Abstract Title:

Inhibition of photosynthesis by a fluoroquinolone antibiotic.

Abstract Source:

Environ Sci Technol. 2010 Feb 15;44(4):1444-50. PMID: 20070075

Abstract Author(s):

Ludmilla Aristilde, Anastasios Melis, Garrison Sposito

Article Affiliation:

Molecular Toxicology Group, Department of Plant and Microbial Biology, and Division of Ecosystem Sciences, University of California at Berkeley, Berkeley, California 94720.


Recent microcosm studies have revealed that fluoroquinolone (FQ) antibiotics can have ecotoxicological impacts on photosynthetic organisms, but little is known about the mechanisms of toxicity. We employed a combination of modeling and experimental techniques to explore how FQs may have these unintended secondary toxic effects. Structure-activity analysis revealed that the quinolone ring and secondary amino group typically present in FQ antibiotics may mediate their action as quinone site inhibitors in photosystem II (PS-II), a key enzyme in photosynthetic electron transport. Follow-up molecular simulations involving nalidixic acid (Naldx), a nonfluorinated quinolone with a demonstrated adverse impact on photosynthesis, and ciprofloxacin (Cipro), the most commonly used FQ antibiotic, showed that both may interfere stereochemically with the catalytic activity of reaction center II (RC-II), the pheophytin-quinone-type center present in PS-II. Naldx can occupy the same binding site as the secondary quinone acceptor (Q(B)) in RC-II and interact with amino acid residues required for the enzymatic reduction of Q(B). Cipro binds in a somewhat different manner, suggesting a different mechanism of interference. Fluorescence induction kinetics, a common method of screening for PS-II inhibition, recorded for photoexcited thylakoid membranes isolated from Cipro-exposed spinach chloroplasts, indicated that Cipro interferes with the transfer of energy from excited antenna chlorophyll molecules to the reaction center in RC-II ([Cipro]>/= 5 muM in vitro and>/=10 muM in vivo) and thus delays the kinetics of photoreduction of the primary quinone acceptor (Q(A); [Cipro]>/= 0.6 muM in vitro). Spinach plants exposed to Cipro exhibited severe growth inhibition characterized by a decrease in both the synthesis of leaves and growth of the roots ([Cipro]>/= 0.5 muM in vivo). Our results thus demonstrate that Cipro and related FQ antibiotics may interfere with photosynthetic pathways, in addition to causing morphological deformities in higher plants.

Study Type : In Vitro Study

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