The pot experiment was conducted in the greenhouse with minimum and maximum air temperatures ranging from 7.4 to 44.9 °C, situated at the University of South Africa, Florida Science Campus, Roodepoort, at a latitude of −26°9′29.274″ and a longitude of 27°55′17.663″ (28). The average relative humidity inside the greenhouse was maintained at 68%. Certified seeds of Cannabis were obtained from Marijuana SA (Pty) Ltd. (2019/092707/07) and planted in white disposable foam cups filled with the Hygro-Mix. The seeds germinated on day 10 after planting.

The plastic pots were arranged in a completely randomized design (CRD) consisting of 12 treatments, replicated three times. The treatment combinations consisted of N (0.21; 0.36; 0.54 g L⁻¹), P (0.06; 0.12; 0.24 g L⁻¹), and K (0.36; 0.6; 0.84 g L⁻¹). Fertilizers were applied at week 2 after transplanting. Fertilizers used as sole sources of nitrogen, phosphorus, and potassium were urea [CO(NH₂)2: 46% of nitrogen]; calcium superphosphate [Ca(H₂PO₄)2: 20%], and potassium sulfate (K₂SO₄: 60%), respectively. All pots were uniformly irrigated with tap water every second day using Addis’s watering can. The experiment was terminated at week 13 after planting, at the flowering stage.

Cannabis plants treated with different levels of NPK fertilizers were harvested for leaves and cleaned at the flowering stage. The leaves were air-dried in the Biochemistry Laboratory, Florida Campus, UNISA, until completely dry, and then milled and sieved to obtain a fine powder. Leaf extracts from different treatments were prepared in acetone at a concentration of 10 mg/mL, while the working concentration of the positive control was 2 mg/mL.

The antibacterial activity of the acetone crude extracts of leaf powder was determined using the two-fold serial microdilution method. Bacterial strains of A. hydrophila (ATCC 35654), E. tarda (ATCC 15947), and P. fluorescens (ATCC 13525) (Analytical Technology, South Africa) were used for the antibacterial assay. The strains were maintained in brain heart infusion agar.

The antibacterial assay was performed using a microplate serial dilution method (29). Bacterial cultures grown overnight in brain heart infusion medium (Sigma-Aldrich, South Africa) were adjusted to McFarland standard No. 1 (equivalent to 3 × 10⁸ CFU/mL). A 100-μL aliquot of sterile distilled water was added to all wells of a 96-well microtiter plate. Prepared extracts (10 mg/mL stock concentration) were added to the first row of the microplate and serially diluted in a 1:1 ratio. One hundred microliters of the adjusted bacterial culture was then added to each well. The bacterial inoculum was exposed to final extract concentrations ranging from 2.5 to 0.01 mg/mL. Acetone and gentamicin (2 mg/mL) served as negative and positive controls, respectively. The inoculated plates were incubated at 37 °C for 18–24 h. Following incubation, 40 μL (0.2 mg/mL) of p-iodonitrotetrazolium violet (INT) was added to each well and incubated for 1 h. The MIC was defined as the lowest extract concentration showing growth inhibition, indicated by a decrease in red color resulting from reduced INT conversion by actively respiring bacteria. The most active extract treatments were selected for further screening.

Data obtained from the antimicrobial and cytotoxicity experiments were expressed as mean + standard deviation (SD), as experiments were performed in triplicate and repeated three times.

Generally, among the solvent extracts of different treatments, 0 g N; 0 g P; 0.84 g K exhibited the best average antibacterial activity of 0.15 against all tested pathogens (Table 1A). In contrast, 0 g N; 0 g P; 0 g K showed the weakest average MIC value (1.77) across all tested organisms (Table 1B). Solvent extract treatment 0.36 g N; 0.12 g P; 0 g K exhibited the best MIC value (0.02 mg/mL) against E. tarda and P. fluorescens (Table 1A). Solvent extract treatment 0 g N; 0.36 g P; 0.6 g K displayed good antibacterial activity against E. tarda and P. fluorescens, with MIC values of 0.07 mg/mL and 0.05 mg/mL, respectively, while 0 g N; 0 g P; 0.84 g K demonstrated excellent antibacterial activity with an MIC value of 0.07 mg/mL against both pathogens (Table 1A). Treatment 0 g N; 0.24 g P; 0 g K also showed good antibacterial activity against E. tarda (MIC = 0.07 mg/mL) and moderate antibacterial activity against A. hydrophila and P. fluorescens, with MIC values of 0.31 mg/mL and 0.15 mg/mL, respectively (Table 1A). Furthermore, 0.54 g N; 0 g P; 0 g K, 0.36 g N; 0.06 g P; 0.12 g K, 0.36 g N; 0.12 g P; 0.36 g K, 0.21 g N; 0.06 g P; 0.36 g K, and 0 g N; 0 g P; 0 g K displayed moderate antibacterial activity against E. tarda with MIC values of 0.31, 0.15, 0.15, 0.31, and 0.31 mg/mL, respectively (Tables 1B, C).

