Cytotoxic Staphylococcus aureus PSMα3 inhibits the aggregation of human insulin in vitro

Phenol-soluble modulins (PSMs) are extracellular short amphipathic peptides secreted by the bacteria ( ). They play an essential role in the bacterial lifecycle, biofilm formation, and stabilisation. From the PSM family, PSMα3 has been of special interest recently due to its cytotoxicity and highly...

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Published in:Physical chemistry chemical physics : PCCP 2024-05, Vol.26 (21), p.15587-15599
Main Authors: Kalitnik, Aleksandra, Szefczyk, Monika, Wojciechowska, Alicja W, Wojciechowski, Jakub W, Gąsior-Głogowska, Marlena, Olesiak-Bańska, Joanna, Kotulska, Małgorzata
Format: Article
Language:English
Subjects:
Amyloid - chemistry
Amyloid - metabolism
Bacteria
Bacterial Toxins - chemistry
Bacterial Toxins - metabolism
Dimerization
Fibrillation
Helices
Humans
Insulin
Insulin - chemistry
Insulin - metabolism
Peptides
Protein Aggregates - drug effects
Staphylococcus aureus - drug effects
Staphylococcus aureus - metabolism
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Summary:Phenol-soluble modulins (PSMs) are extracellular short amphipathic peptides secreted by the bacteria ( ). They play an essential role in the bacterial lifecycle, biofilm formation, and stabilisation. From the PSM family, PSMα3 has been of special interest recently due to its cytotoxicity and highly stable α-helical conformation, which also remains in its amyloid fibrils. In particular, PSMα3 fibrils were shown to be composed of self-associating "sheets" of α-helices oriented perpendicular to the fibril axis, mimicking the architecture of canonical cross-β fibrils. Therefore, they were called cross-α-fibrils. PSMα3 was synthesised and verified for identity with wild-type sequences ( ). Then, using several experimental techniques, we evaluated its propensity for aggregation. According to our findings, synthetic PSMα3 (which lacks the N-terminal formyl groups found in bacteria) does not form amyloid fibrils and maintains α-helical conformation in a soluble monomeric form for several days of incubation. We also evaluated the influence of PSMα3 on human insulin fibrillation , using a variety of experimental approaches in combination with computational molecular studies. First, it was shown that PSMα3 drastically inhibits the fibrillation of human insulin. The anti-fibrillation effect of PSMα3 was concentration-dependent and required a concentration ratio of PSMα3: insulin equal to or above 1 : 100. Molecular modelling revealed that PSMα3 most likely inhibits the production of insulin primary nuclei by competing for residues involved in its dimerization.
ISSN:1463-9076
1463-9084
1463-9084
DOI:10.1039/d4cp00669k