Chromobacterium violaceum (C. violaceum) is a Gram-negative coccobacillus and an environmental bacterium commonly found in soil and water, particularly in tropical and subtropical regions. Infections with C. violaceum are often linked to skin injuries, trauma, or water exposure, which provide a route for the bacterium to enter the body (1,2). A distinctive characteristic of C. violaceum is its production of violacein, a violet pigment regulated through a quorum sensing (QS) system (3,4). C. violaceum, as with numerous other opportunistic pathogens, forms biofilms with structured communities of bacterial cells encased in a protective matrix (5). This biofilm formation enhances its ability to produce various exotoxins, including hemolysins, which can lyse red blood cells (RBCs) and other host cells (1,2). Additionally, its outer membrane contains lipopolysaccharides (LPS), potent endotoxins that are recognized by the host immune system as danger signals, triggering an inflammatory response. In systemic infections, the excessive release of LPS can lead to septic shock a severe and life-threatening condition marked by widespread inflammation and multi-organ failure (1,6).

C. violaceum possesses both type III and type VI secretion systems (T3SS and T6SS), needle-like structures that inject virulence proteins directly into host cells. These systems are crucial for delivering effector proteins that manipulate host cell functions, such as inhibiting immune responses or inducing apoptosis, enhancing the ability of the bacterium to survive and multiply within host tissues (7). Additional virulence factors include motility via flagella, siderophore production, antioxidant enzymes and proteases, all of which contribute to rapid invasion, tissue destruction and resistance to immune defenses, complicating treatment and increasing the severity of infections (8).

One of the most alarming characteristics of C. violaceum is its unexpected resistance to a number of commonly used antibiotics, largely attributed to its QS mechanisms (9). The link between QS and pathogenesis underscores the urgent need for the development of innovative strategies to combat infections and mitigate their harmful effects on human health (10). In light of these challenges, early treatment of the pathogen, particularly through the use of natural compounds, is vital for improving patient outcomes (11). Given that plant-based medicines are often reported to be reliable, effective and relatively safe, they continue to be widely used in traditional medicine worldwide (12). Furthermore, as they are derived from natural sources, plant-based treatments are considered to cause fewer side-effects than modern synthetic drugs. A recent study demonstrated that natural compounds, particularly plant-derived flavonoids, have greater potential to combat dental bacterial biofilms; these compounds exhibit promising antibiofilm properties, rendering them effective alternatives for preventing and managing dental infections (13).

Pithecellobium dulce (P. dulce), a fruit of American origin from the Fabaceae family, is native to tropical America and widely grown in India and the Andaman Islands (14). Commonly referred to as ‘Jungal Jalebi’ or ‘Black Bead Tree’ in English, ‘Vilayati Babul’ in Hindi and ‘Kodukkapuli’ in Tamil, P. dulce is an evergreen, medium-sized, spiny tree (15). Various parts of the plant have notable medicinal uses, with the root extracts exhibiting estrogenic activity (16). Traditionally, different plant parts have been employed to treat earaches, leprosy, peptic ulcers, toothaches and venereal diseases, and serve as emollients, abortifacients, anodynes and larvicides (17). The bark of P. dulce is used as an astringent for dysentery and febrifuge, as well as to treat dermatitis and eye inflammation. Polyphenols in the bark have demonstrated anti-venomous properties (18). Additionally, ethanolic extracts from the pod pulp of P. dulce have been shown to exhibit antibacterial activity against both Gram-positive and Gram-negative bacteria, including Bacillus subtilis and Klebsiella pneumoniae, with secondary metabolites, such as flavonoids and saponins contributing to this antibacterial effect (19).

To the best of our knowledge, the present study is the first study to date aiming to investigate the effects of P. dulce isolates on C. violaceum. The anti-QS functions of P. dulce in relation to C. violaceum have not yet been thoroughly investigated.

