Antifungal Essential Oil Metabolites

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geraniol, thymol and borneol inhibited growth of Aspergillus niger, Penicillium chrysogenum ... Thymol and borneol effectively inhibited two brown-rot fungi,.
IRG/WP 10-30531

THE INTERNATIONAL RESEARCH GROUP ON WOOD PROTECTION Section 3

Wood Protecting Chemicals

Antifungal Essential Oil Metabolites Carol A. Clausen1, Bessie M. Woodward1 and Vina W. Yang1 1

U.S. Forest Service

Forest Products Laboratory

One Gifford Pinchot Drive

Madison, Wisconsin 53726 U.S.A.

Paper prepared for 41st Annual Meeting

Biarritz, France

9-13 May, 2010

Disclaimer The opinions expressed in this document are those of the author(s) and are not necessarily the opinions or policy of the IRG Organization.

IRG SECRETARIAT

Box 5609

SE-114 86 Stockholm

Sweden

www.irg-wp.com

Antifungal Essential Oil Metabolites Carol A. Clausen1, Bessie M. Woodward1 and Vina W. Yang1 1

U.S. Forest Products Laboratory, One Gifford Pinchot Drive Madison, Wisconsin 53726 U.S.A. [email protected] [email protected] [email protected]

ABSTRACT New environmentally-friendly wood protection systems based on “green” technologies are needed to inhibit wood-inhabiting mold and decay fungi. Utilizing bioactive essential oils from select herbaceous plants is one promising approach, but the concentrations of bioactive compounds are somewhat variable even in the highest (therapeutic) grade essential oils. Purified primary metabolites from four bioactive plant essential oils were evaluated for antifungal activity in southern pine treated with those compounds. Purified carvone, citronellol, geraniol, thymol and borneol inhibited growth of Aspergillus niger, Penicillium chrysogenum and Trichoderma viride for 12 weeks at concentrations equal to or less than those present in therapeutic grade essential oils. Thymol and borneol effectively inhibited two brown-rot fungi, Postia placenta and Gloeophyllum trabeum and one white-rot fungus, Trametes versicolor, but other metabolites tested were ineffective against the decay fungi. Select purified bioactive metabolites of essential oils effectively inhibit fungi that inhabit wood and wood products.

Keywords: essential oil, mold fungi, decay fungi

The use of trade or firm names in this publication is for reader information and does not imply endorsement by the U.S. Department of Agriculture of any product or service. The Forest Products Laboratory is maintained in cooperation with the University of Wisconsin. This article was written and prepared by U.S. Government employees on official time, and it is therefore in the public domain and not subject to copyright.

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1. INTRODUCTION Essential oils from herbaceous plants have been used most often in the food industry as flavoring, the cosmetics industry as fragrance, and the pharmaceutical industry for their functional properties. Essential oils are now being evaluated as fungitoxic and insecticidal wood protectants. Research on the antifungal and insecticidal properties of essential oils from woody plants, such as juniper, cypress, Melaleuca, eucalyptus, or yellow cedar (Park and Shin 2005, Sim et al. 2006; Yi et al. 2006, Mater et al. 2006), has sharply increased as environmental concerns about commercial wood preservatives have initiated interest in “green” preservatives. Several herbaceous plant essential oils have been reported to possess inhibitory properties against mold and decay fungi (Yang and Clausen 2006; 2007; 2008; Kartal et al. 2006; Shujun et al. 2007; Karic et al. 2006), and subterranean termites (Chang and Cheng 2002; Zhu et al. 2003; Raina et al. 2007; Clausen and Yang 2009; Clausen 2009). Utilizing essential oils as wood preservatives causes concern over innately variable bioactivity that is likely to occur in any natural product such as a plant extract. Bioactivity can vary greatly because of variability in chemical composition of plant oil, which is dependent largely on the part of the plant that is extracted, time of the year the plant is harvested, climatic and soil variations and portion of the plant that is extracted. Certain plant species, such as thyme, oregano, basil, rosemary and mint are consistently bioactive due to one or more of the constituents of the oil (Isman and Machial 2006). Essential oils are complex mixtures comprised of a large number of constituents in variable ratios (van Zyl et al. 2006). There are no regulations for essential oils in America, however AFNOR (Association French Normalization Organization Regulation) and ISO (International Standards Organization) certification standardizes the chemical profile and principal constituents that differentiate therapeutic grade from lower grade (referred to as Grade A) essential oils. Analysis of the principal constituents is reported in certified oils to ensure that a minimal level of activity is present based on those constituents. The objective of this study was to evaluate the purified principal metabolites of four essential oils for bioactivity. The four essential oils demonstrate antifungal activity against decay and mold fungi. 2. EXPERIMENTAL METHODS 2.1 Essential oils Primary metabolites from four therapeutic grade essential oils were evaluated in this study. Test chemicals obtained from Sigma-Aldrich (St. Louis, MO) are listed in Table 1 along with the essential oil they comprise. Ninety-five percent ethanol was used as the diluent. 2.2 Mold test Mold fungi, Aspergillus niger 2.242, Penicillium chrysogenum PH02, and Trichoderma viride ATCC 20476, were grown on 2% malt extract agar for 2 weeks. A mixed mold spore suspension was prepared by washing the surface of one Petri dish for each test organism with 10 mL of sterile deionized water (DI) according to ASTM standard D4445-91 (ASTM 1998). Spores were collected, counted and equal numbers of spores for each test organism were transferred to a spray bottle. The spore mixture was diluted with DI water to yield approximately 3 x 107 spores ml-1. The spray bottle was adjusted to deliver 1 ml inoculum per spray and was mixed frequently during inoculation to ensure a homogeneous inoculum.

