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Bacteria are fascinating, microscopic organisms. One of the most fascinating aspects about them is their duality; they are both extraordinarily good for us and simultaneously terribly bad for us. This duality is dependent on the specific bacteria, the time, the place, and the function in that place. We need to recognize the features of specific bacteria; from their gram stain, to their primary method of metabolism, to what they contribute to our ecosystem. This helps us to categorize bacteria individually and to have a better understanding of bacteria as a group and microbiology as a subject.
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Jetzt kostenlos anmeldenBacteria are fascinating, microscopic organisms. One of the most fascinating aspects about them is their duality; they are both extraordinarily good for us and simultaneously terribly bad for us. This duality is dependent on the specific bacteria, the time, the place, and the function in that place. We need to recognize the features of specific bacteria; from their gram stain, to their primary method of metabolism, to what they contribute to our ecosystem. This helps us to categorize bacteria individually and to have a better understanding of bacteria as a group and microbiology as a subject.
Bacteria are defined as a group of unicellular microorganisms, some of which cause disease, that is distinguished by the following features - the presence of a cell wall, the lack of discrete organelles, and the lack of an organized nucleus.
We can discuss each of the above three features in greater detail.
In the great division of living organisms between prokaryotes and eukaryotes, bacteria are firmly in the prokaryotic category.
Prokaryotes are defined by their lack of nuclei and organelles, a fact that is consistent with the appearance of bacteria.
The other member of the group Prokaryote is Archaea.
The reason bacteria do not have organelles or nuclei is not that they lack genomes, or lack enzymes and enzymatic activity that might otherwise be found within an organelle in eukaryotes (such as humans). Bacteria have genomes, certainly, and have enzymes ranging from urease to penicillin-binding proteins that can lead to penicillin resistance in certain infections. However, bacteria lack organelles and any nucleus because they lack internal membranes within their cells. The sole membrane typically present in bacteria is their cell/plasma membrane. This is in contrast to humans and other eukaryotes that have membranes for their lysosomes, their mitochondria, their peroxisomes, and many other organelles found within them.
You can find the components of the bacterial cell (seen below in Bacteria structure) lying directly within their cellular cytoplasm.
We know the differences between the structure of a gram-negative and a gram-positive bacterial cell wall. But what about the other components that make up the ultrastructure of the bacterium?
We will discuss these structures from the outermost to the innermost, so we can have a good idea of each component's placement and location, as well as its function. Remember that not all these features are common to all bacteria.
Flagella - these are attached to and located on the outside of the capsule (we'll get to that in a second!). The primary function of flagella is movement, they help facilitate chemotaxis, which is when an organism moves closer to some chemical stimulus (often food). Flagella cause a propeller-like movement that helps the bacteria to tumble and swim.
Flagella are made of flagellin - a protein.
These flagellin subunits are joined together to form a hair-like tube that's hollow on the inside.
Attaching the flagella o the capsule is a motor,
Flagella can be monotrichous - a single flagellum, located at one side, the end of a bacterium.
Flagella can be peritrichous - multiple flagella, located all over the bacteria.
Flagella can be lophotrichous - multiple flagella, located at one side, the end of the bacterium.
Pilus - also known as the sex pilus, these may be mistaken for flagella at times but they have very different uses and structures. Pili help bacteria to do conjugation, also known as bacterial sex, where virulence genes are passed from one bacteria to the next. These genes are passed typically, on a plasmid (we'll get to that in a bit!).
Capsule - this is a layer on the outside of bacteria, made of polysaccharides.
Capsules are often considered virulence factors, which are traits that increase the bacteria's ability to infect and its pathogenicity. This is because capsules help bacteria evade phagocytosis.
Cell wall - we will elaborate on the bacterial cell wall below. It is made of peptidoglycan and differs in thickness based on whether the bacteria are gram-negative or gram-positive.
Plasma membrane - this is a lipid bilayer membrane. Like our own plasma membranes, they are semi-permeable and allow for certain solutes to pass through.
