New Perspectives on the Use of Phytochemicals as an Emergent Strategy to Control Bacterial Infections Including Biofilms
"> Figure 1
<p>Mechanisms involved in bacterial resistance to antibiotics.</p> "> Figure 2
<p>Main mechanisms of biofilm resistance to antibiotics.</p> "> Figure 3
<p>Main antibiofilm strategies. The suggested approaches can be divided in two major lines of action: some are meant to prevent biofilm formation and others to eradicate established biofilms, and they can comprise the application of physical, chemical and biological methods. Some of them such as QSI, chelating agents and the use of natural compounds from plants (phytochemicals) can be applied for both biofilm inhibition and eradication. Although the second messenger c-di-GMP is mainly involved in the transition of the planktonic to sessile state, it can be also used as a target to disperse biofilms. The use of photodynamic therapy and nanoparticles as drug carriers is not specific for biofilm removal, as they can be useful to inhibit biofilm formation.</p> "> Figure 4
<p>Examples of plant-based molecules able to inhibit QS-regulated processes.</p> "> Figure 4 Cont.
<p>Examples of plant-based molecules able to inhibit QS-regulated processes.</p> "> Figure 4 Cont.
<p>Examples of plant-based molecules able to inhibit QS-regulated processes.</p> ">
Abstract
:1. Introduction
2. Clinical Multidrug-Resistant Bacteria—The Beginning of the Post-Antibiotic Era
2.1. Mechanisms Explaining Bacterial Resistance to Antibiotics
- Prevention of access to target by reducing permeability—Microorganisms are surrounded by a cell envelop that constitutes a selective permeability barrier and thus can effectively offer protection from drug molecules in the extracellular environment, while providing sufficient nutrients to the cell [27]. Most of the antibiotics target intracellular processes and must be able to penetrate the bacterial membrane [28]. Reduction of the concentration of the antibiotic into the cell, due to modification of the cell surface, limits the interaction with the drug (e.g., lipid A modification) or reduces the number of entry channels (e.g., porins) [27]. In Gram-negative bacteria the outer membrane serves as a physical and functional barrier. Such an outer membrane contains an inner layer that has phospholipids and an outer layer that has lipid A. This composition reduces the permeability to many drug [25]. For bacteria belonging to the Enterobacteriaceae family, the majority of the porins are thought to function as non-specific channels; an example of this is the outer-membrane proteins OmpF and OmpC of Escherichia coli [15].
- Increased efflux pumps—Several energy-dependent systems that reduce the intracellular concentration of toxic substances were identified in bacteria. EPs are transport proteins, localized in the cytoplasmatic membrane, found in both Gram-negative and -positive bacteria as well as in eukaryotic organisms. These pump systems remove toxic compounds out of the bacterial cell in a process that does not comprise the alteration or degradation of the molecules [27]. EPs can be specific for one substrate or transport a variety of structurally dissimilar substances, such as these latter pumps associated with the occurrence of MDR bacteria [29]. Currently, the identification and characterization of EPs remains one of the major problems [30]. There are five major families of EP transporters: RND (resistance-nodulation-division); MF (major facilitator); MATE (multidrug and toxic efflux); SMR (small multidrug resistance); and ABC (ATP binding cassette). In most of the bacteria, EP genes are localized in an operon controlled by a regulatory gene [31]. In the last years, new EPs have been described, such as MdeA in Streptococcus mutans, KexD in Klebsiella pneumoniae and Lmrs in Staphylococcus aureus [32,33,34].
