The alcoholic DPPH solution is reduced to yellow diphenyl-picrylhydrazine in the presence of an antioxidant sample that donates hydrogen as part of this method for evaluating antioxidant activity (Brand-Williams et al., 1995). A UV–VIS spectrophotometer (UV–VIS-2600, Shimadzu) was used to measure the change in colour from deep violet to yellow at a wavelength of 517 nm.

The procedure of Oyaizu (1986), as given by Gülçin (2009), was used to ascertain the reducing power of M. koenigii leaf extract. The foundation of this technique is the antioxidant samples’ reduction of the ferric/ferricyanide complex to a ferrous state.

The effect of sub-MICs of MKCF on cell growth kinetics was determined. Each bacterial strain was inoculated to 25 mL LB broth with or without different sub-MICs of the fraction, and the OD at 600 nm was monitored at regular intervals of 2 h till 20 h.

The previously described standard methodology was used to qualitatively evaluate the violacein inhibitory action of the plant extract/ active fraction (McLean et al., 2004; Haris and Ahmad, 2024b). Five milliliters of LB soft agar (0.5% w/v agar) containing C. violaceum 12,472 was overlaid on LB agar plates and let the plates kept standing for 20 min. Sterile discs (8 mm) impregnated with varying concentrations of the plant extract/fractions were mounted on the solid media. For 24 h, plates were left incubated at 30 °C and the pigment inhibition in the form of a halo zone around the discs was recorded. Growth inhibition, in the form of clear zones around the impregnated disc, if present was also monitored. The results were expressed in diameter (mm) of pigment inhibition or growth inhibition.

Quantitative evaluation of violacein inhibition in the presence of plant extract/active fraction were also carried out as previously described (Haris and Ahmad, 2024b; Taganna et al., 2011). C. violaceum 12,472 with and without different sub-MICs of plant extract was cultured in liquid LB medium at 30 °C for 24 h. Following the incubation, 1 mL of vortexed broth was centrifuged at 12,000 rpm for 10 min. In 1 mL of DMSO, the pellet was reconstituted and vortexed for 5 min to solubilize the cell-bound violacein. The solution was again centrifuge to remove the bacterial cells and the OD₅₈₅ of cell-free DMSO solution was acquired for violacein.

The pyocyanin assay was performed in pseudomonas broth (PB) medium (20 g/L peptone, 1.4 g/L MgCl₂, and 10 g/L K₂SO₄) as this medium enhances the production of pyocyanin by the described procedure (Essar et al., 1990). Briefly, P. aeruginosa PAO1 was cultured in PB medium in the absence and presence of varying sub-MICs of MKCF for 18 h. A 5 mL supernatant was extracted with 3 mL of chloroform, and the aqueous phase was discarded. The organic phase was reextracted into 1.2 mL of HCl (0.2 N). The absorbance of the pink or deep red aqueous phase was recorded at 520 nm. The concentration of pyocyanin is expressed in μg/ml, which was obtained by multiplying the OD₅₂₀ by 17.072.

The previous standard procedure was used to measure the pyoverdin levels spectrophotometrically (Ankenbauer et al., 1985). Briefly, to produce a cell-free supernatant, overnight developed cultures of P. aeruginosa PAO1 in the presence and absence of sub-MICs of MKCF were centrifuged. 900 μL of 50 mM Tris–HCl (pH 7.4) were combined with 100 μL of supernatant. Using an RF-5301PC spectrofluorometer (Shimadzu, Japan), the sample’s fluorescence emission signal was excited at 400 nm and measured at 460 nm.

The proteolytic activity of the bacterial strains under the effect of different sub-MICs of the MKCF was determined by azocasein degradation assay as previously described (Husain et al., 2017). Briefly, 100 μL cell-free supernatant of untreated and treated cultures were mixed with 1 mL of 0.3% (w/v) azocasein (containing 0.5 mM CaCl₂ in 0.05 M Tris- HCl, pH 7.5), and the reaction mixture was incubated for 15 min at 37 °C. Five hundred microlitres of trichloroacetic acid (10% w/v) was added to terminate the reaction and then centrifuged at 12000 rpm for 10 min. The absorbance of the supernatant was recorded at 400 nm.