Mesosome - although this is may be listed as a special component of bacteria, it is just an invagination of the plasma membrane. This is not a native structure of bacteria, but rather these invaginated folds are created during certain chemical fixing processes that scientists use to visualize bacteria.
Cytoplasm - the cytoplasm of bacterial cells is actually rather thick, and gel-like. It's the central location for many of the enzymes, ribosomes, proteins, nutrients, and assorted cell structures of the bacteria.
Plasmid - this is extra, circular, double-stranded DNA that a bacteria may have within its cytoplasm. Typically, the genes on a plasmid promote virulence and antibiotic resistance, and they can be passed from bacteria to bacteria through the pili.
Plasmids replicate independently of the bacterial genome properly.
DNA (nucleoid) - this is the bacterial genome or chromosome.
Note that it's not encased in a nucleus, there are no organelles in prokaryotes.
The bacterial genome is circular, double-stranded DNA.
Inclusion body - these are folded aggregates of proteins, called amyloids.
their exact function is unknown
some scientists think they form as a result of dynamic shifts in protein formation
Ribosome - prokaryotic ribosomes make proteins from mRNA transcripts, just as ours do. However, the particular subunits that make up the ribosomes of bacteria differ from ours.
A bacteria cell diagram will help you understand the shape and positioning of each of the organelles described above.
Bacteria have cell walls located outside of their cell membrane. The cell wall is made up of sugar (glycan) chains connected by short peptides, hence it is given the name peptidoglycan. The peptidoglycan cell walls form a dense, mesh-like structure; known as a crystal lattice, as the glycan chains connect to each other via their peptides, by cross-linking them.
An alternate name you might see for peptidoglycan in some sources is murein. They are the same thing!
There are two sugars that comprise peptidoglycan; NAG and NAM (for N-acetylglucosamine and N-acetylmuramic acid, respectively). NAM is the glycan that contains the peptide attachment; called an oligopeptide.
An oligopeptide is just a short chain of amino acids, and in the case of NAM, the amino acids are a mix of L-amino acids and D-amino acids, the latter of which is quite rare.
NAG and NAM attach to each other directly on the same chain, and then two NAM molecules on adjacent chains form a cross-link between their oligopeptides.
The cell wall functions to give the bacteria its shape, as well as to protect it from external environmental factors and lysis, two very essential functions.
Many common antibiotics, such as penicillin, target the formation of the bacterial cell wall, because of their importance in maintaining many bacterial lives.
Nonetheless, it's important to remember that not all bacteria have a cell wall, and not all bacterial cell walls are created equally. In fact, we can classify the types of bacteria based on the presence of, and then the nature of, their cell walls.
Based on the features of their cell wall apparatus (or lack thereof) bacteria can be grouped into the following categories:
Gram-positive bacteria
Bacteria without a cell wall
We will go through each in turn.
Gram-positive bacteria have thick peptidoglycan cell walls. This is their most distinguishing feature (as a group) and is also what allows them to stain violet on Gram Stain.
Yes, we have an article on that!
The cell wall of a gram-positive bacterium can be anywhere from 15 to 80 nanometers thick. Each nanometer is 1-7 of a centimeter, and while this might not sound like much, in the land of bacteria and prokaryotes, this makes for quite a thick layer.
Sticking out of the cell wall, in gram-positive bacteria, are teichoic and lipoteichoic acids. The functions of these are not yet fully understood, but scientists think adherence may be one of their main purposes. They may help bacteria stick to an assortment of surfaces.
Gram-negative bacteria, on the other hand, have thin peptidoglycan cell walls. Outside of these walls, they often have an outer membrane; another feature that helps distinguish them from Gram-positive bacteria. Gram-negative bacteria stain pink on gram stain.
Read more in the Gram Negative Bacteria article!
Deeper within the gram-negative bacterial cell, there is a periplasm or a periplasmic space. This is a space filled with a rather thick, gel-like matrix, that is the site of important enzymes and proteins that promote bacterial existence.