Dried Cannabis leaves collected after exposure to different fertilizing regimens were extracted using acetone in this study. The highest percentage yield (13.73%) was obtained from solvent extract treatment 0.54 g N; 0 g P; 0 g K, followed by 0.36 g N; 0.12 g P; 0.6 g K, and 0.36 g N; 0.06 g P; 0.12 g K, which yielded 11.06 and 10.92%, respectively (Tables 2A–C). The lowest percentage yield (0.76%) was obtained from the solvent extract treatment 0 g N; 0 g P; 0 g K (control) (Table 2C). The extraction yield and bioactivities of extracts using different extractants vary considerably (34), hence the choice of acetone in this study. The average total antibacterial activity (TAA) values of the plant extracts ranged from 11 to 3,199.12 mL/g against all tested bacteria (Tables 2A–C, 3). The highest TAA value (3,199.12 mL/g; Table 2A) was produced by solvent extract treatment 0.36 g N; 0.12 g P; 0 g K against E. tarda and P. fluorescens.

The results of the anti-biofilm (ABF) potential of the Cannabis acetone extracts against selected fish pathogens are presented in Table 3. Extracts or fractions resulting in inhibition above 50% were considered to exhibit good ABF activity (++), while those with inhibition between 0 and 50% were regarded as having poor ABF activity (+), and values <0% (−) were considered to indicate no inhibition or enhancement of biofilm development and growth. All the tested extracts showed the capacity to either prevent or disrupt formed biofilms, while solvent extract treatment 0.36 g N; 0.06 g P; 0.12 g K displayed the best ABF activity. The results demonstrated that several extracts exhibited both preventive and disruptive effects against the tested pathogens. Specifically, solvent extract treatments 0 g N; 0.24 g P; 0 g K, 0.54 g N; 0 g P; 0 g K, 0.36 g N; 0.06 g P; 0.12 g K, 0.36 g N; 0.12 g P; 0.36 g K, and 0.36 g N; 0 g P; 0.36 g K were effective in both preventing and destroying (>50% inhibition) A. hydrophila. In addition, a broader range of treatments—including 0 g N; 0 g P; 0.84 g K, 0 g N; 0.24 g P; 0 g K, 0.36 g N; 0.12 g P; 0.6 g K, 0.54 g N; 0 g P; 0 g K, 0.36 g N; 0.06 g P; 0.12 g K, 0.36 g N; 0.12 g P; 0.36 g K, 0.36 g N; 0 g P; 0.36 g K, 0.21 g N; 0.12 g P; 0.36 g K, 0.21 g N; 0.06 g P; 0.36 g K, and 0 g N; 0 g P; 0 g K—showed preventive activity against the same pathogen. Solvent extract treatments 0 g N; 0.36 g P; 0.6 g K, 0.21 g N; 0.06 g P; 0.36 g K, and 0 g N; 0 g P; 0 g K were capable of both preventing and destroying (>50% inhibition) E. tarda. In the case of P. fluorescens, treatments 0.36 g N; 0.12 g P; 0.6 g K and 0.54 g N; 0 g P; 0 g K demonstrated both preventive and disruptive effects (>50% inhibition), whereas treatments 0.36 g N; 0.12 g P; 0.6 g K, 0.54 g N; 0 g P; 0 g K, 0.36 g N; 0.06 g P; 0.12 g K, 0.36 g N; 0.12 g P; 0.36 g K, 0.36 g N; 0 g P; 0.36 g K, 0.21 g N; 0.12 g P; 0.36 g K, 0.21 g N; 0.06 g P; 0.36 g K, and 0 g N; 0 g P; 0 g K were effective in preventing its growth. These findings highlight the broad-spectrum potential of some extracts, particularly treatments 0.54 g N; 0 g P; 0 g K, 0.21 g N; 0.06 g P; 0.36 g K, and 0 g N; 0 g P; 0 g K, which showed activity across multiple pathogens. Furthermore, inhibition of biofilm formation at T₀ against A. hydrophila and P. fluorescens was higher (>50% inhibition) than at T₂₄. In contrast, inhibition at T₀ against E. tarda was lower (0–50% inhibition) than that observed at T₂₄.