The previously stated orcinol procedure was used to execute the rhamnolipid test (Haris and Ahmad, 2024a; Husain et al., 2017). In brief, P. aeruginosa was cultivated for 18 h at 37 degrees Celsius both in the absence and presence of sub-MICs of MKCF, and the cell supernatant was collected by centrifugation. Six hundred microliter diethyl ether was combined with 300 microlitres of cell-free supernatant from cultures. The mixture was vortexed for 1 min. A 100 microlitre solution of deionized water was used to reconstitute the organic phase after it had been separated and evaporated to dryness at 37 degrees Celsius. A hundred microliter of each sample was added with 900 μL of an orcinol solution. For 30 min, the mixture was heated to 80 °C. After cooling the sample for 15 min at room temperature, absorbance at 421 nm was measured.

In order to assess the swimming motility, LB plates (0.3% agar) were spotted with 5 microlitres of the bacterial culture that had been cultivated overnight, and the plates were allowed to dry at room temperature (Haris and Ahmad, 2024a). The control group consisted of plates devoid of MKCF. After 18 h of incubation, the plates were examined, and the swimming zone was measured by the transparent ruler in millimeters (mm).

In Luria-Bertani media, prodigiosin pigment was evaluated using the established procedure as described earlier (Haris and Ahmad, 2024b; Slater et al., 2003). In brief, for 18 h at 30 °C, S. marcescens was cultivated both in the absence and presence of sub-MICs of active plant extracts/fractions. The bacterial cells were pelleted by centrifuging two milliliters of the growing culture at 10,000 rpm for 5 min. A rigorous vortexing process lasting 5 min was used to dissolve the pellet in 1 mL of an acidified ethanol solution. In order to eliminate debris, the sample was centrifuged once more for 5 min at a speed of 13,000 rpm. Using a UV-2600 spectrophotometer, the absorbance was measured at 534 nm.

As previously mentioned, the azocasein degradation technique was employed to evaluate S. marcescens’s exoprotease activity (Salini and Pandian, 2015). Briefly, S. marcescens was grown for 18 h at 30 degrees Celsius with and without sub-MIC levels of MKCF. 100 microliters of the supernatant that was left over after centrifuging the culture was mixed with one milliliter of 0.3% (w/v) azocasein. The reaction mixture was shaken and then incubated for 15 min at 37 °C. After adding 0.5 mL of ice-cold TCA to terminate the reaction, the insoluble azocasein was removed by centrifugation. At 400 nm, the absorbance was taken with a UV-2600 spectrophotometer.

MKCF’s quantitative assessment of biofilm inhibition was evaluated on a 96-well microtitre plate using the previously described crystal violet technique (O’Toole and Kolter, 1998). Following an overnight incubation period, bacterial cultures with various sub-MICs of MKCF were introduced to the wells containing LB media. After three rounds of cleaning with sterile phosphate buffer to eliminate extra broth and planktonic cells, the wells were left to air dry for 20 min. The biofilms were gently rinsed three times to eliminate the stain after being stained for 15 s with 200 μL of crystal violet. The crystal violet affixed to the biofilm was extracted using 200 microliters of 90% ethanol, and the absorbance at 620 nm was measured using a microplate reader (Thermo Scientific Multiskan EX, UK).

Biofilms on glass coverslips were inhibited using the previously described method (Sybiya Vasantha Packiavathy et al., 2012). Briefly, 60 μL overnight-grown cultures of the bacterial pathogens were seeded into a 24-well culture plate containing 3 mL of culture media. Furthermore, sterile glass coverslips with the highest sub-MICs of MKCF were placed in the wells. After a 24-h incubation period, the loosely attached cells were rinsed three times with sterile phosphate buffer solution and allowed to air dry for 20 min. Slides were left to air dry for half an hour after being stained with crystal violet solution. A light microscope (Olympus BX60, Model BX60F5, Olympus Optical Co., Ltd., Japan) equipped with a colour VGA camera (Sony, Model no. SSC-DC-58AP, Japan) was used to view the biofilms.

Biofilms formed on coverslips, as mentioned before. Unbound bacterial cells were removed after being cleaned with sterile phosphate buffer and fixed with 2.5% glutaraldehyde. The adherent cells and biofilms were then dried for 10 min using an ethanol gradient. The slides were air-dried and gold-coated before visualization. A JEOL-JSM 6510 LV was utilized by the University Sophisticated Instrumentation Facility (USIF), AMU, Aligarh, to take the SEM micrographs.

