In comparison to
eukaryotes, the intracellular (internal) features of the bacterial cell are extremely simple. Bacteria do not typically contain eukaryotic membrane-bound
organelles, but often contain other complex intracellular structures.
The bacterial DNA and plasmids Unlike
eukaryotes, the bacterial
DNA is not enclosed inside of a membrane-bound
nucleus but instead resides inside the
cytoplasm. The processes concerning the transfer of genetic information —
translation,
transcription, and
DNA replication — therefore all occur within the same compartment and can interact with other cytoplasmic structures, most notably
ribosomes. Bacterial DNA can be located in two places: • Bacterial chromosome, located in the irregularly shaped region known as the
nucleoid •
Extrachromosomal DNA, located outside of the nucleoid region as circular or linear
plasmids The bacterial DNA is not packaged using
histones to form
chromatin as in
eukaryotes but instead exists as a highly compact
supercoiled structure, the precise nature of which remains unclear. Most bacterial chromosomes are
circular, although some examples of linear chromosomes exist (e.g.
Borrelia burgdorferi). Usually, a single bacterial chromosome is present, although some species with multiple chromosomes have been described. Examples of
bacteria containing intracellular membranes are
phototrophs (ex.:
thylakoid),
nitrifying bacteria (ex.:
anammoxosome) and
methane-oxidising bacteria such as the
methylococcaceae. Intracellular membranes are also found in
bacteria belonging to the poorly studied
Planctomycetota group, although these membranes more closely resemble organellar membranes in
eukaryotes and are currently of unknown function.
Chromatophores are intracellular membranes found in
phototrophic bacteria. Used primarily for photosynthesis, they contain
bacteriochlorophyll pigments and carotenoids.
Cytoskeleton The
prokaryotic cytoskeleton is the collective name for all structural
filaments in
prokaryotes. It was once thought that prokaryotic cells did not possess
cytoskeletons, but advances in imaging technology and structure determination have shown the presence of filaments in these cells.
Homologues for all major cytoskeletal proteins in
eukaryotes have been found in prokaryotes. Cytoskeletal elements play essential roles in
cell division, protection, shape determination, and polarity determination in various prokaryotes.
Nutrient storage structures Most
bacteria do not live in environments that contain large amounts of nutrients at all times. To accommodate these transient levels of nutrients,
bacteria contain several different methods of nutrient storage in times of plenty for use in times of want. For example, many
bacteria store excess carbon in the form of
polyhydroxyalkanoates or
glycogen. Some microbes store soluble nutrients such as
nitrate in
vacuoles. Sulfur is most often stored as elemental (S0) granules which can be deposited either intra- or extracellularly. Sulfur granules are especially common in
bacteria that use
hydrogen sulfide as an electron source. Most of the above-mentioned examples can be viewed using a
microscope and are surrounded by a thin nonunit membrane to separate them from the
cytoplasm.
Inclusions Inclusions are considered to be nonliving components of the cell that do not possess metabolic activity and are not bounded by membranes. The most common inclusions are glycogen, lipid droplets, crystals, and pigments.
Volutin granules are cytoplasmic inclusions of complexed inorganic polyphosphate. These granules are called
metachromatic granules due to their displaying the metachromatic effect; they appear red or blue when stained with the blue dyes methylene blue or toluidine blue.
Gas vacuoles Gas vacuoles are membrane-bound, spindle-shaped
vesicles, found in some
planktonic bacteria and
Cyanobacteria, that provides
buoyancy to these cells by decreasing their overall cell
density. Positive buoyancy is needed to keep the cells in the upper reaches of the water column, so that they can continue to perform
photosynthesis. They are made up of a shell of protein that has a highly
hydrophobic inner surface, making it impermeable to water (and stopping water vapour from condensing inside) but permeable to most
gases. Because the gas vesicle is a hollow cylinder, it is liable to collapse when the surrounding
pressure increases. Natural selection has fine tuned the structure of the gas vesicle to maximise its resistance to
buckling, including an external strengthening protein, GvpC, rather like the green thread in a braided hosepipe. There is a simple relationship between the diameter of the gas vesicle and pressure at which it will collapse – the wider the gas vesicle the weaker it becomes. However, wider gas vesicles are more efficient, providing more buoyancy per unit of protein than narrow gas vesicles. Different species produce gas vesicle of different diameter, allowing them to colonise different depths of the water column (fast growing, highly competitive species with wide gas vesicles in the top most layers; slow growing, dark-adapted, species with strong narrow gas vesicles in the deeper layers). The diameter of the gas vesicle will also help determine which species survive in different bodies of water. Deep lakes that experience winter mixing expose the cells to the hydrostatic pressure generated by the full water column. This will select for species with narrower, stronger gas vesicles. The cell achieves its height in the water column by synthesising gas vesicles. As the cell rises up, it is able to increase its
carbohydrate load through increased photosynthesis. Too high and the cell will suffer photobleaching and possible death, however, the carbohydrate produced during photosynthesis increases the cell's density, causing it to sink. The daily cycle of carbohydrate build-up from photosynthesis and carbohydrate
catabolism during dark hours is enough to fine-tune the cell's position in the water column, bring it up toward the surface when its carbohydrate levels are low and it needs to photosynthesis, and allowing it to sink away from the harmful
UV radiation when the cell's carbohydrate levels have been replenished. An extreme excess of carbohydrate causes a significant change in the internal pressure of the cell, which causes the gas vesicles to buckle and collapse and the cell to sink out.
Microcompartments Bacterial microcompartments are widespread, organelle-like structures that are made of a protein shell that surrounds and encloses various enzymes. provide a further level of organization; they are compartments within bacteria that are surrounded by polyhedral protein shells, rather than by lipid membranes. These "polyhedral organelles" localize and compartmentalize bacterial metabolism, a function performed by the membrane-bound organelles in eukaryotes.
Carboxysomes Carboxysomes are bacterial microcompartments found in many
autotrophic bacteria such as Cyanobacteria, Knallgasbacteria, Nitroso- and Nitrobacteria. They are proteinaceous structures resembling phage heads in their
morphology and contain the enzymes of carbon dioxide fixation in these organisms (especially ribulose bisphosphate carboxylase/oxygenase, RuBisCO, and carbonic anhydrase). It is thought that the high local concentration of the enzymes along with the fast conversion of bicarbonate to carbon dioxide by carbonic anhydrase allows faster and more efficient carbon dioxide fixation than possible inside the cytoplasm. Similar structures are known to harbor the coenzyme B12-containing
glycerol dehydratase, the key enzyme of glycerol fermentation to 1,3-propanediol, in some Enterobacteriaceae (e. g. Salmonella).
Magnetosomes Magnetosomes are bacterial microcompartments found in
magnetotactic bacteria that allow them to sense and align themselves along a magnetic field (
magnetotaxis). The ecological role of magnetotaxis is unknown but is thought to be involved in the determination of optimal oxygen concentrations. Magnetosomes are composed of the mineral
magnetite or
greigite and are surrounded by a lipid bilayer membrane. The morphology of magnetosomes is species-specific. == Endospores ==