Interference of the Cannabis acetone extracts with QS-mediated purple pigment production in C. violaceum is indicative of QS inhibition. The results in Table 4 indicate that the solvent extracts of different treatments exhibited anti-quorum-sensing (AQS) activity against C. violaceum. All solvent extract treatments showed good anti-quorum-sensing activity, while treatment 0.36 g N; 0.06 g P; 0.12 g K achieved the highest violacein inhibition (98.61%) at a concentration of 1.25 mg/mL, followed by 0.36 g N; 0 g P; 0.36 g K, which demonstrated 97.85% inhibition at the same concentration.

The cytotoxicity activity against Vero kidney cells and the selectivity indices of solvent extracts from different fertilizer treatments are presented in Table 5. Solvent extract 0 g N; 0.24 g P; 0 g K was the most toxic, with an LC₅₀ value of 0.04 mg/mL against Vero cells, while solvent extracts 0.36 g N; 0.12 g P; 0 g K, 0 g N; 0.36 g P; 0.6 g K, and 0 g N; 0 g P; 0 g K showed moderate toxicity with LC₅₀ values of 0.06 mg/mL. The LC₅₀ values for the other solvent extracts were all greater than 0.1 mg/mL, indicating that they are non-cytotoxic to mammalian (Vero) cells. Specifically, solvent extracts 0 g N; 0 g P; 0.84 g K, 0.54 g N; 0 g P; 0 g K, and 0.36 g N; 0.06 g P; 0.12 g K showed LC₅₀ values of 0.10 mg/mL, followed by 0.36 g N; 0.12 g P; 0.6 g K, 0.36 g N; 0 g P; 0.36 g K, and 0.21 g N; 0.06 g P; 0.36 g K with LC₅₀ values of 0.09 mg/mL. Solvent extract 0.21 g N; 0.12 g P; 0.36 g K had an LC₅₀ value of 0.08 mg/mL, while solvent extract 0.36 g N; 0.12 g P; 0.36 g K had an LC₅₀ value of 0.07 mg/mL. Cytotoxicity (mg/mL) and MIC (mg/mL) values were used to calculate the selectivity index (SI) of plant extracts (SI = LD₅₀/MIC), which represents the safety margin of the extract (35). In this study, solvent extract 0.36 g N; 0.12 g P; 0 g K displayed the highest SI (3.00) against E. tarda and P. fluorescens, followed by 0 g N; 0 g P; 0.84 g K with an SI of 2.29 against the same pathogens. Solvent extract 0 g N; 0.36 g P; 0.6 g K showed a good SI (1.20) only against P. fluorescens.