C. violaceum is an opportunistic pathogen that is usually linked to serious infections that occur after skin injuries or water contamination exposure (23). Treatment is complex, and the risk of systemic infections, such as septicemia and meningitis are increased due to its capacity to produce virulence factors such as violacein and different exotoxins, as well as its ability to form biofilms. The growing resistance of bacteria to widely used antibiotics has made treating infections increasingly challenging, pushing the need for alternative solutions (12,24). In this context, natural remedies are gaining recognition as a promising approach for the future. As antibiotic resistance escalates, natural compounds known for their diverse bioactive properties offer the potential for safer and more effective treatments. This marks a pivotal shift in the management of infections, paving the way for innovative strategies in the coming era.

The present study highlights the potent antibacterial and antibiofilm properties of P. dulce, demonstrating its effectiveness against C. violaceum CV12472. The extracts from both the seeds and fruits exhibited significant growth inhibition at concentrations as low as 20 mg/ml, indicating that P. dulce may serve as a viable natural alternative to conventional antibiotics. This is particularly relevant given the increasing prevalence of antibiotic resistance among pathogenic bacteria. Studies have demonstrated that P. dulce exhibits significant antibacterial effects against Streptococcus mutans at concentrations of 25, 50 and 100 µl (25). These findings add to the growing body of evidence supporting the potential of natural substances as alternatives to conventional antibiotics. Additionally, P. dulce has been shown to exhibit bactericidal activity against Acinetobacter baumannii at a concentration of 233 mg/ml, as well as against Staphylococcus aureus and Escherichia coli at 300 mg/ml. These results highlight the promising role of P. dulce as a natural antimicrobial agent with broad-spectrum activity (26).

Additionally, the investigation into the anti-QS properties of P. dulce is a novel aspect of the present study, as QS plays a critical role in the virulence of many bacteria, including C. violaceum CV12472. By inhibiting QS mechanisms, P. dulce may disrupt biofilm formation and reduce virulence factor production, thereby enhancing treatment outcomes. Recent studies have highlighted a range of natural compounds with notable anti-biofilm and QS inhibitory activities (9,22,25). One such compound is epigallocatechin gallate (EGCG), a polyphenol derived from green tea. EGCG has demonstrated notable efficacy in disrupting biofilms, achieving up to 95% inhibition in certain bacterial strains, particularly when used in combination with antibiotics. This underscores its potential as a valuable adjunct in antimicrobial therapies aimed at overcoming biofilm-associated infections (27). This synergistic approach not only enhances the efficacy of existing antibiotics, but also addresses the challenge posed by biofilm-associated infections. The observed inhibition of biofilm formation in the present study by P. dulce (seed) at sub-MIC level of 10 mg/ml, with a reduction of up to 58.91%, along with an impressive 80.66% decrease in violacein production in C. violaceum CV12472, underscores its strong potential to disrupt key survival mechanisms of the pathogen. By contrast, the P. dulce fruit extract exhibited limited effects on biofilm formation. This comparative insight suggests that the bioactive compounds in the seed extract may target key pathways in biofilm-related infections more effectively than those in the fruit extract. These results position P. dulce (seed) as a promising candidate for combating biofilm-related infections and QS-mediated virulence. Similarly, research on QS inhibitors (QSIs) has shown significant reductions in biofilm biomass when combined with antibiotics. For instance, Brackman et al (28) reported that the co-administration of QSIs alongside antibiotics resulted in a 68-90% reduction in viable bacteria within biofilms. This demonstrates the effectiveness of combination therapies in combating resistant strains, such as P. aeruginosa and S. aureus, offering a promising strategy to overcome biofilm-associated infections (29). Additionally, a previous study revealed that the synthesis and testing of phytochemical tannic acid-mediated gold nanoparticles effectively inhibited the biofilm of Streptococcus mutans at lowest concentration range of 16 µg/ml (30). Furthermore, recent studies have reported that the methanol extract of Actinidia deliciosa (kiwi fruit) exhibits significant antibiofilm activity at a concentration of 2.5 mg/ml (31). These results are consistent with those obtained with P. dulce, which likewise functions as an antibacterial agent and an anti-QS compound. Furthermore, the present study (Fig. 4) demonstrated that P. dulce seed extract did not inhibit planktonic growth at a concentration of 10 mg/ml, underscoring its specific effect on biofilm formation rather than broad antibacterial activity.