- Degradation and modification of antibiotics—Another means by which bacteria can be resistant is by destroying the active component of the antibiotics. There are three mechanisms through which bacteria inactivate the antibiotics: enzymatic hydrolysis; group transfer; or redox process [30]. Among them, antibiotic inactivation catalysed by enzymes is the main mechanism of resistance. Various antibiotics have hydrolytically susceptible chemical bonds, e.g., esters and amides, whose integrity is central to biological activity [35]. Thousands of enzymes are known to degrade and modify antibiotics of different classes, including β-lactams, aminoglycosides, phenicols and macrolides. The expansion of antibiotic classes to include derivatives that have improved properties has been reflected by the emergence of hydrolytic enzymes that have altered spectres of activity [36,37,38,39].The β-lactamases are broadly prevalent and clinically important resistant enzymes [40]. The β-lactamases can be classified using two systems: Ambler and Bush-Jacoby-Medeiros [24]. These enzymes are the most important mechanisms of resistance in Gram-negative bacteria and can be coded on plasmids and chromosomes [25]. The genes that codify β-lactamases can be transferred by transposons but can be found in the composition of integrons [41]. There are two distinct chemical mechanisms employed by β-lactamases to hydrolytically cleave the ring of β-lactam antibiotics: formation of a covalent enzyme intermediate followed by hydrolysis or meta-activation of nucleophilic water molecules via the Zn2+ centre [30,42]. Serine β-lactamase cephalosporinases are found in Enterobacter spp. and Pseudomonas spp., penicilinases in strains of S. aureus [24,43,44,45,46]. The enzyme metallo-β-lactamase, found in Pseudomonas aeruginosa, K. pneumoniae, E. coli, and on the Gram-positive bacteria Proteus mirabilis and Enterobacter spp., is responsible for resistance to imipenem, and the new generation of cephalosporins and penicillins [25,43]. Extended-spectrum β-lactamases (ESBLs) that are active against first-generation β-lactams can be encoded in large plasmids but can also be transferred by transposon insertion [47,48,49,50,51]. Other examples of hydrolytic enzymes include esterases, which have been linked to macrolide antibiotic resistance and fosfomycin resistance ring-opening epoxidases [25]. Hydrolytic enzymes inactivate the antibiotics before the molecule can reach their target in the bacteria. Because these enzymes require only water as a co-substrate, they can often be excreted by the bacteria [30]. The most varied family of resistance enzymes is the transferases group that inactivates aminoglycosides, chloramphenicol, streptogramin, macrolides or rifampicin. The inactivation of antimicrobial agents occurs by binding adenylyl, phosphoryl, or acetyl groups to the periphery of the molecule. Phosphoryltransferases, nucleotidyltransferases, or adenylyltransferases and acetyltransferases are aminoglycoside neutralizer enzymes [52]. These enzymes can be found in S. aureus, Enterococcus faecalis and Streptococcus pneumoniae [53]. Oxidation and reduction are also used by pathogenic bacteria as a mechanism of antibiotic resistance [52,54].
- Modification of the molecular target—The majority of the antibiotics specifically bind to their targets with high affinity, so even a small mutation in a target molecule is sufficient to influence antibiotic binding to the target [52]. Alteration of the natural antibiotic target may arise from a spontaneous chromosomal mutation resulting in single or multiple amino acid modification, or from homologous recombination with exogenous DNA containing gene segments that encode proteins with low antibiotic binding affinity [30]. In clinical pathogenic bacteria, several genes that encode for target modification of the same antibiotic were already described. One example is the methicillin resistance in S. aureus [24,52,55].
2.2. Biofilms as a Contributing Factor for the Increased Resistance to Antibacterials
2.3. Drug-Resistant Microorganisms—from Environment to Clinic
3. Non-Conventional Strategies to Treat Drug-Resistant Bacteria
4. The Use of Plants as Sources of Antibiotic Adjuvants
5. Non-Conventional Strategies to Treat Bacteria Growing within a Biofilm
- (a)
- Inhibition of bacterial reversible adhesion by optimization of the physicochemical properties of the materials used in medical devices and implants, and surface modification using surfactants/biosurfactants and other types of non-antibiotic coatings;
- (b)
- Inhibition of irreversible adhesion by interference with the production of adhesins, blocking of the adhesins’ interaction with their receptors, use of chelating agents that inhibit the transport of essential metals to the interior of cells, thus stopping biochemical pathways that are crucial for biofilm formation, and inhibition of nucleotide signalling biosynthesis such as cyclic diguanosine monophosphate (c-di-GMP), which can maintain bacteria in the planktonic state;
- (c)
- Interference with the bacterial communication through the use of QS inhibitors (QSI); the use of non-pathogenic bacteria which can compete with pathogens by producing toxins (e.g., bacteriocins) or other substances, thus preventing colonization; and vaccination in order to produce antibodies against antigens of bacterial biofilms, preventing the evolution of infection.