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Table 1: Major components of 4 therapeutic grade essential oils.

Botanical name Anethum graveolen

Common name Dill weed "

Test Chemical Carvone Limonene

Concentration [%]a 35.2 12.7

Pelargonium graveolens

Egyptian geranium "

Citronellol Geraniol

50 19

Spanish Rosmarinus officinalis rosemary Cineol 30 " Borneol 20 White Thymus zygis thyme Thymol 38 " Cymene 20 a Approximate percent of test chemical present in therapeutic grade essential oil. Southern pine (7 x 20 mm cross section by 7 cm long) cut from kiln-dried lumber was soaked for 24 hr before testing. Average moisture content was 20% by weight prior to testing. Five random replicate specimens were dip-treated for 30s in individual test solutions. Treated specimens were held in a covered container overnight according to ASTM standard test method D4445-91. Five specimens for each treatment were arranged over 4 layers of blotting paper that was saturated with 30 mL DI water and a polyethylene mesh spacer in sterile disposable Petri dishes (150 x 25mm) (B-D Falcon, Los Angeles, CA). Ethanol-treated wood blocks served as a diluent control. Untreated specimens dipped in DI water served as a positive control. After spraying with 1 mL mixed mold-spore inoculum, plates containing specimens were sealed in polyethylene bags to prevent drying and were incubated at 27ºC and 70% RH. Specimens were individually visually rated for mold growth at 4, 8, and 12 weeks on a scale of 0–5, with 0 denoting no mold growth and 5 representing heavy mold growth. 2.3 Decay test Soil block culture bottles were prepared according to AWPA E-10-09 (American Wood Protection Association (AWPA 2009). Southern pine feeders were inoculated with the brown-rot fungi Postia placenta (Fries) Lars. & Lomb. MAD 698, and Gloeophylum trabeum (Pers:Fries) Murrill, MAD 617, and yellow poplar feeders were inoculated with the white-rot fungus, Trametes versicolor (L.: Fr.) Quel. MAD 697. Bottles were incubated at 27ºC and 70% RH for 3 weeks until the fungus completely colonized each feeder. Pre-weighed 1 x 1 x 1 cm southern pine blocks conditioned at 27ºC and 70% RH, were vacuum-treated for 40 min at 172 kPa with each treatment concentration listed in Table 1 (n=5 per fungus). Blocks were conditioned at 27ºC for 14 days and reweighed to determine chemical retention. Following conditioning, blocks were gas-sterilized with propylene oxide and placed on actively growing feeders in soil bottle cultures. Soil bottles were incubated at 27ºC, 70% RH for 10 weeks. Following incubation, surface mycelium was brushed from each block before the blocks were oven-dried at 60ºC for 24h, and reconditioned at 27ºC and 70% RH to a constant weight. Average chemical retention and percentage weight loss were calculated.

