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Intrinsic resistance

What is intrinsic resistance?
Schematic of a bacterial plasma membrane, peptidoglycan cell wall and outer membrane, with a porin and a label reading 'reduced permeability' in the outer membrane, and an efflux pump spanning all three layers
© Wellcome Connecting Science

Let’s start with an overview of the mechanisms of resistance

Intrinsic resistance refers to the natural resistance of bacterial species to certain antibiotic or family of antibiotics, without the need for mutation or gain of further genes. This means that these antibiotics can never be used to treat infections caused by that species of bacteria.

An example of intrinsic resistance is the resistance of Pseudomonas aeruginosa (a common cause of lung infections in people with cystic fibrosis) to most β-lactam antibiotics.

The figure at the top of the page shows the three main mechanisms of intrinsic resistance: reduced permeability of the outer membrane, selective exclusion via porins and efflux pumps actively pumping antibiotics out of the cell.

There are two major mechanisms by which bacteria mediate intrinsic resistance:

1. Differences in membrane permeability and access

Bacteria are classified into two groups by a process known as Gram staining. Gram staining uses a series of chemical dyes and washing steps to differentiate bacteria. This results in some bacteria staining purple, these are known as Gram-positive bacteria, while other bacteria stain pink/red, and are known as Gram-negative bacteria.

The difference between Gram-positive and Gram-negative bacteria is due to differences in the structure of their cell wall, which means that Gram-positive bacteria will retain the purple dye, while Gram-negative bacteria lose it. In summary the main structural differences are:

Gram-positive bacteria: have a thick peptidoglycan layer.

Gram-negative bacteria: have a thin peptidoglycan layer and an extra outer membrane containing lipopolysaccharide.

This difference in the structure of the cell wall means that Gram-negative bacteria are resistant to vancomycin (a glycopeptide antibiotic) because their extra outer membrane prevents a large molecule like vancomycin entering the cell.

Gram-negative bacteria and some Gram-positive bacteria also have structures called porins, which act as pores through which molecules including nutrients can pass through the membrane into the cell. In some intrinsically resistant bacteria the chemical properties or the size of porins exclude certain antibiotics. The number of the porins that is expressed in the membrane is also thought to contribute to intrinsic resistance. For example, when a bacterial species has a lower number of porins, it reduces the permeability of the membrane to certain antibiotics.

Other bacteria such as members of the genus _Mycobacterium _ have exceptionally thick or waxy cell walls, further enhancing their intrinsic resistance to many antibiotics.

2. Pumping out

Another mechanism of intrinsic resistance in Gram-negative bacteria is due to the presence of efflux pumps. These pump antibiotics out of the cell thereby preventing them reaching lethal concentrations. When combined with reduced permeability of the cell membrane, the action of efflux pumps can enhance a bacterium’s ability to resist antibiotics. Some of these efflux pumps are classified as multidrug-efflux pumps as they provide resistance to a number of different classes of antibiotics. For example, MexAB-OprM efflux system in P. aeruginosa, which mediates intrinsic reduced susceptibility to fluoroquinolones, tetracyclines, phenicols, macrolides and β-lactams.

Efflux pumps is a mechanism of antimicrobial resistance that can involve epigenetic factors, as outlined in the next step. Epigenetic changes refer to modifications that affect gene expression without altering the underlying DNA sequence.

Why do you think that some bacteria are intrinsically resistant?

This step is an updated version of a step from Wellcome Connecting Science course Bacterial Genomes: Antimicrobial Resistance in Bacterial Pathogens
© Wellcome Connecting Science
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Antimicrobial Databases and Genotype Prediction: Data Sharing and Analysis

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