- (a)
- Induction of dispersal by the application of enzymes (e.g., DNAse I, proteinase K, tripsin, lysostaphin, amylase, lyase and lactonase), divalent metal chelators, QS signal inhibitors, and other molecules such as d-amino acids (e.g., d-leucine, d-methionine, d-tyrosine and d-tryptophan), norspermidine, dispersin B, N-acetylcysteine, cis-2-decenoic acid, and nitric oxide;
- (b)
- The use of bacteriophages;
- (c)
- Eradication of persister cells (e.g., combined application of sugars or silver with antibiotics and/or an increase in the production of reactive oxygen species).
6. Plant-Based Strategies to Deal with Unwanted Biofilms
6.1. Phytochemicals as Quorum-Sensing Inhibitors
6.2. Phytochemicals as Biofilm Metal Chelators
6.3. Phytochemicals as Biofilm Efflux Pump Inhibitors
7. Concluding Remarks and Future Perspectives
Acknowledgments
Conflicts of Interest
Abbreviations
ABC | ATP binding cassette |
agr | accessory gene regulator |
AHLs | N-Acyl homoserine lactones |
c-di-GMP | Cyclic diguanosine monophosphate |
EPS | Extracellular polymeric substances |
ESBLs | Extended-spectrum β-lactamases |
EPs | Efflux pumps |
EPIs | Efflux pump inhibitors |
EPS | Extracellular polymeric substances |
FDA | Food and Drug Administration |
MF | Major facilitator |
MIC | Minimum inhibitory concentration |
MATE | Multidrug and toxic efflux |
MDR | Multidrug resistant |
MRSA | Methicillin-resistant S. aureus |
PGG | 1,2,3,4,6-Penta-O-galloyl-b-d-glucopyranose |
QS | Quorum sensing |
Quorum-quenching | |
QSI | QS inhibitors |
RND | Resistance-nodulation-division |
SMR | Small multidrug resistance |
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Source | Effect(s) | Bacteria | Reference(s) |
---|---|---|---|
Plant Crude Extracts | |||
Aqueous extracts from Ananas comosus, Musa paradiciaca, Manilkara zapota and Ocimum sanctum | -Inhibition of biofilm formation and virulence factor production (pyocyanin, staphylolytic protease and elastase); Reduction of N-Acyl homoserine lactones (AHLs)-mediated violacein production | P. aeruginosa PAO1; Chromobacterium violaceum CV12472 | [156] |
Extracts from Prunus armeniaca, Prunella vulgaris, Nelumbo nucífera, Panax notoginseng, Punica granatum, Areca catechu and Imperata cylindrica | -Inhibition of violacein production and swarming motility | C. violaceum CV026; P. aeruginosa PAO1 | [157] |
Methanolic extract from Capparis spinosa Linn. | -Inhibition of biofilm formation and motility (swimming and swarming); Decreases the biosurfactant and EPS production; Inhibition of violacein production | P. aeruginosa PAO1; E. coli ATCC 10536; P. mirabilis ATCC 7002; Serratia marcescens FJ584421; C. violaceum CV026/CV12472 | [158] |
Ethanolic extracts of Italian medicinal plants Ballota nigra, Castanea sativa and Sambucus ebulus | -Inhibition of δ-haemolysin production through of the interference with agr (accessory gene regulator) locus | MRSA (NRS385) clinical isolate | [159] |
Methanolic, ethanolic, chloroformic, acetonic and aqueous extracts from Salvadora persica | -Inhibition of initial adhesion and biofilm formation; Interferes with QS regulators, Streptococcus OmpP and Staphylococcus Lux proteins | S. mutans cariogenic isolates | [160] |
Crude extract and ethanolic fraction from Emblica officinalis | -Reduces cell adherence, cell-surface hydrophobicity, glucan synthesis and biofilm formation; Suppresses the expression of genes involved in biofilm formation; Obliterates biofilm structure | S. mutans MTCC 497 | [161] |
Extract of Cymbopogan citratus (lemongrass) | -Inhibition of biofilm formation; eradication of pre-formed biofilms | S. aureus NCIM 5022 | [162] |
