OBJECTIVES: We have shown previously that a polycationic conjugate between poly-L-lysine and the photosensitizer chlorin(e6) was effective in photodynamic inactivation (PDI) of both Gram-positive and Gram-negative bacteria. In this report we explore the relationship between the size of the polylysine chain and its effectiveness for mediating the killing of Gram-negative and Gram-positive bacteria. METHODS: Conjugates were prepared by attaching precisely one chlorin(e6) molecule to the alpha-amino group of poly-(epsilon-benzyloxycarbonyl)lysines of average length eight and 37 lysine residues, followed by deprotection of the epsilon-amino groups, and were characterized by iso-electric focusing. The uptake of these conjugates and free chlorin(e6) by Gram-positive Staphylococcus aureus (ATCC 27659) and Gram-negative Escherichia coli (ATCC 29181) after washing was measured as a function of photosensitizer concentration (0-4 microM chlorin(e6) equivalent) and incubation time. After incubation the bacteria were exposed to low fluences (10-40 J/cm(2)) of 660 nm light delivered from a diode laser, and viability was assessed after serial dilutions by a colony-forming assay. RESULTS: S. aureus and E. coli took up comparable amounts of the two conjugates, but free chlorin(e6) was only taken up by S. aureus. After illumination S. aureus was killed in a fluence-dependent fashion when loaded with the 8-lysine conjugate and free chlorin(e6) but somewhat less so with the 37-lysine conjugate. In contrast, PDI of E. coli was only effective with the 37-lysine conjugate at concentrations up to 4 microM. PDI using the 8-lysine conjugate and free chlorin(e6) on E. coli was observed at a concentration of 100 microM. Transmission electron micrographs showed internal electron-lucent areas consistent with chromosomal damage. CONCLUSION: These results can be explained by the necessity of a large polycation to penetrate the impermeable outer membrane of Gram-negative E. coli, while Gram-positive S. aureus is more easily penetrated by small molecules. However, because S. aureus is more sensitive overall than E. coli the 37-lysine conjugate can effectively kill both bacteria.
OBJECTIVES: We have shown previously that a polycationic conjugate between poly-L-lysine and the photosensitizer chlorin(e6) was effective in photodynamic inactivation (PDI) of both Gram-positive and Gram-negative bacteria. In this report we explore the relationship between the size of the polylysine chain and its effectiveness for mediating the killing of Gram-negative and Gram-positive bacteria. METHODS: Conjugates were prepared by attaching precisely one chlorin(e6) molecule to the alpha-amino group of poly-(epsilon-benzyloxycarbonyl)lysines of average length eight and 37 lysine residues, followed by deprotection of the epsilon-amino groups, and were characterized by iso-electric focusing. The uptake of these conjugates and free chlorin(e6) by Gram-positive Staphylococcus aureus (ATCC 27659) and Gram-negative Escherichia coli (ATCC 29181) after washing was measured as a function of photosensitizer concentration (0-4 microM chlorin(e6) equivalent) and incubation time. After incubation the bacteria were exposed to low fluences (10-40 J/cm(2)) of 660 nm light delivered from a diode laser, and viability was assessed after serial dilutions by a colony-forming assay. RESULTS:S. aureus and E. coli took up comparable amounts of the two conjugates, but free chlorin(e6) was only taken up by S. aureus. After illumination S. aureus was killed in a fluence-dependent fashion when loaded with the 8-lysine conjugate and free chlorin(e6) but somewhat less so with the 37-lysine conjugate. In contrast, PDI of E. coli was only effective with the 37-lysine conjugate at concentrations up to 4 microM. PDI using the 8-lysine conjugate and free chlorin(e6) on E. coli was observed at a concentration of 100 microM. Transmission electron micrographs showed internal electron-lucent areas consistent with chromosomal damage. CONCLUSION: These results can be explained by the necessity of a large polycation to penetrate the impermeable outer membrane of Gram-negative E. coli, while Gram-positive S. aureus is more easily penetrated by small molecules. However, because S. aureus is more sensitive overall than E. coli the 37-lysine conjugate can effectively kill both bacteria.
Authors: Imran Ahmed; Yanyan Fang; Min Lu; Quan Yan; Ahmed El-Hussein; Michael R Hamblin; Tianhong Dai Journal: Recent Pat Antiinfect Drug Discov Date: 2018