For decades, Cannabis plants have been used to treat infections, and currently, novel Cannabis-derived antibiotics are highly promising and are progressing through clinical trials (36), due to their established medicinal properties (37, 38). Solvent extract treatments with MIC values ≤0.1 mg/mL were considered to exhibit significant activity, while moderate activity was defined as MIC values between 0.1 and 0.625 mg/mL, and MIC values >0.625 mg/mL were regarded as weak or poor activity (39). The antibacterial activity of Cannabis extract observed in this study is consistent with findings from other medicinal plant extracts with promising antibacterial activities. In agreement with the present results, (40) reported potent antibacterial activity of acetone extracts of Azadirachta indica against Pseudomonas species, with the lowest MIC value of 0.18 mg/mL. The results obtained by (41) demonstrated that aqueous extracts of Terminalia arjuna showed strong antibacterial activity against P. fluorescens at a concentration of 25 μL. Another study reported that methanolic leaf extracts of Ziziphus mauritiana exhibited high antibacterial activity against P. fluorescens at concentrations of 25 and 50 μg/μL (42). Generally, there is limited information on the antibacterial activity of medicinal plants against E. tarda. However, (43) reported that extracts of Moringa oleifera exhibited strong antibacterial activity against E. tarda at a concentration of 375 mg/L. The present findings are also consistent with those reported by (44), who showed that coffee leaf extracts exhibited strong antibacterial activity against E. tarda at concentrations ranging from 20 to 80%. Furthermore, leaf extracts of Lantana camara have been reported to inhibit the growth of E. tarda at a concentration of 200 mg/L (45). Based on our findings, solvent extract treatment 0 g N; 0.24 g P; 0 g K exhibited moderate antibacterial activity against A. hydrophila with an MIC value of 0.31 mg/mL, which contrasts with the findings of (46), where leaf extracts of Nelumbo nucifera showed potent activity against A. hydrophila with an MIC value of 31.25 μL/mL using an ethanol–water solvent system. In addition, (47) demonstrated that guava leaf extracts inhibited the growth of A. hydrophila at a concentration of 50%. Varying NPK fertilizer concentrations have been shown to influence plant antibacterial activity by affecting the biosynthesis of antibacterial secondary metabolites, such as flavonoids and phenolics, which possess antimicrobial properties (48). In this study, solvent extracts obtained under different fertilizer treatments, particularly 0.36 g N; 0.12 g P; 0 g K, 0 g N; 0.36 g P; 0.6 g K, 0 g N; 0.24 g P; 0 g K, and 0 g N; 0 g P; 0.84 g K, appeared to enhance the production of these bioactive compounds, resulting in strong antibacterial activity against E. tarda and P. fluorescens. However, bioassay-guided fractionation is necessary to isolate and identify the specific compounds responsible for these antibacterial activities. The results of this study suggest that Cannabis extracts have promising anti-pathogenic potential and warrant further investigation. To the best of our knowledge, this is the first study to investigate the antibacterial activities of Cannabis solvent extracts obtained under different fertilizer treatments against fish pathogens.

The yield of a plant extract is important for calculating total activity and comparing plants for bioprospecting (49). In this study, acetone solvents offered the best yields in most of the tested Cannabis extracts obtained under different fertilizer treatments; however, this does not necessarily translate into efficient extraction of antimicrobial substances. Similar to our study (22), acetone has consistently proven to be an effective extractant for screening and isolating antimicrobial compounds from plants. This is because acetone demonstrates a high capacity to extract compounds with a wide range of polarity (49). However, this does not imply that other solvents are not equally useful, as the solubility of plant extracts differs depending on the solvent and plant part used, as well as the phytochemical composition. The potency of a plant extract, referred to as TAA, can be determined on the basis of both the MIC (mg/mL) and extract yield (mg/g), which together indicate the volume (mL) to which the extract obtained from 1 g of plant material can be diluted while still inhibiting bacterial growth. In this study, solvent extract treatment 0.36 g N; 0.12 g P; 0 g K exhibited the highest mean TAA (3,199.12 mL/g) against E. tarda and P. fluorescens, suggesting that extracts obtained from 1 g of this treatment remain effective after substantial dilution and can still inhibit bacterial growth. The TAA is therefore useful for identifying suitable plant extracts for compound isolation and bioprospecting (34). It is worth noting that the antibacterial efficiency of plant extracts may be attributed to continuous plant defense against phytopathogens in their environment, which stimulates the production of broad-spectrum antimicrobial compounds (50).

