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Gram-negative bacteria are classified as such due to their appearance after a gram stain test. They have certain physical properties, that while invisible to the naked eye, allow them to pick up particular dyes in gram staining, which belie the characteristics of their cell wall and other structures. We will examine these properties of gram-negative bacteria and, by doing so, see the differences that distinguish gram-negative bacteria from gram-positive bacteria.
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Jetzt kostenlos anmeldenGram-negative bacteria are classified as such due to their appearance after a gram stain test. They have certain physical properties, that while invisible to the naked eye, allow them to pick up particular dyes in gram staining, which belie the characteristics of their cell wall and other structures. We will examine these properties of gram-negative bacteria and, by doing so, see the differences that distinguish gram-negative bacteria from gram-positive bacteria.
The contents of the cell are contained in the plasma membrane. Outside of this is the periplasmic space. Beyond that is the peptidoglycan cell wall, and lastly we have the outer membrane. We will go over each layer and its specific contents one by one, below.
Plasma membrane
Periplasmic space
The periplasmic space is present between the inner and outer membranes of gram-negative bacteria. It presents a significant portion of the space that gram-negative bacteria occupy.
The periplasmic space is an environment for enzymatic activity, including:
Protein folding
Production of substances for secretion by the bacterium
The peptidoglycan cell wall is present within the periplasmic space, but we will discuss this in its own section, below.
Peptidoglycan cell wall
The peptidoglycan cell wall in gram-negative bacteria is quite thin, much thinner than in gram-positive bacteria. This is especially relevant with gram staining.
Atop the peptidoglycan layer are lipoproteins called "Braun's Lipoproteins", which help attach the peptidoglycan cell wall to the outer membrane beyond it.
Outer membrane
The outer membrane of gram-negative bacteria is made up of another lipid bilayer, uniquely present outside of its cell wall.
Different proteins may be present in this lipid bilayer
The transmembrane proteins, peripheral proteins, and integral proteins can be seen as a part of the cytoplasmic membrane bilayers and may be seen here in the outer membrane again.
Porins - channels made up of protein subunits that facilitate the movement of substances in and out of the cell.
These porins act, as you could guess, as pores. When closed, they reduce permeability and, when open, increase permeability.
Lipopolysaccharides are present as the last and most important constituent of gram-negative bacterial cell membranes (Fig. 3).
There are three parts of lipopolysaccharide molecules (also called LPS).
Two of those parts are made up of carbohydrates, and one is made up of lipids.
The innermost part of LPS, which intercalates within the outer leaflet of the outer membrane, is called lipid A
The outermost part of LPS is called the O antigen or the O-polysaccharide.
Between lipid A and the O-polysaccharide is the core polysaccharide.
What are the properties that arise from each feature of a gram-negative bacterial cell, its cell wall, and its membranes? We will examine them one by one.
A thin peptidoglycan cell wall facilitates the color change from purple to pink, seen during gram staining. The first step of gram staining - primary stain - involves dying the cell purple. The second step - fixing - helps to fix this color to the cell's wall. However, because of the thin, highly porous cell wall in gram-negative bacteria, alongside the lipid-rich outer membrane that is easily lyzed by alcohol, the third step - decolorizing - easily washes out the purple stain and leaves the gram-negative bacterial cell colorless. Thus, in the fourth and final step - counterstaining with safranin - the gram-negative bacteria are free to pick up the pink color of the second dye. Hence, gram-negative bacteria are pink after gram staining.
What are some examples of gram-negative bacteria? We can group them according to their morphology. Cocci are spherical or circular, bacilli are rod-shaped, and coccobacilli are some intermediate of the two. We will list them by genus.
Gram-negative bacteria have a bit more diversity of shape than gram-positive bacteria do. For example, there are gram-negative spiral-shaped bacteria, which we do not see in gram-positive bacteria.
Cocci
Bacilli
Spiral shaped
Coccobacilli
Gram-negative bacteria and gram-positive bacteria have quite a few differences in structure. These differences help decide what organisms, and what organs within those organisms, they can infect. These differences also help define their classification, which is important both when diagnosing and studying these pathogens. It can even help medical doctors decide what kind of antibiotic or treatment is preferable, as the activity of certain medications are stronger in gram-negative vs gram-positive bacteria, and vice versa. We will outline the differences between gram-positive and gram-negative bacteria below.
Difference #1: Gram-negative bacteria have a relatively quite thin peptidoglycan cell wall. Gram-positive bacteria, on the other hand, have a large, thick peptidoglycan cell wall.
Difference #2: Gram-negative bacteria lack both lipoteichoic acids and teichoic acids. Gram-positive bacteria can, and frequently do, have both.
Difference #3: Gram-negative bacteria have lipopolysaccharides on the outer leaflet of their outer membrane, beyond their cell walls. Gram-positive bacteria do not have an outer leaflet or lipopolysaccharides, their best version of highly virulent agents are their lipoteichoic acids.
Difference #4: Gram-negative bacteria have an outer membrane. Gram-positive bacteria, on the other hand, do not. They have only a single cell membrane, beneath their cell wall. This is the standard cytoplasmic membrane that gram-negative bacteria have in addition to their outer membrane.
Difference #5: Gram-negative bacteria are defined by the pink color they assume after the process of gram staining is complete. Gram-positive bacteria are defined by their purple color.
Gram-negative bacteria are bacteria that have a thin cell wall and an outer lipidic membrane. They are called Gram-negative because they do not stain violet after the Gram-staining procedure.
Gram-negative bacteria do not have colour per se, but they turn pink after the Gram-staining procedure because they retain the Safranin dye at the end.
Yes, Gram-negative bacteria have a cell wall, but it is a thin cell wall.
Yes, Gram-negative bacteria have a peptidoglycan cell wall, but in comparison to Gram-positive bacteria, it is a very thin cell wall.
Yes, Gram-negative bacteria can be contagious. They are most commonly transmitted in a medical setting, and are more resistant than Gram-positive bacteria.
What is the name of the final dye in gram staining?
Safranin
What is the first dye in gram staining?
Crystal violet
True or False: Ethyl alcohol cannot decolorize gram negative bacteria
False
Iodine is used as a mordant in gram staining. What is a mordant?
A fixing agent, that helps affix the primary dye
What color are gram negative bacteria at the end of gram staining?
Pink
Gram-negative bacteria come in all the following shapes except
Linear
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