The Plasma Membrane
Plasma membrane (cytoplasmic membrane) is an absolute requirement for all
living beings as it is the chief point of contact with the cells environment
and thus is responsible for much of its relationships with the outside world.
If the membrane is broken, the integrity of the cell is destroyed and the
internal contents leak into the environment resulting in the death of the cell.
(i) Structure
The
plasma membrane is approximately 7.5 nm (0.0075 μm) thick, forms the limiting
boundary of the cell and is made up of phospholipids (about 20-30%) and
proteins (about 60-70%). Several models have been proposed to explain the
ultrastructure of the plasma membrane, the most widely accepted one is Fluid
Mosaic Model introduced by Singer and Nicolson (1974). According to this model
the membrane is a bi-layer of phospholipids and the two
opposing layers of phospholipids overlap slightly; each phospholipid molecule
consisting of a phosphate group and a lipid.
Each
phospholipid is structurally asymmetric with polar and nonpolar ends and is
called amphipathic. The polar ends interact with water and are hydrophilic; the
nonpolar ends do not interact with water (i.e. insoluble in water) and are
hydrophobic. The hydrophilic ends occur towards the outer surface of the
membrane whereas the hydrophobic ends are burried in the interior away from the
surrounding water.
Digrammatic
representation of the fluid mosaic model of plasma membrane
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1.
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Outside Cell
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7.
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Hydrophobic Region of Integral Protein
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2.
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Inside Cell
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8.
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Polar (Phosphate)
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3.
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Extrainsic or Peripheral Protein
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9.
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Non Polar (Lipid)
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4.
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Intrinsic or Integral Protein
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10.
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Non Polar (Lipid)
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5.
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Hopanoids
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11.
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Polar (Phosphate)
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6.
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Hydrophilic Region of Integral Protein
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12.
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Phospholipid Bilayer
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The structure of Phosphatidylethanolamine, an
amphipathic phospholipid usually occuring in bacterial plasma membrane. R =
long, nonpolar fatty acid chains
The
bi-layer phospholipid is interrupted by proteins which are distributed in a
mosaic-like pattern. Some of the proteins are confined to the outer surface of
bilipid layer (extrinsic or peripheral proteins) and others are partially or
totally buried within it (intrinsic or integral proteins). The integral
proteins, like membrane lipids, are amphipathic. Their hydrophobic regions are
burried in the lipid while the hydrophilic regions project out from the plasma
membrane surface.
A common hopanoid (bacteriohopanetetrol) occuring in bacterial plasma
membrane
Often
carbohydrates are attached to the outer surface of plasma membrane proteins and
seem to perform important functions. Both proteins and lipids move within the
phospholipid matrix of the membrane. However, many bacterial plasma membranes
do contain pentacyclic sterol-like molecules called hopanoids
which are synthesized from the same precursors as steroids. Like steroids in
eukaryotic cells, hopanoids are thought to provide stability to bacterial
plasma membrane.
(ii) Differences with Eukaryotic Plasma membrane
Although
the bacterial plasma membrane resembles its counterpart of eukaryotic cells, it
differs from the latter in two distinctive features:
(a)
Sterols (such as cholesterols) that occur in eukaryotic cell membranes are
absent in bacteria (except in the mycoplasmas that do not have cell wall).
These substances help stabilize the phospholipids in eukaryotic membrane and
make it more rigid.
(b)
The proportion of protein to phospholipids is high (typically 2: 1 in
prokaryotes, and 1: 1 or less in eukaryotes).
Functions
The plasma membrane is of extreme importance to the cell and performs following important functions:
1. Being differentially permeable barrier, the plasma membrane regulates the flow of materials, in and out of the cell i.e. it selectively restricts movement of molecules in and out. Thus, the plasma membrane prevents the loss of essential components through leakage while allowing the movement of other molecules.
2. It contains enzymes that mediate in the synthesis of membrane lipids and various other macromolecules that compose the bacterial cell wall.
3. It is the site of enzymes and carriers of electron transport system that generates ATP from ADP.
4. It contains specific attachment sites of the chromosome and for plasmids, and that it plays an active role in their replication at the time of cell division.
The plasma membrane is of extreme importance to the cell and performs following important functions:
1. Being differentially permeable barrier, the plasma membrane regulates the flow of materials, in and out of the cell i.e. it selectively restricts movement of molecules in and out. Thus, the plasma membrane prevents the loss of essential components through leakage while allowing the movement of other molecules.