For CLSM, biofilms were grown on glass surfaces using the same procedure as previously mentioned. The biofilms were then stained for 20 min with acridine orange (0.1%). The images were taken at USIF, AMU, Aligarh, with a Zeiss LSM780.

Different fractions of active plant extracts were preliminarily tested for the presence of a common class of plant compounds, such as terpenoids, flavonoids, and alkaloids, using thin-layer chromatography (TLC) according to the previously reported standard procedure (Wagner and Bladt, 1996; Harborne, 1998). All extracts were dried and redissolved in methanol. The samples were then spotted on TLC plates using the Pasteur pipette. The chromatograms of plant extract were developed using ethyl acetate, toluene, and formic acid (5:4:1) on TLC Silica 60 F254 plates (Merck, Germany). The details of the phytochemical class, reagents used, band colors observed, and their inference is presented in Supplementary material SI 10.

MKCF was subjected to GC/MS analysis for the identification and relative quantification of its phytocompounds. GC 7890A (Agilent Technologies, Santa Clara, CA, USA) systems, along with the Accutof GCv JMST100 mass spectrometer (JEOL India Pvt. Ltd.) were used for the GC–MS analysis. To identify compounds, the observed peak mass spectra were compared to a standard database (the NIST library).

To further identify compounds using the previously established approach, MKCF was employed in LC-qTOF/MS analysis (Khan et al., 2018). The Agilent 1,290 infinite UPLC machine (Agilent Technologies, USA) was used to perform chromatographic separation on a C18 column. The spectra were recorded using the quadrupole time-of-flight unit. The Sophisticated Analytical Instrument Facility (SAIF) at the Indian Institute of Technology Bombay (IIT-B), Maharashtra, India, is where the LC-qTOF/MS analysis was conducted. The identification of phytocompounds was done using Agilent Mass Profiler Professional (MPP) software.

The methanolic extract of M. koenigii leaves was fractioned using liquid–liquid partitioning in different solvents, with the chloroform fraction (MKCF) showing the highest violacein inhibition (75.29%), as shown in Table 2, prompting further investigation into its bioactive anti-QS fraction.

The fractions of M. koenigii were also tested for their ability to prevent P. aeruginosa PAO1 from producing pyocyanin through QS (Table 3). The chloroform fraction of M. koenigii (MKCF) was more promising than other fractions, demonstrating 75.35% pyocyanin inhibition. Other fractions of M. koenigii following the chloroform fraction were ethyl acetate (70.05%) > aqueous (49.14%) > hexane (24.49%).

MKCF was primarily evaluated for its effect on violacein pigment production by C. violaceum 12,472 using the disc diffusion method at concentrations of 500 and 1,000 μg/mL per disc. Methanolic crude extract and most antioxidant-active chloroform fraction exhibited varying levels of pigment inhibition at the tested concentrations (Figure 3A). At the highest tested concentration (1,000 μg/mL) impregnated disc, MKCF inhibited violacein production more effectively than the methanolic extract. Violacein inhibition was also quantitatively estimated when sub-MICs (125–1,000 μg/mL) of MKCF were present. Figure 3B illustrates how the most active chloroform fraction inhibits the formation of violacein. The findings showed that the violacein pigment was reduced by 39.41, 46.91, 55.29, and 70.73% in the presence of 125, 250, 500, and 1,000 μg/mL MKCF, respectively. Azithromycin (2 μg/mL) was used as positive control (data not shown).

MKCF was also tested for anti-QS property against S. marcescens, and the results are shown in Table 4. Comparing the pigment levels to the untreated control, the addition of 125, 250, 500, and 1,000 μg/mL MKCF decreased them by 13.20, 30.18, 49.05, and 62.26%, respectively. Protease activity was shown to be affected by MKCF in a dose-dependent manner and inhibited by 68.75% when 1,000 μg/mL MKCF was present. S. marcescens was examined for its ability to swarm over agar plates, supplemented with MKCF. When 1,000 μg/mL MKCF was present, the swarming motility was 76.03% lower than the control.