Ethanolic extracts from Hydrastis canadensis L. (Ranunculaceae) | -Anti-QS activity by attenuation of signal transduction through the AgrCA component system; Inhibit toxin (alpha-toxin) production and prevents keratinocyte damage | S. aureus (CA-MRSA USA300 TCH1516, LAC, AH1263 and SA502A) | [163] |
Methanolic extracts from Achyranthes aspera L. (Amaranthaceae) | -Inhibition of QS through of the interaction with OmpR QS regulator; Prevent glycosyltransferase (EPS synthesizing enzyme) expression; Inhibit biofilm formation | S. mutans cariogenic isolates | [164] |
Hexane extract from Amphypterygium adstringens | -Inhibition of pyocyanin and rhamnolipid production; Decreases the elastolytic activity; Inhibition of violacein production | P. aeruginosa PA14; C. violaceum CV12472 | [165] |
Methanolic extracts from Securinega suffruticosa, Angelica dahurica, Rodgersia podophylla, Viburnum carlesii, Nymphaea tetragona var. Angusta and Mallotus japonicus | -Inhibition of swarming motility; Inhibition of violacein production | P. aeruginosa PAO1; C. violaceum CV12472 | [166] |
Methanolic extract rich in ellagic acid derivatives from Terminalia chebula Retz. | -Downregulation of lasIR and rhlIR genes expression; Attenuation of virulence factor production (pyocyanin, elastase, rhamnolipid and protease); Reduction of alginate production; Inhibition of biofilm formation and enhanced sensitivity of biofilm towards tobramycin; Enhanced survival of Caenorhabditis elegans | P. aeruginosa PAO1 | [167] |
n-hexane extract of Dalbergia trichocarpa | -Inhibition of biofilm formation, motility (swarming and twitching) and virulence factor production (pyocyanin, elastase and proteases); Increases the effectiveness of biofilm-encapsulated to tobramycin | P. aeruginosa PAO1 | [168] |
Ethyl acetate fraction of ethanol extract from Syzygium cumini L., Pimentadioica L., Centella asiatica L. and Adenanthera pavonina L.; Flavonoid fraction from leaves of Psidium guajava L. | -Inhibition of several QS-regulated phenotypes, namely: pyocyanin production, elastolytic and proteolytic activities, swarming motility and biofilm formation; Inhibition of violacein production | P. aeruginosa PAO1; C. violaceum CV026/CV12472 | [169,170,171,172] |
Polyphenol rich extract from Rosa rugosa tea | -Inhibition of swarming motility and biofilm formation; Inhibition of violacein production | E. coli K-12; P. aeruginosa PAO1; C. violaceum CV026/CV12472 | [173] |
Extracts of neotropical rainforest plants from Meliaceae, Melastomataceae, Lepidobotryaceae, and Sapindaceae families | -Biofilm formation and violacein production inhibition | P. aeruginosa PA14; C. violaceum CV12472 | [174] |
Extract from wheat bran | -Interferes with QS by degrading AHLs; Inhibition of biofilm formation; Eradication of pre-formed biofilms | Pseudomonas fluorescens (P3/pME6863 and P3/pME6000); S. aureus (BMA/FR/0.32/0074) clinical isolate | [175] |
Extracts from Chamaemelum nobile (Chamomile) | -Inhibit biofilm formation, swarming motility | P. aeruginosa PAO1 and clinical isolates from different types of infections | [176] |
Methanolic extract from Kalanchoe blossfeldiana | -Reduces virulence factors secretion (protease and pyoverdine) and cytokine formation in lipopolysaccharide-stimulated peripheral blood mononuclear cells; Inhibition of biofilm production | P. aeruginosa MTCC 2453 | [177] |
Ethanolic extract from Amomum tsaoko | -Inhibition of violacein production, swarming motility and biofilm formation | C. violaceum ATCC 12472; S. aureus ATCC 6538; Salmonella enterica serovar Typhimurium ATCC 50013; P. aeruginosa ATCC 9027 | [178] |
Methanolic extract from Anethum graveolens and one of its principle active, 3-O-methyl ellagic acid | -Downregulation of QS-regulated genes (fimC, bsmA and flhD) crucial for initial adhesion and motility; Reduction of biofilm formation and virulence factors (prodigiosin and protease) production | S. marcescens MG1/MG44 and clinical isolates | [179] |