2. It contains enzymes that mediate in the synthesis of membrane lipids and various other macromolecules that compose the bacterial cell wall.
3. It is the site of enzymes and carriers of electron transport system that generates ATP from ADP.
4. It contains specific attachment sites of the chromosome and for plasmids, and that it plays an active role in their replication at the time of cell division.
Mesosomes
In most of the bacteria cells (particularly Gram-positive ones) the plasma membrane shows characteristic infoldings either superficially or significantly deep, invading the cytoplasm. These infoldings are called Mesosomes, the term coined by Fitzjames. The bacterial DNA (chromosome) is always attached to or closely associated with mesosomes. Mesosomes are considered to play in important role in the intiation of replication of bacterial DNA and the septa formation at the time of cell division (Higgins and Shockmann, 1971). They act as sites of respiratory activity as well.
In most of the bacteria cells (particularly Gram-positive ones) the plasma membrane shows characteristic infoldings either superficially or significantly deep, invading the cytoplasm. These infoldings are called Mesosomes, the term coined by Fitzjames. The bacterial DNA (chromosome) is always attached to or closely associated with mesosomes. Mesosomes are considered to play in important role in the intiation of replication of bacterial DNA and the septa formation at the time of cell division (Higgins and Shockmann, 1971). They act as sites of respiratory activity as well.
Mesosomes Real Structures
Although many functions have been proposed
for Mesosomes, it has been found during the recent past that the bacterial
cells with no apparent Mesosomes were not defective for such functions. The
promoted to reevaluate the evidence for the existence of Mesosomes were always
observed attached to or closely associates with bacterial DNA in electron
microscopic observations were frozen in liquid nitrogen and then exposed to
X-rays to break up the DNA before the cells were dehydrates for electron microscopy.
When this procedure was followed, no
Mesosomes were observed in such cells. This suggests that the observed
Mesosomes were artifacts of preparations for electron microscopic observation,
formed by DNA pulling on the plasma membrane when the cell was dehydrated. The
current view, therefore, is that Mesosomes are artifacts rather than real
structures of the bacterial cell with definite functions.
The Cytoplasmic Inclusions
The cytoplasm of most prokaryotes lacks
chloroplasts, mitochondria, and all other membrane-bound organelles of
cytoplasmic origin such as endoplasmic reticulum and Golgi bodies. Therefore,
it is a homogenous aqueous solution of soluble proteins, cell solutes,
metabolites of smaller molecular weights, and inorganic ions. It contains many
enzymes, tRNAs, amino acids and a large amount of RNA collected into ribosomes.
Granules and cell inclusions of various types, e.g. polyphosphates (volutin
granules or metachromatin granules), poly-β-hydroxybutyrate (DHB), glycogen,
gas vacuoles, magnetosomes, sulphur inclusions, carboxysomes, etc., are
sometimes observed in the cytoplasm.
Ribosomes
Ribosomes are small granular bodies of 10-20 nm in diameter freely lying in the cytoplasm and composed of ribosomal ribonucleic acid (rRNA) and proteins. Bacterial ribosomes are thought to contain about 80-85% of the bacterial RNA. Sometimes, they are found in small groups called polyribosomes or polysomes, which are formed when several ribosomes begin to translate a single mRNA molecule. Each ribosome has sedimentation coefficient of 70 S and a mass of 2.8 x 106 daltons, and is made up of two subunits of 50 S and 30 S, each subunit consisting of roughly equal amounts of rRNA and protein. Ribosomes are functional only when the two subunits are combined together.
The association and dissociation of two subunits of ribosomes depend on the concentration of Mg++ ions. Each 50 S subunit (mass of 1.8 x 106 daltons) contains one molecule of 23 S rRNA (having approximately 3200 nucleotides), one molecule of 5 S rRNA (having only about 120 nucleotides) and 34 different proteins designated as L1 to L34; while the 30 S subunit (mass of 0.9 x 106 daltons) contains one molecule of 16 rRNA (having approximately 1540 nucleotides) and 21 different proteins designated as S 1 to S21.
