Extracellular DNA facilitates the formation of functional amyloids in Staphylococcus aureus biofilms

Persistent staphylococcal infections often involve surface‐associated communities called biofilms. Staphylococcus aureus biofilm development is mediated by the co‐ordinated production of the biofilm matrix, which can be composed of polysaccharides, extracellular DNA (eDNA) and proteins including amyloid fibers. The nature of the interactions between matrix components, and how these interactions contribute to the formation of matrix, remain unclear. Here we show that the presence of eDNA in S. aureus biofilms promotes the formation of amyloid fibers. Conditions or mutants that do not generate eDNA result in lack of amyloids during biofilm growth despite the amyloidogeneic subunits, phenol soluble modulin peptides, being produced. In vitro studies revealed that the presence of DNA promotes amyloid formation by PSM peptides. Thus, this work exposes a previously unacknowledged interaction between biofilm matrix components that furthers our understanding of functional amyloid formation and S. aureus biofilm biology.     

Total synthesis,structural, and biological evaluation of stylissatin A and related analogs

The natural product cyclic peptide stylissatin A ( 1a ) was reported to inhibit nitric oxide production in LPS‐stimulated murine macrophage RAW 264.7 cells. In the current study, solid‐phase total synthesis of stylissatin A was performed by using a safety‐catch linker and yielded the peptide with a trans‐Phe⁷‐Pro⁶ linkage, whereas the natural product is the cis rotamer at this position as evidenced by a marked difference in NMR chemical shifts. In order to preclude the possibility of 1b being an epimer of the natural product, we repeated the synthesis using d ‐allo‐Ile in place of l ‐Ile and a different site for macrocyclization. The resulting product (d ‐allo‐Ile²)‐stylissatin A ( 1c ) was also found to have the trans‐Phe⁷‐Pro⁶ peptide conformations like rotamer 1b . Applying the second route to the synthesis of stylissatin A itself, we obtained stylissatin A natural rotamer 1a accompanied by rotamer 1b as the major product. Rotamers 1a , 1b , and the epimer 1c were separable by HPLC, and 1a was found to match the natural product in structure and biological activity. Six related analogs 2–7 of stylissatin A were synthesized on Wang resin and characterized by spectral analysis. The natural product ( 1a ), the rotamer ( 1b ), and (d ‐allo‐Ile²)‐stylissatin A ( 1c ) exhibited significant inhibition of NO^.. Further investigations were focused on 1b , which also inhibited proliferation of T‐cells and inflammatory cytokine IL‐2 production. The analogs 2–7 weakly inhibited NO^. production, but strongly inhibited IL‐2 cytokine production compared with synthetic peptide 1b . All analogs inhibited the proliferation of T‐cells, with analog 7 having the strongest effect. In the analogs, the Pro⁶ residue was replaced by Glu/Ala, and the SAR indicates that the nature of this residue plays a role in the biological function of these peptides. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.     

Requirement for Protein Synthesis in rec-Dependent Repair of Deoxyribonucleic Acid in Escherichia coli after Ultraviolet or X Irradiation

Deprivation of amino acids required for growth or treatment with chloramphenicol or puromycin after irradiation reduced the survival of Rec(+) cells of Escherichia coli K-12 which had been exposed to either ultraviolet (UV) or X radiation. In contrast, these treatments caused little or no reduction in the survival of irradiated recA or recB mutants. The effect of chloramphenicol on the survival of X-irradiated cells was correlated with an inhibition of repair of single-strand breaks in irradiated deoxyribonucleic acid (DNA), previously shown to be controlled by recA and recB. In UV-irradiated cells no effect of chloramphenicol was detected on the repair of single-strand discontinuities in DNA replicated from UV-damaged templates, a process controlled by recA but not by recB. From this we concluded that inhibiting protein synthesis in UV or X-irradiated cells may interfere with some biochemical step in repair dependent upon the recB gene. When irradiated Rec(+) cells were cultured for a sufficient period of time in minimal growth medium before chloramphenicol treatment their survival was no longer decreased by the drug. After X irradiation this occurred in less than one generation time of the unirradiated control cells. After UV irradiation it occurred more slowly and was only complete after several generation times of the unirradiated controls. These observations indicated that replication of the entire irradiated genome was probably not required for rec-dependent repair of X-irradiated cells, although it might be required for rec-dependent repair of UV-irradiated cells.     

Dark Recovery Processes in Escherichia coli Irradiated with Ultraviolet Light II. Effect of uvr Genes on Liquid Holding Recovery

The uvr mutations of Escherichia coli K-12 decrease the ability of cells to survive ultraviolet light (UV), to excise pyrimidine dimers from their deoxyribonucleic acid and to reactivate bacteriophage exposed to UV. The rec mutations decrease the ability of the cells to survive UV and to undergo genetic recombination. Certain rec mutations, including recA1, rec-12, recA13, and rec-56, are necessary for the expression of liquid-holding recovery (LHR), observed as an increase in colony-forming ability when irradiated cells are held in buffer in the dark. These rec mutations appear to act indirectly to permit the detection of LHR rather than to affect its occurrence directly. We have tested the effect of uvr markers on LHR in cells containing one of these rec mutations. Recombinants containing rec-56 together with a uvr marker were constructed and tested for LHR. None of the 39 recombinants examined, carrying uvrA6, uvrB5, or uvrC34, showed LHR. Three rec(-)uvr(-) strains were also tested for photoreactivation. In all three, photoreactivation was observed, indicating that they contained detectable amounts of pyrimidine dimers. Our results are consistent with the idea that uvr mutations inactivate LHR, and suggest that LHR reflects excision-dependent repair of pyrimidine dimers.     

The duration of recovery and DNA repair in excision deficient derivatives of Escherichia coli K-12 after ultraviolet irradiation

Summary Our results indicate that cells of excision deficient (uvr) mutants of Escherichia coli K-12 which survive exposure to ultraviolet radiation may require several hours to complete their recovery. For example, the duration of the recovery period for cells exposed to 63 ergs mm^-2 at 254 nm was about 5 hours, the equivalent of slightly more than 4 generations of the unirradiated controls. During the recovery period the rate of cell division was reduced (Figs. 3 and 4), the cells gradually regained resistance to complex medium (Figs. 1 and 3), and they became refractory to photoreactivation (Fig. 1). Over the same period of time their pattern of DNA synthesis changed. More intact molecules, similar to those found in unirradiated controls, and relatively fewer discontinuous molecules were synthesized (Figs. 6 and 7).