Everything about Organelles totally explained
In
cell biology, an
organelle is a specialized subunit within a
cell that has a specific function, and is separately enclosed within its own
lipid membrane.
The name
organelle comes from the idea that these structures are to cells what an
organ is to the
body (hence the name
organelle, the suffix
-elle being a
diminutive). Organelles are identified by
microscopy, and can also be purified by
cell fractionation.
There are many types of organelles, particularly in the
eukaryotic cells of higher organisms.
Prokaryotes were once thought not to have organelles, but some examples have now been identified.
History and Terminology
In biology, an
organ is defined as a confined functional unit within an
organism. The
analogy of bodily organs to microscopic cellular substructures is obvious, as from even early works, authors of respective textbooks rarely elaborate on the distinction between the two.
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Credited as the first to use a
diminutive of
organ for respective cellular structures was German zoologist
Karl August Möbius (1884), who used the term "organula" (plural form of
organulum, the diminutive of
latin organum). From the context, it's clear that he referred to reproduction related structures of
protists. In a footnote, which was published as a correction in the next issue of the journal, he justified his suggestion to call organs of unicellular organisms "organella" since they're only differently formed parts of one cell, in contrast to multicellular organs of multicellular organisms. Thus, the original definition was limited to structures of unicellular organisms.
It would take several years before
organulum, or the later term
organelle, became accepted and expanded in meaning to include subcellular structures in multicellular organisms. Books around 1900 from
Valentin Häcker,
Edmund Wilson
and
Oscar Hertwig still referred to cellular
organs.
Later, both terms came to be used side by side:
Bengt Lidforss wrote 1915 (in German) about "Organs or Organells".
Around 1920, the term organelle was used to describe propulsion structures ("motor organelle complex", for example,
flagella and their anchoring) and other protist structures, such as
ciliates.
Alfred Kühn wrote about
centrioles as division organelles, although he stated that, for
Vahlkampfias, the alternative 'organelle' or 'product of structural build-up' hadn't yet been decided, without explaining the difference between the alternatives.
In his 1953 textbook,
Max Hartmann used the term for extracellular (pellicula, shells, cell walls) and intracellular skeletons of protists.
Later, the now-widely-used
definition of organelle emerged, after which only cellular structures with surrounding
membrane had been considered organelles.
However, the more original definition of subcellular functional unit in general still coexists.
In 1978,
Albert Frey-Wyssling suggested that the term organelle should refer only to structures that convert energy, such as centrosomes, ribosomes, and nucleoli. This new definition, however, didn't win wide recognition.
Examples
Whereas most cell biologists consider the term
organelle to be synonymous with "
cell compartment," other cell biologists choose to limit the term organelle to include only those that are DNA-containing, having originated from formerly-autonomous microscopic organisms acquired via
endosymbiosis.
The most notable of these organelles having originated from
endosymbiont bacteria are:
Other organelles are also suggested to have endosymbiotic origins, (notably the flagellum - see
evolution of flagella).
Not all parts of the cell qualify as organelles, and the use of the term to refer to some structures is disputed. These structures are large assemblies of
macromolecules that carry out particular and specialized functions, but they lack membrane boundaries. Such cell structures, which are not formally organelles, include:
ribosome
cytoskeleton
flagellum.
Eukaryotic organelles
Eukaryotes are the most structurally complex 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 the light microscope. They were among the first biological discoveries made after the invention of the microscope.
Not all eukaryotic cells have every one of the organelles listed below. Exceptional species of cells don't have some organelles that might otherwise be considered universal to eukaryotes
(such as mitochondria). There are also occasional exceptions to the number of membranes surrounding organelles, listed in the tables below (for example, some that are listed as double-membrane are sometimes found with single or triple membranes). In addition, the number of individual organelles of each type found in a given cell varies depending upon the function of that cell.
Major eukaryotic organelles>
| Organelle |
Main function |
Structure |
Organisms |
Notes |
| chloroplast (plastid) |
photosynthesis |
double-membrane compartment |
plants, protists |
has some genes; theorized to be engulfed by the ancestral eukaryotic cell (endosymbiosis) |
| endoplasmic reticulum |
translation and folding of new proteins (rough endoplasmic reticulum), expression of lipids (smooth endoplasmic reticulum) |
single-membrane compartment |
all eukaryotes |
rough endoplasmic reticulum is covered with ribosomes, has folds that are flat sacs; smooth endoplasmic reticulum has folds that are tubular |
| Golgi apparatus |
sorting and modification of proteins |
single-membrane compartment |
all eukaryotes |
cis-face (convex) nearest to rough endoplasmic reticulum; trans-face (concave) farthest from rough endoplasmic reticulum |
| mitochondrion |
energy production |
double-membrane compartment |
most eukaryotes |
has some DNA; theorized to be engulfed by the ancestral eukaryotic cell (endosymbiosis) |
| vacuole |
storage, homeostasis |
single-membrane compartment |
eukaryotes |
|
| nucleus |
DNA maintenance, RNA transcription |
double-membrane compartment |
all eukaryotes |
has bulk of genome |
Mitochondria and chloroplasts, which have double-membranes and their own DNA, are believed to have originated from incompletely consumed or invading prokaryotic organisms, which were adopted as a part of the invaded cell. This idea is supported in the Endosymbiotic theory.
Minor 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 |
| glycosome |
carries out glycolysis |
single-membrane compartment |
Some protozoa, such as Trypanosomes. |
| 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 (for example, proteins + polysaccharides) |
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 |
breakdown of metabolic hydrogen peroxide |
single-membrane compartment |
all eukaryotes |
| ribosome |
translation of RNA into proteins |
RNA-protein |
eukaryotes, prokaryotes |
| vesicle |
material transport |
single-membrane compartment |
all eukaryotes |
Other related structures:
cytosol
endomembrane system
nucleosome
microtubule
cell membrane
Prokaryotic organelles
Prokaryotes are not as structurally or metabolically complex as eukaryotes, and were once thought not to have any internal structures 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. An early false turn was the idea developed in the 1970's that bacteria might contain membrane folds termed mesosomes, but these were later shown to be artifacts produced by the chemicals used to prepare the cells for electron microscopy. However, more recent research has revealed that at least some prokaryotes have microcompartments, which are compartments enclosed by proteins. Even more striking is the description of magnetosomes, as well as the nucleus-like structures of the Planctomycetes that are surrounded by lipid membranes.
Further Information
Get more info on 'Organelles'.
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