The findings in Table 5 demonstrate MKCF’s in vitro anti-QS activity against P. aeruginosa PAO1’s virulence factors, which showed significant inhibition in a concentration-dependent manner. The pyocyanin level in untreated P. aeruginosa was 6.98 ± 0.22 μg/mL, and it dropped in a concentration-dependent way following MKCF treatment. Pyocyanin production was inhibited by 9.45, 19.19, 45.98, and 64.75% after treatment with 125, 250, 500, and 1,000 μg/mL MKCF, respectively. Likewise, in the presence of 1,000 μg/mL MKCF, the pyoverdin fluorescence was maximally decreased by 54.39% in a concentration-dependent manner. Protease activity showed a similar downward trend, decreasing by 56.66% at the highest measured sub-MIC (1,000 μg/mL) in comparison to the untreated control. In comparison to the untreated control, the rhamnolipid content also decreased dose-dependently, with the concentration lowered by 55.88% at the highest measured sub-MIC (1,000 μg/mL). There was a 56.28% reduction in swarming motility in the presence of 1,000 μg/mL MKCF.

Table 6 shows that the tested fraction inhibited the production of biofilms in a dose-dependent manner. A 1000 μg/mL concentration of MKCF decreased P. aeruginosa biofilms by 66.07%. Comparing the biofilms of C. violaceum and S. marcescens to the untreated control, 1,000 μg/mL MKCF decreased them by 76.62 and 64.83%, respectively.

Following a quantitative evaluation of plant extracts’ ability to suppress biofilm development using the microbroth dilution experiment, the inhibition of biofilm formation on a glass coverslip was examined. In the untreated control, bacterial cells formed a thick and dense biofilm on the glass surface, as shown in the light microscopic pictures of bacterial biofilm (Supplementary material SI 1). As indicated by the scattered cells, treatment with 1,000 μg/mL MKCF decreased the bacterial cells’ tendency to aggregate on the glass surface. Subsequent SEM examination revealed that the untreated control showed thick and compact biofilm growth on the glass surface that resembled exopolysaccharides (EPS) (Figure 4). In comparison to the untreated control, treatment with the highest sub-MIC of MKCF produced dispersed bacterial cells and fewer microcolony clumps. A thick carpet-like structure generated by bacterial pathogens on the surface of the glass control (untreated) was visible in the CLSM images. Nevertheless, the presence of the highest sub-MIC, i.e., 1,000 μg/mL MKCF, decreased the production of biofilms (Figure 5).

Molecular docking studies were conducted to better understand the interaction between the identified phytocompounds in MKCF and the proteins or enzymes involved in QS-mediated virulence factors and biofilms. Table 10 lists the binding energies of the phytocompounds of MKCF that show the highest affinity. Among the identified compounds, morellin was found to interact with LasA, CviR, EsaI, and PilY1 most strongly with binding energy of −8.48, −8.29, −9.88, and −8.73 kcal mol⁻¹, respectively, compared to other phytocompounds. Similar to morellin, murrayazolinol also showed a good binding affinity with CviR and EsaI with binding energy of −9.07 and −9.17 kcal mol⁻¹, respectively.

In the active site cavity of 3IT7: Murrayazolinol showed three H-bonding interactions with Arg12 (3.07 and 3.49 Å) and Tyr15 (2.11 Å), it showed alkyl and π-alkyl hydrophobic interactions with Arg12 (3.97 Å), Tyr15 (4.85 and 5.46 Å) and Tyr49 (4.54 Å) (Figure 8).

Morellin exhibited three hydrogen bonding interactions with Ala1 (2.85 Å), Met7 (2.07 Å) and Ser138 (2.72 Å), it showed alkyl and π-alkyl hydrophobic interactions with Leu6 (4.10 and 4.66 Å), Trp75 (5.19 and 5.46 Å), Ala137 (4.40 Å) and Ala181 (3.37, 3.50 and 4.32 Å) (Figure 9).

Gibberellic acid, methyl ester exhibited three H-bonding interactions with Arg12 (3.34 Å), Trp17 (2.81 Å) and Ser50 (2.16 Å), it showed π-alkyl hydrophobic interactions with Tyr15 (5.49 Å), Tyr39 (4.02 and 4.95 Å) and Tyr49 (4.33, 4.82 and 5.38 Å) (Supplementary material SI 4).

