al. ''Science'', 2006 and Scheffel et al. ''Nature'', 2006) and the nucleus-like organelles of the ''Planctomycetes'' (see Fuerst ''Annual Review of Microbiology'', 2005), surrounded by
lipid membranes.
See also
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Cell
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Endosymbiotic theory
References
★ Alberts, Bruce et al. (2002). ''The Molecular Biology of the Cell,'' 4th ed., Garland Science, 2002, ISBN 0-8153-3218-1.
★ Kerfeld, Cheryl A et al., Protein Structures Forming the Shell of Primitive Bacterial Organelles, ''Science'' '309':936-938 (5 August 2005)
Pubmed.
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