This blog intends to display concepts, informations, musics, videos, games, cartoons, curiosities about biochemical issues. Because Biochemistry does not have to be incomprehensible...
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Monday, July 27, 2015
Monday, July 20, 2015
Sunday, July 5, 2015
Cytochrome c and apoptosis
As
mentioned in one of my last posts, cytochrome c is a small protein, essential
for mitochondrial respiratory chain, where it acts as an electron carrier
between the complex III and complex IV. Besides this very important function,
cytochrome c is also an important activator of programmed cell death, or
apoptosis; more specifically, it is an activator of the intrinsic pathway of
apoptosis. Because of this dual role, cytochrome c is often classified as
"a central molecule for life in our oxygen world, and simultaneously a key
that opens the door to death."
While
apoptosis is a form of cell death, it is a fundamental mechanism for keeping
the homeostasis of our body. In fact, when a cell accumulates irreparable
damage (in DNA or in another biomolecule), when placed in an environment where
it may be potentially dangerous to the remaining cells (shortage of nutrients,
detachment from the surrounding cells, deprivation of growth factors,
infection, autoreactive leukocytes, etc.), or when it is not important in the
body (natural selection of neurons, for example) tends to commit suicide -
apoptosis. This obvious idea, but at the same time strange, suggests something
that I often refer in my classes, that is the fact that multicellular organisms
must be regarded not as a living being composed of many cells, but as a living
community, where each cell has its role, and lives in community with the others.
Apoptosis
is a complex process that involves many mediators and that ultimately leads to
the activation of enzymes that promote cell self-digestion. Caspases are a
class of proteases that plays a key role in the apoptotic response. Overall,
there are defined two apoptosis activation mechanisms: the intrinsic pathway
and the extrinsic pathway. The intrinsic pathway is also sometimes referred to
as pathway initiated by the cytochrome c, since this protein is the main actor
in early apoptotic response. Several stimuli can lead to the release of
cytochrome c from the intermembrane space into the cytosol. When this happens,
it starts the activation of caspases. Under normal conditions cytochrome c does
not abandon the intermembrane space, since it interacts with an existing
glycerophospholipid in the inner mitochondrial membrane, cardiolipin. The high
density of negative charges of the phospholipid electrostatically attracts the
positively charged cytochrome c. In addition, a hydrophobic tail of the lipid is
inserted in a hydrophobic cavity of the protein, enhancing the interaction
between both molecules. It is the damage caused on cardiolipin which can make
these interactions to be destroyed and the cytochrome c released.
Once
in the cytosol, cytochrome c promotes the release of calcium stored in the
endoplasmic reticulum, increasing the ion concentration in the cytosol. One of
the functions of calcium is the stimulation of the release of more cytochrome c
into the cytosol, thus causing a positive feedback loop. A further consequence
of the presence of cytochrome c in the cytosol is the activation of caspase 9,
which in turn activates caspases 3 and 7, and the fate of the cell is irreversible
- death by apoptosis!
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