Methanolic extract from Sygygium aromaticum | -Inhibition of biofilm formation; Inhibition of EPS and pyocyanin production, proteolytic activity and swimming motility | C. violaceum ATCC 12472; P. aeruginosa clinical isolates | [180] |
Methanolic extracts rich in ursene and oleanene derivatives (pentacyclic triterpenes) from Castanea sativa (European chestnut) | -Inhibition of haemolytic activity, harmful exotoxins (e.g., δ-toxin) production and biofilm formation (to a lesser extent) as results of the agr-mediated QS blockage; Attenuate skin abscesses in an in vivo animal model | S. aureus (AH408, SA502A, AH430, AH845, AH1263, LAC, AH1677, AH1747, AH1872, AH2759 and AH3052) | [181] |
n-hexane and dichloromethane extracts of Liriodendron hybrid barks | -Inhibition of violacein production; Inhibition of biofilm formation | C. violaceum ATCC 12472/CV026; MRSA clinical isolates | [182] |
Extract rich in polyphenols (orcinol, arabitol, apigenin, and usnic acid) from Usnea longissimi (Beard lichen) | -Inhibition of violacein production; Reduction of virulence factor secretion (acid production, ATPase, enolase, lactate dehydrogenase, protease, total exopolysaccharide content and glucosidase); Inhibition of biofilm formation; Improvement of the susceptibility to conventional antibiotics | C. violaceum CV12472; S. mutans MTCC 0497 clinical strain | [183] |
Crude extract and methanolic fraction from Z. officinale | -Inhibition of biofilm formation; Reduce the insoluble glucan synthesis and sucrose-dependent adherence; Induce the dispersal of biofilm cells; Reduce caries development using an in vivo mouse model | S. mutans UA159 | [184] |
Extract rich in flavonoids (licoricone, glycyrin and glyzarin) from Glycyrrhiza glabra | -Reduce the production of QS-regulated virulence factors (e.g., motility, biofilm formation and production of antioxidant enzymes); Downregulation of the autoinducer (AI) synthase gene (abaI) expression | A. baumannii ATCC 19606 and ATCC 17978, and clinical isolates (M2, M2 (abal::Km), M2 (Pabal-lacZ) and C1-C4) | [185] |
Methanolic extracts rich in tannin from Phyllanthus emblica, Terminalia bellirica, Terminalia chebula, Punica granatum, Syzygium cumini, and Mangifera indica | -β-lactamase inhibition as a result of the interference with agr expression; Inhibition of violacein production | S. aureus agrP3::blaZ RN6390 pRN8826; C. violaceum CV12472 | [186] |
Ethanolic extract from Piper betle | -Reduces swarming, swimming, and twitching; Inhibition of biofilm formation and pyocyanin production | P. aeruginosa PAO1 | [187] |
Phenolic extract from Rubus rosaefolius (wild strawberry) | -Inhibition of several QS-regulated phenotypes, namely: violacein production, swarming motility and biofilm formation | C. violaceum ATCC 6357; S. marcescens UFOP-001; Aeromonas hydrophila IOC/FDA110 | [188] |
Ethanol solution extract rich in evodiamine, rutaecarpine and evocarpine from Euodia ruticarpa | -Inhibition of AI-2 production; Inhibition of cell adhesion and biofilm formation | Campylobacter jejuni | [189] |
Plant pure compounds | |||
Epigallocatechin gallate from green tea | -Inhibition of biofilm formation and swarming motility; Synergistic activity with ciprofloxacin in the treatment of biofilm infections | P. aeruginosa PAO1 | [190] |
Catechin and naringenin from Combretum albiflorum | -Interfere with the pyocyanin and elastase production; Affect the AIs perception; Biofilm formation inhibition | P. aeruginosa PAO1 | [191] |
Catechins with a galloyl moiety (e.g., epichatechin gallate and epigallocatechin gallate) | -Affect AI-2 and inhibit biofilm formation | Eikenella corrodens 1073 | [192] |