7,8-Epoxylanostan-11-ol, 3-acetoxy- showed two H-bonding interactions with Ser115 (2.24 Å) and Thr117 (3.33 Å), it showed π-alkyl hydrophobic interaction with Tyr90 (4.26 and 4.90 Å) (Supplementary material SI 5).

In the active site cavity of 3QP5: Murrayazolinol exhibited no H-bonding interaction however, it showed alkyl and π-alkyl hydrophobic interactions with Leu57 (4.48, 4.91, 5.16 and 5.46 Å), Ala59 (3.91 Å), Leu72 (4.39 and 4.58 Å), Tyr80 (4.46 Å), Trp84 (3.87 Å), Leu85 (4.20 and 4.22 Å), Tyr88 (3.72 and 5.13 Å), Met89 (4.52 Å), Ile99 (5.11 Å), Leu100 (3.49 Å) and Ile153 (4.89 Å) (Figure 10).

Morellin showed H-bonding with Leu72 (2.77 Å), it showed alkyl and π-alkyl hydrophobic interactions with Arg71 (4.26 Å), Leu72 (4.61 Å), Val75 (4.45 Å), Leu85 (4.30 and 4.70 Å), Tyr88 (4.99 Å), Met89 (4.54 and 5.39 Å), Ala94 (4.07 and 5.09 Å) and Leu100 (4.64 Å) (Figure 11).

Gibberellic acid, methyl ester showed no H-bonding interaction however, it showed alkyl and π-alkyl hydrophobic interactions with Tyr80 (5.45 Å), Trp84 (4.17 Å), Leu85 (4.22 Å), Tyr88 (4.97 Å), Ile99 (4.87 and 5.47 Å), Leu100 (4.51 and 4.73 Å) and Trp111 (5.50 Å) (Supplementary material SI 6).

7,8-Epoxylanostan-11-ol, 3-acetoxy- showed H-bonding interaction with Leu72 (2.93 Å), it showed alkyl and π-alkyl hydrophobic interactions with Leu57 (3.65 Å), Leu72 (5.11 Å), Tyr80 (4.06 and 4.65 Å), Trp84 (5.22 Å), Leu85 (4.66 and 4.95 Å), Met89 (4.21, 4.76 and 5.12 Å), Trp111 (5.16 Å) and Met135 (5.09 Å) (Supplementary material SI 7).

In order to investigate the potential mode of action of MKCF phytoconstituents, molecular docking was also carried out using PilY1, a protein associated with biofilms.

In the active site cavity of 3HX6: Murrayazolinol exhibited no hydrogen bonding interaction however, it showed alkyl and π-alkyl hydrophobic interactions with Ile661 (4.40 Å), Ala736 (4.38 Å), Ala794 (3.99 and 4.68 Å), Trp801 (5.02 and 5.39 Å), Leu849 (5.10, 5.11 and 5.22 Å) and Ala858 (4.14 Å) (Figure 12).

Morellin showed five H-bonding interactions with Lys790 (3.42 Å), Thr792 (2.02 Å), Pro847 (2.50 Å), Arg848 (3.05 Å) and Leu849 (2.99 Å). It showed alkyl hydrophobic interactions with Val734 (3.93 and 4.68 Å), Ala736 (3.16 Å), Lys790 (4.74 Å), Val793 (4.89 Å), Leu849 (5.38 Å) and Ile1047 (4.39 Å) (Figure 13).

Gibberellic acid, methyl ester showed two H-bonding interactions with Arg795 (2.88 Å) and Gly856 (1.86 Å), it exhibited alkyl and π-alkyl hydrophobic interactions with Leu657 (4.00 and 4.60 Å), Ala658 (4.28 Å), Ile661 (4.37 Å), Ala794 (5.04 Å) and Trp801 (4.78 Å) (Supplementary material SI 8).

7,8-Epoxylanostan-11-ol, 3-acetoxy- showed H-bonding interaction with Leu927 (2.84 Å), it showed alkyl and π-alkyl hydrophobic interactions with Tyr653 (4.09 and 5.41 Å), Ala794 (4.97 Å), Trp801 (5.42 Å), Arg848 (5.42 Å), Leu849 (4.20 Å), Ala850 (5.31 Å), Ala858 (3.86 Å) and Leu927 (4.10 Å) (Supplementary material SI 9).