Ribosomes are small granular bodies of 10-20 nm in diameter freely lying in the cytoplasm and composed of ribosomal ribonucleic acid (rRNA) and proteins. Bacterial ribosomes are thought to contain about 80-85% of the bacterial RNA. Sometimes, they are found in small groups called polyribosomes or polysomes, which are formed when several ribosomes begin to translate a single mRNA molecule. Each ribosome has sedimentation coefficient of 70 S and a mass of 2.8 x 106 daltons, and is made up of two subunits of 50 S and 30 S, each subunit consisting of roughly equal amounts of rRNA and protein. Ribosomes are functional only when the two subunits are combined together.
The association and dissociation of two subunits of ribosomes depend on the concentration of Mg++ ions. Each 50 S subunit (mass of 1.8 x 106 daltons) contains one molecule of 23 S rRNA (having approximately 3200 nucleotides), one molecule of 5 S rRNA (having only about 120 nucleotides) and 34 different proteins designated as L1 to L34; while the 30 S subunit (mass of 0.9 x 106 daltons) contains one molecule of 16 rRNA (having approximately 1540 nucleotides) and 21 different proteins designated as S 1 to S21.
The Structure of the prkaryotic ribosome
As in eukaryotes, ribosomes
are the sites of protein synthesis and, therefore, antibiotics such as
streptomycin and chloramphenicol specifically inhibit protein synthesis by
attacking ribosomes. Generally, the ribosomes are a few hundred in. number in
each bacterial cell, but when the cell undertakes active protein synthesis,
they increase in number to as many as 15,000-20,000 per cell, about 15% of the
cell mass.
Polyphosphates (Volutin Granules or Metachromatin Granules)
Many
bacteria and microalgae accumulate phosphates in the form of polyphosphates
(Fig. 3.21). Because they were first described in Spirillum volutans and
because they bring about characteristic changes in the pigmentation of certain
dyes, they have been given the name volutin granules and metachromatin
granules respectively. These granules are composed of
polymetaphosphate and are common in diphtheria bacillus and in certain lactic
acid bacteria.
These granules stained reddish with blue dyes (e.g., methylene blue), are highly refractive and hence are easily observable under light microscope. The volutine granules represent intracellular phosphate reserve when nucleic acid synthesis does not occur, and when the latter starts, this phosphate is incorporated into the nucleic acids.
Polyphosphate Structure
These granules stained reddish with blue dyes (e.g., methylene blue), are highly refractive and hence are easily observable under light microscope. The volutine granules represent intracellular phosphate reserve when nucleic acid synthesis does not occur, and when the latter starts, this phosphate is incorporated into the nucleic acids.
Polyphosphate Structure
Poly-β-hydroxybutyrate
(PHB)
Poly-β-hydroxybutyrate
(PHB) is a lipid-like compound. It is formed from β-hydroxybutyrate units
joined by ester-linkages resulting in long PHB polymer which aggregate into
granules of around 0.2-0.7 μm in diameter. PHB is accumulated by aerobic and
facultative bacteria when the cells are deprived of oxygen and must carry out
fermentative metabolism. On return of aerobic conditions, PHB is used as an
energy and carbon source and incorporated into the oxidative metabolism.
Structure of polu-β-hydroxy butyrate
Some bacteria produce co-polymers of PHB often referred to as poly-β-hydroxy-alkanoate (PHA). The latter can be thermoplastically moulded and used as new plastics that shows advantage over conventional plastics (polypropylene or polyethylene) of being biodegradable.
Glycogen
Glycogen
like PHB, is another storage product formed by prokaryotes. It is a polymer of
glucose units composed of long chains formed by α(l → 4) glycosidic bonds
and branching chains connected to them by α (1 → 6) glycosidic bonds.
Glycogen is dispersed more evenly throughout the cytoplasmic matrix as small
(about 20 - 100 nm in diameter) and is a storage reservoir for carbon and
energy. Glycogen is also known as animal starch and, besides
prokaryotes, is found in fungi.
Glycogen Structure
Gas Vacuoles
These
are single membrane vacuoles formed as a result of the aggregation of enormous
number of small, hollow, cylindrical structures called gas vesicles. Each gas
vacuole appears about 75 nm in diameter with conical ends and about 200-1,000
nm in length. They characteristically occur in many aquatic bacteria,
especially purple and green photosynthetic ones. These bacteria float at or
near the surface of water because gas vacuoles give them buoyancy. Bacteria
possessing gas vacuoles can regulate their buoyancy to float at the depth
necessary for proper light intensity, oxygen concentration, and nutrient
levels. They descend by simply collapsing vesicles and further float upward
when new one are formed.
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