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. 2025 Jun 8;14(6):593.
doi: 10.3390/antibiotics14060593.

Antibacterial and Synergistic Effects of Terminalia citrina Leaf Extracts Against Gastrointestinal Pathogens: Insights from Metabolomic Analysis

Sze-Tieng Ang  1 Tak Hyun Kim  1 Matthew James Cheesman  2 Ian Edwin Cock  1
Affiliations

Antibacterial and Synergistic Effects of Terminalia citrina Leaf Extracts Against Gastrointestinal Pathogens: Insights from Metabolomic Analysis

Sze-Tieng Ang et al. Antibiotics (Basel). .

Abstract

Background/Objectives: Bacterial contamination leads to foodborne illnesses, and new antibiotics are required to combat these pathogens. Interest has increased in medicinal plants as targets for new antibiotics. Methods: This study evaluated the antibacterial activity of leaf extracts from Terminalia citrina (Gaertn.) Roxb. ex Fleming against four bacterial pathogens (including a methicillin-resistant Staphylococcus aureus (MRSA) strain) using disc diffusion and liquid microdilution assays. The phytochemical composition of the extracts were determined using ultra-high-performance liquid chromatography-mass spectrometry (UPLC-MS). Results: Both the aqueous and methanol extracts demonstrated noteworthy antibacterial activity against Bacillus cereus (MICs of 468.8 µg/mL and 562.5 µg/mL, respectively). Additionally, the extracts were effective against MRSA (MICs = 625 µg/mL). Strong antibacterial effects were also observed against S. aureus, with MICs of 625 µg/mL (aqueous extract) and 833.3 µg/mL (methanol extract). Twelve combinations of extracts and conventional antibiotics were synergistic against B. cereus and S. flexneri. UPLC-MS analysis revealed two flavonoids, orientin 2″-O-gallate and astragalin, exclusive to the aqueous extract, whilst pinocembrin and gallic acid were only detected in the methanol extract. Both extracts contained vitexin 2″-O-p-coumarate, ellagic acid, orientin, rutin, chebulic acid, terminalin, and quercetin-3β-D-glucoside. Both extracts were determined to be nontoxic. Conclusions: The abundance and diversity of polyphenols in the extracts may contribute to their strong antibacterial properties. Further research is required to investigate the antibacterial effects of the individual extract compounds, including their effects when combined with conventional antibiotics, and the potential mechanisms of action against foodborne pathogens.

Keywords: Combretaceae; MRSA; antibacterial activity; combinational therapies; gastrointestinal pathogens; metabolomics; plant extracts.

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Conflict of interest statement

The authors declare no conflicts of interest.

Figures

Figure 1
Figure 1
Agar disc diffusion assays using 100 µg of T. citrina leaf extracts (10 µL of the 10,000 µg/mL extracts) and reference antibiotics were conducted against S. aureus, MRSA, B. cereus, and S. flexneri. The ZOIs were measured in mm, and the disc sizes were 6 mm. Negative control discs were infused with 10 µL sterile water containing 1% DMSO. Concentrations of the cefotaxime, ciprofloxacin, tetracycline, and vancomycin controls were 30 µg, 10 µg, 10 µg, and 5 µg, respectively. Values are expressed as mean ± standard error of the mean (SEM) of three independent assays, each with internal triplicates (n = 9). * indicates results that are significantly different from the negative control (p < 0.05).
Figure 2
Figure 2
Isobolograms of tetracycline in combination with (A) TciW and (B) TciM at various combination ratios against B. cereus. FIC values are displayed as the means of two independent repeats (n = 2). Ratio = % antibiotic: % extract. FIC values below the 0.5/0.5 line represents synergy; FIC values represent additive interactions between 0.5 and 1. Only the synergistic and additive ratios are shown in these figures.
Figure 3
Figure 3
Isobolograms of TciW in combination with (A) ciprofloxacin and (B) tetracycline at various combination ratios against S. flexneri. FIC values are displayed as the means of two independent repeats (n = 2). Ratio = % antibiotic: % extract. FIC values below the 0.5/0.5 line represents synergy; FIC values represent additive interactions between 0.5 and 1. Only the synergistic and additive ratios are shown in these figures.
Figure 4
Figure 4
(A) Astragalin, (B) orientin 2″-O-gallate, (C) gallic acid, and (D) pinocembrin.
Figure 5
Figure 5
(A) catechin, (B) ellagic acid, (C) orientin, (D) (-)-epicatechin gallate, (E) vitexin 2″-O-p-coumarate, (F) chebulic acid, (G) formononetin, (H) luteolin, (I) (-)-epigallocatechin gallate, (J) rutin, (K) procyanidin B3 3-O-gallate, (L) quercetin-3β-D-glucoside, (M) cinnamtannin A4, (N) terminalin, (O) quercetin 3-(6″-p-hydroxybenzoylgalactoside), (P) 6-O-galloyl-glucose, (Q) 1,3,6-trigalloyl glucose, and (R) corilagin.
Figure 5
Figure 5
(A) catechin, (B) ellagic acid, (C) orientin, (D) (-)-epicatechin gallate, (E) vitexin 2″-O-p-coumarate, (F) chebulic acid, (G) formononetin, (H) luteolin, (I) (-)-epigallocatechin gallate, (J) rutin, (K) procyanidin B3 3-O-gallate, (L) quercetin-3β-D-glucoside, (M) cinnamtannin A4, (N) terminalin, (O) quercetin 3-(6″-p-hydroxybenzoylgalactoside), (P) 6-O-galloyl-glucose, (Q) 1,3,6-trigalloyl glucose, and (R) corilagin.
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