Saponins, ginsenosides, and polysaccharides fom Panax ginseng | -Suppression of the production of LasA and LasB; Downregulation of AHLs synthesis; Clearance of pulmonary infections in animal studies by biofilm disruption | P. aeruginosa PAO1 and its isogenic mucoid variant (PAOmucA22) | [193,194] |
Baicalin hydrate, cinnamaldehyde and hamamelitannin | -Increase biofilm susceptibility to treatment with antibiotics (e.g., tobramycin, clindamycin, vancomycin); Enhance the survival of infected C. elegans and Galleria mellonella; Reduce the microbial load in the lungs of infected BALB/c mice | P. aeruginosa (PAO1, ATCC 9027, MH340 and MH710); Burkholderia cenocepacia (LMG 16656, LMG 16659 and LMG 18828); S. aureus (LMG 10147 and Mu50–MRSA) and clinical isolates (CS1) | [195] |
Chrysophanol, nodakenetin, shikonin and emodin from tradicional Chinese herbs (Rheum officinale Baill, Peucedanum decursivum (Miq). Maxim, Lithospermum erythrorhizon Sieb, Rheum palmatum L.) | -Inhibition of biofilm formation; Potentiation of the ampicillin activity; Proteolysis of the QS signal receptor TraR | Stenotrophomonas maltophilia GIMT1.118; P. aeruginosa PAO1; E. coli BL21(DE3) | [196] |
Allicin and ajoene from Allium sativum | -Reduction of QS-controlled virulence genes expression; Attenuation of the rhamnolipid production; Synergistic activity with tobramycin on biofilms; Cessation of the polymorphonuclear leukocytes lytic necrosis; Enable the clearance of pulmonary infections in mouse models | P. aeruginosa PAO1 | [143,197] |
Iberin from Armoracia rusticana (horseradish) | -Blockage of the QS-regulated genes expression by targeting LasIR and RhlIR QS networks; Downregulation of rhamnolipid production | P. aeruginosa PAO1 | [146] |
Methyl eugenol from Cuminum cyminum | -Inhibition of biofilm formation, motility (swimming and swarming) and EPS production | P. aeruginosa PAO1; P. mirabilis ATCC 7002; S. marcescens FJ584421 | [198] |
Rosmarinic acid, naringin, chlorogenic acid, morin and mangiferin | -Inhibition of biofilm formation and virulence factor production (protease, elastase and haemolysin) | P. aeruginosa PAO1; P. aeruginosa AS1 and AS2 | [199] |
Curcumin from Curcuma longa L. | -Inhibition of biofilm formation and attenuation of QS-dependent factors (exopolysaccharide and alginate production); Inhibition of swimming and swarming motility; Biofilm susceptibility enhancement to antibiotics; Enhanced survival rate of Artemia nauplii | E. coli ATCC 10536; P. aeruginosa PAO1; P. mirabilis ATCC 7002; S. marcescens FJ584421; Vibrio harveyi MTCC 3438, Vibrio parahaemolyticus ATCC 17802 and Vibrio vulnificus MTCC 1145 | [200,201] |
Glycosylflavonoids (chlorogenic acid, isoorientin, orientin, isovitexin, vitexin, and rutin) from Cecropia pachystachya Trécul | -Inhibition of violacein production; Inhibition of bioluminescence production | C. violaceum ATCC 31532; E. coli pSB403 | [202] |
Salicylic acid | -Inhibit swimming motility; Dual-species biofilms enhancement to a second exposure to salicylic acid | Bacillus cereus isolated from a disinfectant solution; P. fluorescens ATCC 13525 | [203] |
Salicylic acid, tannic acid and trans-cinnamaldehyde | -Inhibition of AHLs and pyocyanin production | P. aeruginosa PAO1 | [204] |
[6]-gingerol, [6]-shogaol and zingerone from Zingiber officinale Roscoe | -Inhibition of biofilm formation, violacein and pyocyanin production | C. violaceum MTCC 2656; P. aeruginosa MTCC 2297/PA14 | [205,206] |
Zingerone from ginger root | Decreases swimming, swarming and twitching motility; Reduces biofilm-forming capacity; Interferes with the production of virulence factors including rhamnolipid, elastase, protease, pyocyanin; Improves the antibiofilm efficacy of ciprofloxacin | P. aeruginosa PAO1 | [207,208] |