Detecting and diagnosing biofilm-related infections pose significant hurdles due to their resilient nature, since mature biofilms intensify the development of antimicrobial resistance. Consequently, the efficacy of previously active antibiotics against planktonic cells becomes weakened. According to the previous study, the eradication of more than 50% of the pre-formed biofilm was considered indicative of notable anti-biofilm activity (49). Based on our findings, many of these Cannabis acetone leaf extracts showed the ability to inhibit or disrupt formed biofilms against the selected bacterial pathogens; however, few reports have explored their ability to interfere with biofilm formation and QS signaling mechanisms. The results obtained in this study are consistent with those reported by (51), which showed that the Limonia acidissima L. methanol and ethyl acetate extracts exhibited pronounced biofilm inhibitory effects, with >50% inhibition against A. hydrophila at concentrations of 250 and 500 μg/mL. Similar observations were reported by (2), who investigated the ABF activity of tea tree and peppermint essential oils against A. hydrophila and found that both exhibited strong ABF activity at concentrations of 0.0078 and 0.015 μL/mL, respectively. In addition, our findings are supported by (52), which showed that leaf extracts of Dendrophthoe falcata demonstrated good ABF activity (>50% inhibition) against A. hydrophila. Similarly, our study demonstrated that solvent extract treatments 0 g N; 0.36 g P; 0.6 g K, 0.21 g N; 0.06 g P; 0.36 g K, and 0 g N; 0 g P; 0 g K showed good inhibitory activity (>50% inhibition) against E. tarda. Most studies have investigated the antibacterial activity of plant extracts against E. tarda; however, this appears to be the first study to determine the ABF activity of Cannabis against this pathogen. In the case of P. fluorescens, solvent extract treatments 0.36 g N; 0.12 g P; 0.6 g K and 0.54 g N; 0 g P; 0 g K revealed both preventive and disruptive effects (>50% inhibition). In addition, solvent extract treatments 0.36 g N; 0.12 g P; 0.6 g K, 0.54 g N; 0 g P; 0 g K, 0.36 g N; 0.06 g P; 0.12 g K, 0.36 g N; 0.12 g P; 0.36 g K, 0.36 g N; 0 g P; 0.36 g K, 0.21 g N; 0.12 g P; 0.36 g K, 0.21 g N; 0.06 g P; 0.36 g K, and 0 g N; 0 g P; 0 g K were effective in preventing its growth. These findings are consistent with those reported by (53), where leaf extracts of Hibiscus sabdariffa demonstrated strong biofilm inhibition against Pseudomonas aeruginosa at a concentration of 0.151 mg/mL. Another study reported that methanolic leaf extracts of Bergenia ciliata and ethanolic leaf extracts of Clematis grata efficiently inhibited biofilm formation of P. aeruginosa, with 81 and 80% inhibition, respectively (54). Our observations are further supported by (55), which showed that Trigonella foenum-graceum extracts exhibited strong biofilm inhibition against P. aeruginosa. These results are also consistent with those of (56), who reported that methanol extracts of A. marina leaves not only inhibited initial cell adhesion and biofilm formation by P. fluorescens but also disrupted pre-formed biofilms, with IC₅₀ values of 42.0 and 45.8 mg/mL. Similarly, (57) reported the most significant anti-biofilm activity against Salmonella typhimurium by acetone extracts of Vachellia xanthophloea. Furthermore, our study showed that A. hydrophila and P. fluorescens were inhibited by most extracts at T_0, indicating that prevention of biofilm attachment and growth is easier to achieve than inhibition of pre-formed biofilms at T₂₄. Similarly, (31) evaluated the ABF activity of alcoholic extracts of Allium sativum against Escherichia coli and observed higher inhibition values for biofilm formation than for disruption of pre-formed biofilms. Interestingly, E. tarda was inhibited by most extracts at T_24, highlighting the effectiveness of Cannabis acetone extracts in preventing and disrupting biofilm formation by this pathogenic bacterium.

