A membrane intercalating metal-free conjugated organic photosensitizer for bacterial photodynamic inactivation.
Arianna MagniSara MattielloLuca BeverinaGiuseppe MattioliMatteo MoschettaAnita ZucchiGiuseppe Maria PaternòGuglielmo LanzaniPublished in: Chemical science (2023)
Photodynamic inhibition (PDI) of bacteria represents a powerful strategy for dealing with multidrug-resistant pathogens and infections, as it exhibits minimal development of antibiotic resistance. The PDI action stems from the generation of a triplet state in the photosensitizer (PS), which subsequently transfers energy or electrons to molecular oxygen, resulting in the formation of reactive oxygen species (ROS). These ROS are then able to damage cells, eventually causing bacterial eradication. Enhancing the efficacy of PDI includes the introduction of heavy atoms to augment triplet generation in the PS, as well as membrane intercalation to circumvent the problem of the short lifetime of ROS. However, the former approach can pose safety and environmental concerns, while achieving stable membrane partitioning remains challenging due to the complex outer envelope of bacteria. Here, we introduce a novel PS, consisting of a metal-free donor-acceptor thiophene-based conjugate molecule (BV-1). It presents several advantageous features for achieving effective PDI, namely: (i) it exhibits strong light absorption due to the conjugated donor-acceptor moieties; (ii) it exhibits spontaneous and stable membrane partitioning thanks to its amphiphilicity, accompanied by a strong fluorescence turn-on; (iii) it undergoes metal-free intersystem crossing, which occurs preferentially when the molecule resides in the membrane. All these properties, which we rationalized via optical spectroscopies and calculations, enable the effective eradication of Escherichia coli , with an inhibition concentration that is below that of current state-of-the-art treatments. Our approach holds significant potential for the development of new PS for controlling bacterial infections, particularly those caused by Gram-negative bacteria.
Keyphrases
- reactive oxygen species
- photodynamic therapy
- multidrug resistant
- escherichia coli
- energy transfer
- cell death
- cancer therapy
- gram negative
- oxidative stress
- single molecule
- drug resistant
- helicobacter pylori infection
- molecular dynamics simulations
- lipopolysaccharide induced
- inflammatory response
- klebsiella pneumoniae
- molecular dynamics
- cell cycle arrest
- human health
- mass spectrometry
- drug delivery
- antimicrobial resistance
- solar cells
- life cycle
- climate change
- living cells