bacterial cell (seen by the fact that only
one cell membrane is present)
Intracellular structures The bacterial cell is surrounded by a
cell membrane, which is made primarily of
phospholipids. This membrane encloses the contents of the cell and acts as a barrier to hold nutrients,
proteins and other essential components within the cell. Unlike
eukaryotic cells, bacteria usually lack large membrane-bound structures in their cytoplasm such as a
nucleus,
mitochondria,
chloroplasts and the other organelles present in eukaryotic cells. However, some bacteria have protein-bound organelles in the cytoplasm which
compartmentalise aspects of bacterial metabolism, such as the
carboxysome. Additionally, bacteria have a multi-component
cytoskeleton to control the localisation of proteins and nucleic acids within the cell, and to manage the process of
cell division. Many important
biochemical reactions, such as energy generation, occur due to
differences in concentration of molecules across membranes, creating a
electrochemical potential analogous to a battery. The general lack of internal membranes in bacteria means these reactions, such as
electron transport, occur across the cell membrane between the cytoplasm and the outside of the cell or
periplasm. However, in many photosynthetic bacteria, the plasma membrane is highly folded and fills most of the cell with layers of light-gathering membrane. These light-gathering complexes may even form lipid-enclosed structures called
chlorosomes in
green sulfur bacteria. of
Halothiobacillus neapolitanus cells with
carboxysomes inside, with arrows highlighting visible carboxysomes. Scale bars indicate 100 nm Bacteria do not have a membrane-bound nucleus, and their
genetic material is typically a single
circular bacterial chromosome of
DNA located in the
cytoplasm in an irregularly shaped body called the
nucleoid. The nucleoid contains the
chromosome with its associated proteins and
RNA. Like all other
organisms, bacteria contain
ribosomes for the
production of proteins, but the structure of the bacterial ribosome is different from that of
eukaryotes and archaea. Its
translation process is also different. Some bacteria produce intracellular nutrient storage granules, such as
glycogen,
polyphosphate,
sulfur or
polyhydroxyalkanoates. Bacteria such as the
photosynthetic cyanobacteria, produce internal
gas vacuoles, which they use to regulate their buoyancy, allowing them to move up or down into water layers with different light intensities and nutrient levels.
Extracellular structures Around the outside of the cell membrane is the
cell wall. Bacterial cell walls are made of
peptidoglycan (also called murein), which is made from
polysaccharide chains cross-linked by
peptides containing D-
amino acids. Bacterial cell walls are different from the cell walls of
plants and
fungi, which are made of
cellulose and
chitin, respectively. The cell wall of bacteria is also distinct from that of archaea, which do not contain peptidoglycan. The cell wall is essential to the survival of many bacteria, and the antibiotic
penicillin (produced by a fungus called
Penicillium) is able to kill bacteria by inhibiting a step in the synthesis of peptidoglycan. '', a genus of
Gram-negative Bacteria. Gram-positive bacteria possess a thick cell wall containing many layers of peptidoglycan and
teichoic acids. In contrast, Gram-negative bacteria have a relatively thin cell wall consisting of a few layers of peptidoglycan surrounded by a second
lipid membrane containing
lipopolysaccharides and
lipoproteins. Most bacteria have the Gram-negative cell wall, and only members of the
Bacillota group and
actinomycetota (previously known as the low G+C and high G+C Gram-positive bacteria, respectively) have the alternative Gram-positive arrangement. These differences in structure can produce differences in antibiotic susceptibility; for instance,
vancomycin can kill only Gram-positive bacteria and is ineffective against Gram-negative
pathogens, such as
Haemophilus influenzae or
Pseudomonas aeruginosa. Some bacteria have cell wall structures that are neither classically Gram-positive or Gram-negative. This includes clinically important bacteria such as
mycobacteria which have a thick peptidoglycan cell wall like a Gram-positive bacterium, but also a second outer layer of lipids. In many bacteria, an
S-layer of rigidly arrayed protein molecules covers the outside of the cell. This layer provides chemical and physical protection for the cell surface and can act as a
macromolecular diffusion barrier. S-layers have diverse functions and are known to act as virulence factors in
Campylobacter species and contain surface
enzymes in
Bacillus stearothermophilus. of
Helicobacter pylori possessing multiple
flagella (
negative staining)
Flagella are rigid protein structures, about 20 nanometres in diameter and up to 20 micrometres in length, that are used for
motility. Flagella are driven by the energy released by the transfer of
ions down an
electrochemical gradient across the cell membrane.
Fimbriae (sometimes called "
attachment pili") are fine filaments of protein, usually 2–10 nanometres in diameter and up to several micrometres in length. They are distributed over the surface of the cell, and resemble fine hairs when seen under the
electron microscope. Fimbriae are believed to be involved in attachment to solid surfaces or to other cells, and are essential for the virulence of some bacterial pathogens.
Pili (
sing. pilus) are cellular appendages, slightly larger than fimbriae, that can transfer
genetic material between bacterial cells in a process called
conjugation where they are called
conjugation pili or sex pili (see bacterial genetics, below). They can also generate movement where they are called
type IV pili.
Glycocalyx is produced by many bacteria to surround their cells, and varies in structural complexity: ranging from a disorganised
slime layer of
extracellular polymeric substances to a highly structured
capsule. These structures can protect cells from engulfment by eukaryotic cells such as
macrophages (part of the human
immune system). They can also act as
antigens and be involved in cell recognition, as well as aiding attachment to surfaces and the formation of biofilms. The assembly of these extracellular structures is dependent on
bacterial secretion systems. These transfer proteins from the cytoplasm into the periplasm or into the environment around the cell. Many types of secretion systems are known and these structures are often essential for the
virulence of pathogens, so are intensively studied. Some
genera of Gram-positive bacteria, such as
Bacillus,
Clostridium,
Sporohalobacter,
Anaerobacter, and
Heliobacterium, can form highly resistant, dormant structures called
endospores. Endospores develop within the cytoplasm of the cell; generally, a single endospore develops in each cell. Each endospore contains a core of
DNA and
ribosomes surrounded by a cortex layer and protected by a multilayer rigid coat composed of peptidoglycan and a variety of proteins. In this dormant state, these organisms may remain viable for millions of years. Endospores even allow bacteria to survive exposure to the
vacuum and radiation of
outer space, leading to the possibility that bacteria could be distributed throughout the
universe by
space dust,
meteoroids,
asteroids,
comets,
planetoids, or
directed panspermia. Endospore-forming bacteria can cause disease; for example,
anthrax can be contracted by the inhalation of
Bacillus anthracis endospores, and contamination of deep puncture wounds with
Clostridium tetani endospores causes
tetanus, which, like
botulism, is caused by a toxin released by the bacteria that grow from the spores.
Clostridioides difficile infection, a common problem in healthcare settings, is caused by spore-forming bacteria. == Metabolism ==