Sesquiterpenoid viridiflorol and triterpenoids, ursolic and betulinic acids, from the liverwort Lepidozia chordulifera | -Inhibition of biofilm formation and elastolytic activity | P. aeruginosa ATCC27853; S. aureus ATTC6538 | [209] |
Malvidin of methanolic extract from Syzygium cumini | -Inhibition of violacein production, EPS synthesis and biofilm formation; Potentiation of the susceptibility to conventional antibiotics | C. violaceum CV026/MTCC 2656; K. pneumoniae PUFST23 | [210] |
Hamamelitannin | -Increases the in vitro biofilm susceptibility to vancomycin treatment through the TraP receptor by affecting cell wall biosynthesis (peptidoglycan) and extracellular DNA release; Increases the in vivo susceptibility to antibiotic treatment using C. elegans and mouse (mammary gland infection) models | MRSA Mu50 | [211] |
Essential oils and components | |||
Clove essential oil | -Inhibition of LasB, total protease, chitinase, pyocyanin and exopolysaccharide production; Swimming motility and biofilm formation reduction | P. aeruginosa PAO1; A. hydrophila WAF-38 | [212] |
Essential oil from Murraya koenigii | -Inhibition of violacein production; Biofilm formation inhibition; Reduces cell adhesion, metabolic activity and EPS production; Prevents biofilm maturation | C. violaceum CV026/CV12472; P. aeruginosa PAO1 | [213] |
Cinnamon oil | -Inhibits biofilm formation and virulence factors production (pyocyanin, rhamnolipid, and protease); Reduces alginate and EPS production, and swarming motility | P. aeruginosa PAO1 | [214] |
Mentha piperita essential oil (peppermint) and menthol | -Inhibition of violacein production; Biofilm formation, EPS production and swarming motility inhibition; Affect QS regulate virulence factors production (elastase, total protease, pyocyanin and chitinase); Interference with las and pqs QS systems; Enhanced survival of C. elegans | C. violaceum CV026; P.aeruginosa; A. hydrophila; E. coli (MG4/pKDT17 and pEAL08-2) | [215] |
Clove bud oil | -Attenuation of extracellular DNA, exopolysaccharides and pigment production; Decreases the transcription of pqsA gene; Biofilm inhibition and dispersal | P. aeruginosa PAO1 | [216] |
Eugenol | -Inhibition of violacein production, elastase, pyocyanin and biofilm formation; Interference with las and pqs QS systems | C. violaceum CV026; P. aeruginosa PAO1/PAO-MW1; E. coli (MG4/pKDT17 and pEAL08-2) | [217] |
Carvacrol | -Inhibition of biofilm formation; Reduction of the expression of cviI gene, production of violacein and chitinase activity | C. violaceum ATCC 12472; S. enterica serovar Typhimurium DT104; S. aureus 0074 | [218] |
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Borges, A.; Abreu, A.C.; Dias, C.; Saavedra, M.J.; Borges, F.; Simões, M. New Perspectives on the Use of Phytochemicals as an Emergent Strategy to Control Bacterial Infections Including Biofilms. Molecules 2016, 21, 877. https://doi.org/10.3390/molecules21070877
Borges A, Abreu AC, Dias C, Saavedra MJ, Borges F, Simões M. New Perspectives on the Use of Phytochemicals as an Emergent Strategy to Control Bacterial Infections Including Biofilms. Molecules. 2016; 21(7):877. https://doi.org/10.3390/molecules21070877
Chicago/Turabian StyleBorges, Anabela, Ana Cristina Abreu, Carla Dias, Maria José Saavedra, Fernanda Borges, and Manuel Simões. 2016. "New Perspectives on the Use of Phytochemicals as an Emergent Strategy to Control Bacterial Infections Including Biofilms" Molecules 21, no. 7: 877. https://doi.org/10.3390/molecules21070877
APA StyleBorges, A., Abreu, A. C., Dias, C., Saavedra, M. J., Borges, F., & Simões, M. (2016). New Perspectives on the Use of Phytochemicals as an Emergent Strategy to Control Bacterial Infections Including Biofilms. Molecules, 21(7), 877. https://doi.org/10.3390/molecules21070877