Targeting QS signaling emerges as an innovative strategy, as this mechanism focuses on virulence factors such as biofilms and others, thereby disarming pathogenic bacteria (58). The preliminary assessment of AQS activity of Cannabis leaf extracts was confirmed through the inhibition of violacein formation in C. violaceum. Violacein, a pigment produced by C. violaceum in response to QS signaling, serves as an indicator of quorum-sensing activity. The results demonstrated that the Cannabis leaf extracts exhibited anti-quorum-sensing activity against the biosensor strain C. violaceum. All tested solvent extract treatments showed good AQS activity against C. violaceum, while solvent extract treatment 0.36 g N; 0.06 g P; 0.12 g K achieved the highest violacein inhibition of 98.61% at a concentration of 1.25 mg/mL. This observation aligns with a previous study on Terminalia catappa, which reported effective inhibition of violacein production at a concentration of 0.0625 mg/mL in vitro (59). Similarly, T. catappa, T. bellerica, T. chebula, and T. macroptera have been reported to attenuate QS in Pseudomonas aeruginosa (16, 59, 60). The findings of this study are consistent with those of (61), in which Artemisia argyi leaf extracts reduced violacein formation in C. violaceum. Another study by (9) reported that Melastoma candidum leaf extracts inhibited violacein production in C. violaceum. Furthermore, the findings of this study are consistent with those of (62), who observed reduced violacein production (up to 38.34%) in C. violaceum for Melianthus comosus, Plectranthus ecklonii, and Pelargonium sidoides extracts. These results reinforce the notion that Cannabis extracts effectively inhibit quorum-sensing-regulated violacein synthesis in C. violaceum. Overall, the medicinal activities displayed by Cannabis leaf extracts against these bacterial pathogens may be attributed to the presence of biologically active compounds in acetone extracts, such as cannabinoids, phenolics, flavonoids, quinones, alkaloids, terpenoids, and polystyrenes, which play key roles in microbial pathogenicity and are involved in the inhibition of QS molecules as well as biofilm formation (63).

The widespread assumption of safety for plant extracts and other natural products is erroneous; therefore, it is essential to conduct cytotoxicity testing to provide scientific validation of their safety. According to (39), when screening plant extracts for antimicrobial potential, there is a need to evaluate their safety on mammalian cell lines. Plant extracts showing sensitivity to cell lines with LC₅₀ values >0.1 mg/mL are considered non-cytotoxic, those with LC₅₀ values ≥0.06 and <0.1 mg/mL are considered moderately toxic, and extracts with LC₅₀ values <0.06 mg/mL are considered toxic. Solvent extracts with good antibacterial activity (from significant to moderate) were selected for cytotoxicity testing. Most solvent extracts tested were non-toxic against Vero cells, except solvent extract 0 g N; 0.24 g P; 0 g K, which was toxic to Vero cells with an LC₅₀ of 0.04 mg/mL, and solvent extracts 0.36 g N; 0.12 g P; 0 g K, 0 g N; 0.36 g P; 0.6 g K, and 0 g N; 0 g P; 0 g K, which showed moderate toxicity with LC₅₀ values of 0.06 mg/mL. A similar study by (49) reported that acetone crude extracts of Eugenia umtamvunensis and Syzygium legatii had non-toxic effects on Vero cells, with LC₅₀ values of 0.82 and 0.14 mg/mL, respectively. In addition, (4) reported that acetone crude extracts of Searsia leptodictya, S. lancea, S. batophylla, Bauhinia galpinii, and B. bowkeri were not toxic to Vero cells, with LC₅₀ values of 0.11, 0.20, 0.15, and 0.51 mg/mL, respectively. Furthermore, similar to our findings, (57) reported that the acetone extract of Elephantorrhiza elephantina had a high LC₅₀ value of 3.6945 ± 0.1149 mg/mL against Vero cells. However, a variety of cell lines should be used to assess the safety of plant extracts, since findings from a single cell model may not apply to whole organisms, although the use of Vero cells reflects general toxicity. The selectivity index (SI) expresses the relationship between antimicrobial and cytotoxic activities of plant extracts on bacterial and normal cells, ensuring that biological activity is not attributed solely to in vitro cytotoxicity. According to (64), plant extracts with SI values <1 indicate that the extracts are relatively less toxic to bacteria and more toxic to mammalian cells. Thus, extracts with SI >1 may be relatively safer to use in vivo, as they are less toxic to mammalian cells but more toxic to pathogens. Therefore, solvent extract 0.36 g N; 0.12 g P; 0 g K exhibited the highest SI values against Vero cells and could be considered promising for further research (65). However, in vivo testing is necessary to validate the efficacy and safety of these Cannabis extracts. These results are consistent with findings reported by (66), where acetone extracts of Carpobrotus edulis revealed a high selectivity index of 17.07 against Enterobacter cloacae. Another study by (11) demonstrated excellent SI values of 25.18 and 50.75 for acetone extracts of B. galpinii and B. bowkeri against Salmonella enteritidis. These Cannabis extracts show potential for development into medicinal products for controlling antimicrobial infections using herbal remedies. Alternatively, isolation of active compounds may provide templates for the development of new drugs.