Table 3.
Main mechanisms of antibiotic resistance and effects of iron withdrawal
| Resistance mechanism | Nature of resistance | Examples (reference) | Likely affected by iron withdrawal? |
|---|---|---|---|
| Antibiotic neutralization | Enzymes produced by microbes to modify/degrade antibiotic; rendering it inactive | β-lactam degradation and aminoglycoside modifications (Wright 2005); metallo-β-lactamase, and aminoglycoside acetyltransferase in A. baumannii | Presumably yes as enzyme induction requires RNA and protein synthesis utilizing iron dependent enzymes |
| Antibiotic target modification | Mutations providing altered non-sensitive microbial target | Mupirocin resistance in S. aureus from altered insensitive isoleucine-tRNA synthetase target (Liu et al. 2017) | Presumably yes as low iron can suppress Fe-dependent ribonucleotide reductase levels as needed for DNA synthesis and repair |
| Antibiotic Efflux Pumps | Reduced intracellular antibiotic concentration, exclusion from cell | Ciprofloxacin and other fluoroquinolone efflux in P. aeruginosa (Lubelski et al. 2007; Amaral et al. 2014) | Yes, iron withdrawal can affect energy production by iron-dependent enzymes and iron insufficiency causes membrane instability (Prasad et al. 2006) |
| Physical resistance to antibiotic delivery into microbes | Biofilm growth physically protecting microbes within biofilm | P. aeruginosa biofilm displays resistance (Gupta et al. 2016) | Yes, iron withdrawal can suppress biofilm formation and also disrupt established biofilm growth (Post et al. 2019) |
| Metabolic mutation; persister cells | Slower growth and reduced electron transport reduces antibiotic sensitivity | S. aureus small colony variants—hemin/menadione and thymidine auxotrophs display multiple resistance (Proctor et al. 1998, 2014) | Yes, deferiprone-Gallium active against S. aureus SCVs, particularly hemin auxotrophs (Richter et al. 2017) |