The findings of the present study indicated that both seed and fruit extracts of Pithecellobium dulce inhibited the growth of C. violaceum CV12472 at 20 mg/ml. However, only the seed extract significantly reduced biofilm formation and violacein production at a sub-MIC concentration of 10 mg/ml, suggesting the presence of bioactive compounds such as flavonoids, anthocyanin, tannins, coumarin, triterpenoids, saponins, alkaloids, sterols and fatty acids that likely target bacterial adhesion and QS pathways essential for biofilm development (32). By contrast, the fruit extract demonstrated limited antibiofilm and anti-QS effects, with no change in violacein production, potentially due to the absence or lower concentrations of these specific compounds.

Integrating P. dulce seed extract into existing treatment regimens presents a promising strategy for managing biofilm-associated infections, particularly as an adjunct to conventional antibiotics. Its selective antibiofilm properties highlight its potential as a natural agent in the fight against biofilm formation and pathogen virulence, addressing the urgent challenge of rising antibiotic resistance.

However, the present study focused solely on C. violaceum CV12472; thus, while the results are promising, they may not extend to other biofilm-forming bacteria. Furthermore, these findings are based on in vitro assays, which may produce different results in vivo, where complex host factors can influence bioactivity. Variability in compound concentrations across different P. dulce sources may also affect the consistency of therapeutic effects.

In order to validate the efficacy and safety of P. dulce seed compounds, in vivo studies are essential. Animal models could provide insight into pharmacokinetics, bioavailability and therapeutic potency in physiological conditions, where host factors may modulate the effects. Such studies would help determine optimal dosing strategies and assess potential synergy when combined with conventional antibiotics. Additionally, in vivo research could reveal any anti-inflammatory or immunomodulatory effects of P. dulce, further supporting its therapeutic potential for biofilm-associated infections.

Future research is required to focus on elucidating the precise mechanisms behind the antibiofilm and anti-QS activities of key compounds in P. dulce seeds. Expanding studies to include a broader range of pathogenic strains would also help confirm the broader applicability of P. dulce seed extract as a therapeutic agent in managing biofilm-associated infections.

Taken together, the findings of the present study indicate that integrating plant-based extracts into treatment regimens could provide a dual advantage: Combating antibiotic resistance, while simultaneously targeting bacterial virulence mechanisms. This approach aligns with the increasing interest in phytotherapy and the use of natural compounds as adjuncts or alternatives to traditional antibiotics.

In conclusion, the present study made an attempt towards screening edible fruits and seeds that inhibit the QS regulated development of biofilms and virulence factors in antibiotic resistant C. violaceum. Notably, to the best of our knowledge, the present study is the first to demonstrate that P. dulce seed extract effectively inhibits biofilm formation of C. violaceum at a sub-MIC of 10 mg/ml, without affecting planktonic cell growth. This highlights its targeted effect on biofilm inhibition rather than exerting broad-spectrum antibacterial activity. These findings suggest that P. dulce seed extracts may serve as potent anti-QS agents, offering potential for managing C. violaceum infections. Therefore, the extracts, either alone or in combination with existing antibiotics, could be effectively utilized as anti-infective agents to help manage stubborn infections caused by C. violaceum.

The exploration of the anti-QS properties of P. dulce not only adds depth to its antimicrobial profile, but also aligns with emerging strategies that leverage natural compounds to combat antibiotic resistance and enhance treatment outcomes against biofilm-associated infections. As research continues to unveil the complexities of bacterial behavior and resistance mechanisms, plant-derived compounds such as P. dulce may play an integral role in future therapeutic developments.