Antimicrobial Resistance and its Mechanism

Bacterial resistance to drugs is a condition in which the bacteria that were earlier susceptible to antibiotics develop resistance against the same antibiotics and are not susceptible to the action of these antibiotics.

Antibiotic resistance is seen more commonly in hospital acquired infections than in community-acquired infections due to widespread use of antibiotics in hospitals that select for these bacteria.

These hospital strains of bacteria are characterized by developing resistance to multiple antibiotics at the same time.

Common examples of such strains of bacteria showing drug resistance include hospital strains of S. aureus and Gram-negative enteric bacteria, such as Escherichia coli and Pseudomonas aeruginosa.

Resistance to multiple antibiotics is mediated by plasmid-carrying several genes that encode enzymes responsible for the resistance.

Hundreds of thousands of people are dying every year in the world from infections caused by drug resistant bacteria.

Antibiotic resistance is a rapidly increasing problem mostly as a result of the worldwide overuse and misuse of antibiotics for conditions that do not require them.

The rapid spread of antibiotic resistance in bacteria makes it necessary to intensify the development of new antibiotics and new methods to combat drug resistant bacteria.

Mechanisms of Antibiotic Resistance

There are many different mechanisms by which microorganisms might exhibit resistance to drugs.

These are

(a) production of enzymes,

 (b) production of altered enzymes,

(c) synthesis of modified targets,

(d) alteration of permeability of cell wall,

(e) alteration of metabolic pathways, and

 (f) efflux pump as follows:

Production of enzymes

Bacteria produce enzymes that inactivate antibiotics.

For example,

  • penicillin-resistant staphylococci produce an enzyme -lactamase that destroys the penicillins and cephalosporins by splitting the _-lactam ring of the drug.
  • Gram-negative bacteria resistant to aminoglycosides, mediated by a plasmid, produce adenylating, phosphorylating, or acetylating enzymes that destroy the drug.

Production of altered enzymes

Certain microorganisms develop an altered enzyme that can still perform its metabolic function, but is much less affected by the drug.

For example,

  • in trimethoprim-resistant bacteria, the dihydrofolic acid reductase is inhibited far less efficiently than in trimethoprim-susceptible bacteria.

Synthesis of modified targets

Certain bacteria produce modified targets against which the antibiotic has no effect.

For example,

  • a methylated 23S ribosomal RNA can result in resistance to erythromycin, and a mutant protein in the 50S ribosomal subunits can result in resistance to streptomycin.
  • Penicillin resistance in S. pneumoniae and enterococci is caused by the loss or alteration of PBPs.

Alteration of permeability of cell wall

Some bacteria develop resistance to antibiotic by changing their permeability to the drug in such a way that an effective intracellular concentration of the antibiotic is not achieved inside the bacterial cell.

For example,

  • P. aeruginosa develops resistance against tetracyclines by changing its porins that can reduce the amount of tetracycline entering the bacteria, thereby developing resistance to the antibiotics.
  • Resistance to polymyxins is also associated with a change in permeability to the drugs.
  •  Streptococci have a natural permeability barrier to aminoglycosides.

Alteration of metabolic pathways

Bacteria may develop resistance by altering metabolic pathway that bypasses the reaction inhibited by the drug.

For example,

  • certain sulfonamide-resistant bacteria do not require extracellular PABA but, like mammalian cells, can utilize preformed folic acid.

Efflux pumps

Efflux pumps have been found to be responsible for conferring resistance to many groups of antibiotics including aminoglycosides, quinolones, etc. The major family of bacterial efflux pumps include ABC (ATP-binding cassette) multidrug efflux pump, multidrug resistance and toxic compound extrusion (MATE) efflux pumps, major facilitator superfamily efflux (MFSE) pumps, etc.


Bacterial Processes Leading to Resistance

  • Transformation: Uptake of DNA from the environment, incorporation into the genome, and gene expression.
  • Transduction– The insertion of genetic material from a virus (Bacteriophage), and incorporation into the genome.
  • Vertical Gene Transfer: Transfer of genetic material from parent to daughter cell (Generational Inheritance)


Binod G C

I'm Binod G C (MSc), a PhD candidate in cell and molecular biology who works as a biology educator and enjoys scientific blogging. My proclivity for blogging is intended to make notes and study materials more accessible to students.

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