USMLE® Step 1 style questions USMLE
Alright, now E. Coli is gram-negative because its cell wall has a thin peptidoglycan layer so it cannot retain the crystal violet stain, but instead, it stains pink with Safranin dye used during Gram staining.
So it looks like a little pink rod under the microscope.
Also, E. Coli is a catalase positive bacteria, and that means it produces an enzyme called catalase.
This can be tested by adding a few drops of hydrogen peroxide to a colony of bacteria, and catalase makes hydrogen peroxide dissociate into water and oxygen, making the mixture foam.
E. Coli is also a lactose fermenter, because it can produce an enzyme called beta B-galactosidase that cleaves lactose into glucose and galactose monomers.
To test this, E. Coli can be cultivated on lactose-containing media such as Phenol lactose, and as it ferments it, the fermentation results in the production of acids that turn the red of phenol to yellow.
It is also a facultative anaerobe, meaning it lives in environments with or without oxygen.
Now, taking a closer look to this bacteria, E. Coli is encapsulated, meaning it’s covered by a polysaccharide layer called a capsule.
E. Coli is a motile bacteria, because it has helical whip-like threads called flagella that it can use to move around.
When E coli is cultivated on eosin methylene blue agar, it grows into black colonies with a greenish-black metallic sheen.
Alright, most of E. Coli are harmless, and they can peacefully colonize the human gut without causing any trouble.
However, some strains of E. Coli are pathogenic, meaning they can cause illness. It starts with this bacteria using little thread-like extensions called fimbriae to attach to the host cell surface.
E coli has many different strains that can do that, and they cause different diseases. These strains can be classified by two systems.
The first system uses serotypes, and it groups E. Coli strains based on their antigens.
So, bacteria within a given serotype, trigger a similar immune response.
There are also capsular – “K” antigens located on the capsule, fimbrial – “F” antigens located on the fimbria, and flagellar – “H” antigens located on the bacterial flagella.
Usually after this letter that tells on what part of the bacteria where the antigen is found, it follows a designation number in case there are more antigens of the same kind, such as K1, K2, and so forth… E. Coli antigens, influence its power to cause diseases, so that’s why they can alternatively be referred to as virulence factors.
For example, E. Coli with capsular antigen one, or K1, are the ones that cause neonatal meningitis, while an E. Coli that has an O157, and an H7 – designated as O157:H7, is associated with hemorrhagic colitis, hemolytic uremic syndrome and diarrheal outbreaks.
Thankfully, there’s a much simpler classification, and that is based on pathotypes.
A pathotype is a group of organisms of the same species, that cause disease in the same way - meaning they use the same virulence factors.
And there are 5 E.Coli pathotypes: Shiga-like toxin-producing E.Coli, or STEC for short, enterotoxigenic E. Coli or ETEC, enteroinvasive E. Coli, or EIEC, enteropathogenic E. Coli, or EPEC, and uropathogenic E. coli or UPEC/
STEC attaches to the host’s intestinal cells, and then start releasing toxins that cause injury to intestinal epithelium and underlying blood vessels, resulting in inflammation.
This makes fluid and blood leak into the intestinal lumen, resulting in bloody diarrhea.
That’s why some people refer to it as enterohemorrhagic E. Coli, or EHEC.
From the bloodstream, the toxin can get to the kidneys, and bind to the endothelial cells lining the glomerulus, making them die by apoptosis, or programmed cell death.
Consequently, a dead endothelial cell leaves a gap in the capillary wall, and as more gaps keep forming, it results in holes big enough to allow large molecules such as proteins to start leaking out of the capillaries, resulting in proteinuria.
The destruction of endothelial cells triggers an inflammatory process in which inflammatory molecules such as cytokines and chemokines are released.
Also these clots can be big enough to obstruct small arterioles.
So, as red blood cells force to pass through obstructed micro-vessels, they can get sliced into fragments called schistocytes in this process known as microangiopathic hemolysis.
So, as more red blood cells get destroyed in the process, their number reduces, which can cause anemia.
Alternatively, if clots obstruct too many arterioles, organs that depend on high blood flow, like the kidney, may lack blood and die by ischemia.
Escherichia coli is a gram-negative, rod-shaped, facultative anaerobic bacterium that is commonly found in the lower intestine of warm-blooded animals, and is an important part of the human gut flora. Escherichia coli is also used as a model organism for bacterial genetics and molecular biology. However, It is known to cause food poisoning, urinary tract infections, neonatal meningitis, septicemia, and other diseases in humans.