Yersinia enterocolitica is a Gram-negative bacillus that belongs to a family of bacteria called the Enterobacteriaceae.
Now, a little bit of microbe anatomy and physiology.
First, Yersinia enterocolitica has a thin peptidoglycan layer, so it doesn’t retain the crystal violet dye during Gram staining.
Instead, like any other Gram-negative bacteria, it stains pink with safranin dye.
And since it’s a Gram-negative bacillus, it looks like a little pink rod under the microscope.
Interestingly, Yersinia enterocolitica can be both motile and non-motile depending on the temperature.
So, at 25 degrees Celsius it’s motile and at 37 degrees Celsius it’s non-motile.
It’s facultative anaerobe, so it can survive in both aerobic and anaerobic environments, and also facultative intracellular which means it can survive both outside and inside the cells.
Finally, it’s non-spore forming, so it doesn’t make spores, and oxidase negative, so it doesn’t produce this enzyme.
Yersinia enterocolitica grows well on MacConkey agar, which is a medium that contains a pH sensitive dye and lactose.
This medium helps identify whether Gram-negative bacteria are lactose fermenters or not.
Some Enterobacteriaceae, like Klebsiella, Escherichia coli and Enterobacter, can ferment lactose, which results in the production of acid, and this makes the pH sensitive dye turn pink - so their colonies will be pink.
Yersinia enterocolitica, however, is a non-lactose fermenter, so it forms colorless colonies on MacConkey agar.
Yersinia enterocolitica also grows on Cefsulodin-Irgasan-Novobiocin agar, or CIN agar for short.
After 24 hours of incubation, it forms white, sharp-bordered colonies with a deep-red center, that looks like bull’s eyes colonies.
Finally, the triple sugar iron test, or TSI for short can be done to assess hydrogen sulfide production.
This medium contains three sugars - lactose, glucose and sucrose, as well as iron and a pH sensitive dye.
If the bacteria produces hydrogen sulfide, that reacts with the iron, and a black precipitate forms in the test tube.
Yersinia enterocolitica doesn’t, so no precipitate forms.
First, Yersinia enterocolitica can use adhesins such as YadA and Ail to attach to gut epithelial cells.
Once attached, it uses another virulence factor, called type III secretion system, or T3SS, to secrete bacterial proteins called Yersinia outer proteins, or Yops for short.
The end result is that Yops suppress the host inflammatory response, and help Yersinia avoid phagocytosis.
Now, the bacteria can replicate inside Peyer’s patches, which are patches of lymphoid tissue located in the gut wall, and from there it can spread to more distant lymphoid tissues such as the mesenteric lymph nodes.
Also it needs iron to survive, so to get iron, it uses a siderophore, which is a term used for a group of small, high-affinity, iron chelating compounds that snatch iron from host cells.
Finally, Yersinia also produces an enterotoxin called Yst, which is considered to be involved in the diarrheal disease but its role is not well defined because diarrheal symptoms have been found in the absence of this enterotoxin.