We have waxed poetic on the importance of the bacterial cell wall, and while this is true, it is not so for every organism. Some bacteria, most notably a species of bacteria called Mycoplasma, but also many others, totally lack a cell wall. These bacteria are sometimes called gram-indeterminate, but may also be merely acknowledged as "not able to be gram stained" because they do not pick up any color - neither purple nor pink.
Often times these cell wall-less bacteria have to live in an osmotically stable environment (i.e. in humans!), and they may have different components of their cell membranes than other bacteria do.
For example; Mycoplasma bacteria have sterols in their cell membranes. This increases the membrane stability, of especial importance in an organism lacking a cell wall.
Bacteria can also be categorized by their method of cellular respiration (Table 1). Bacteria can be aerobic, or anaerobic. When we say respiration in this case, we are not talking about breathing with lungs; rather we are referring more to metabolism and growth. What are the substances that bacteria can take from the environment and utilize for energy, and what kind of environment can particular bacteria live in?
Table 1: Aerobic vs anaerobic bacteria.
Aerobic Bacteria | Anaerobic Bacteria | |
Requirements for growth | - Strict aerobes: must utilize oxygen for growth, metabolism, reproduction, etc.- Microaerophiles: can only use oxygen for growth but need smaller amounts of it than are available in most open air. | - Do not require oxygen for growth.- Facultative anaerobes can live with oxygen, but don't need it.- Strict anaerobes cannot live with oxygen at all, think of it as though oxygen is poisonous to them. |
Classic species | E. coli, Fusobacterium | Pseudomonas, Bacillus |
Features of organisms that affect humans | Tend to infect open wounds (oxygen-rich regions), that can easily be exposed to air or water. | Tend to reside and infect places where "the sun don't shine" (oxygen-poor regions), such as your guts - causing diarrhea, and your teeth - causing tooth infections. |
Final electron acceptor | Oxygen | Some non-oxygen molecule: like carbon dioxide, sulfur, nitrate, etc. |
Energy production | Aerobic bacteria produce more oxygen than anaerobic. | Anaerobic bacteria produce less oxygen than aerobic. |
A few very known examples of bacteria are Escherichia coli, Yersinia pestis, or the genus Lactobacillus. Let's look at them in more detail.
Bacteria are defined as a group of unicellular microorganisms, some of which cause disease, that is distinguished by the following features - the presence of a cell wall, the lack of discrete organelles, and the lack of an organized nucleus.
No, bacteria do not have a nucleus (they are prokaryotes). Bacteria's DNA is floating in the cytoplasm.
Bacteria reproduce through binary fission. Binary fission is a type of asexual reproduction in which the mother cell divides into two daughter cells.
Bacteria can have cell walls. They are made out of peptidoglycans (a carbohydrate bound to a short peptide).
Yes, they are living microorganisms, as they comply with the rules which classify any organism as living: they reproduce, they have metabolism (consume energy), they are made of cells, they can adapt and respond to their environment, they grow and develop, and they strive to keep a stable inner environment (homeostasis).
Bacteria need nutrients, moisture and a certain temperature to grow. The specific conditions for each of these variables will depend on the strain of bacteria we are trying to grow. In laboratories bacteria are grown in incubators to ensure a stable environment.
No, bacteria do not have mitochondria because they do not have any membrane-bound organelles.
Each type of bacteria can cause disease through a different mechanism. However, most bacteria cause disease because they release toxins, they invade, overpower or destroy the host's cells, they consume nutrients required by the host and/or they activate the immune response of the host.
Bacteria ____ membrane bound organelles
Lack
Which bacteria have lipoteichoic acids
Gram positive
Which bacteria have outer membranes
Gram positive
What is the most virulent part of the bacterial outer membrane
Lipid A
Mycoplasma are gram____
indeterminate. Not able to gram stain
What is unique about mycoplasma
They lack cell walls
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