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3. RESULTS AND DISCUSSION 3.1 Mold test Yang and Clausen previously reported that select therapeutic grade essential oils demonstrated bioactivity against mold fungi in laboratory tests (Yang and Clausen 2006; 2007; 2008). They also reported that thyme oil diluted 1 to 4 was an effective mold inhibitor for up to 22 weeks. The concentration of the primary metabolites in those essential oils, based on GC analysis of the therapeutic grade oils, served as the starting point for determining efficacy of the individual components. A summary of mold inhibition ratings is given in Table 2. At the concentrations found in therapeutic grade essential oils, all individual test chemicals completely inhibited the mold fungi used in this study for the 4-week duration of the ASTM D4445 laboratory test. The test was incubated for 12 weeks to evaluate long-term bioactivity due to the volatility of these compounds. Table 2: Average mold ratings for southern pine dip-treated with purified essential oil constituents. Essential Oil Constituents

Concentration Average Mold Rating Tested [%]a 4 wk 8 wk 12 wk Carvone 10 0 0 0.2 5 0 0 1.2 2.5 0 0.3 2.3 1.25 0 1.3 2.2 Limonene 10 2.4 4 4 Citronellol 2.5 0 0 0 1.25 0 0.7 2.8 Geraniol 2.5 0 0 0 1.25 0.2 0.2 0.7 Cineol 30 0.7 3 3.2 Borneol 20 0 0 0.5 10 0.8 0.8 1.4 Cineol/Borneol 30/20 0 0 0 Thymol 40 0 0 0 10 0 0 0.2 Cymene 100 0 4.2 3.4 20 0 2.5 2.3 10 2.4 4.3 3.8 5 0.3 3 4.2 Thymol/Cymene 10/5 0 0.2 0 Control 0 2.8 3 4.8 a Percent dilution from the concentrated oil Dill weed oil is primarily comprised of carvone (~35%) and limonene (12%). Purified carvone was a very effective mold inhibitor at 5% for 12 weeks and 1.25% for 8 weeks. However, purified limonene was not effective at 10% after 4 wk incubation. Egyptian geranium oil is primarily comprised of citronellol (50%) and geraniol (19%). In their purified form, 1.25% of the individual constituents effectively inhibited all mold fungi tested after 8 weeks incubation.

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The two major constituents of Spanish rosemary, cineol (Eucalyptol) (30%) and borneol (20%) gave mixed results for the mold test. Cineol was ineffective at inhibiting the mold test fungi beyond 4 weeks, but borneol was highly effective for 12 weeks or more at10%. A cineol/borneol mixture in the same proportion as they are found in Spanish rosemary showed complete inhibition of mold on southern pine, suggesting these two components are working synergistically. Similarly, thymol, comprising 38% of white thyme oil, was a very effective mold inhibitor even at 10% for 12 weeks, but cymene, comprising only 5% of white thyme oil was ineffective at twice that concentration (10%) in the purified form. A thymol/cymene mixture in the same proportion as they are found in white thyme oil provided nearly complete protection against mold growth on the diptreated pine specimens, suggesting possible synergy. While it appears that the primary metabolite(s) of thyme and rosemary oils used in this study were more effective in combination than alone, bioactive synergism cannot be verified. Thymol and borneol may be individually responsible for a majority of the bioactivity of white thyme and Spanish rosemary oils, respectively. The contribution of minor metabolites was not evaluated in this study. Klaric et al. (2006) characterized essential oil of thyme and pure thymol, the primary constituent of thyme oil, for the minimum inhibitory concentration needed to inhibit mold isolated from damp dwellings of Slovakia. They concluded that the vaporous phase of thyme oil exhibited long-lasting suppressive activity on molds (60-d exposure), suggesting that thymol or thyme essential oil could be used to disinfect mold on walls at low concentration. They also reported that pure thymol exhibited approximately three times stronger inhibition of molds than thyme oil. Our results in this study agree with Karic et al. For the mold fungi tested in this study, thymol is present in white thyme oil at 4 times the concentration needed to inhibit the test fungi, carvone is present in dill weed oil at 14 times the concentration needed to inhibit the test fungi, and geraniol and citronellol are present at 15 to 20 times higher concentration, respectively in Eyptian geranium oil than needed to inhibit mold fungi for 12 weeks. Only borneol, comprising 20% of Spanish rosemary was not efficacious at lower concentrations. However, a borneol and cineol mixture (20:30) in the proportions found in Spanish rosemary appeared to be more efficacious in combination; cineol alone was unable to inhibit the test fungi at 30%. 3.2 Decay test Only chemical constituents that individually demonstrated bioactivity against mold fungi were further tested for inhibition of decay fungi. The five primary constituents of bioactive essential oils were evaluated for decay resistance at the same concentrations that inhibited the mold fungi. Results of vacuum-treated wood blocks challenged with two brown-rot fungi and one white-rot fungus are shown in figure 1. While inhibition of mold spore germination is considerably more difficult than inhibition of decay fungi, only two of the five metabolites, thymol (10%) and borneol (8%) inhibited the three decay fungi used in this study.

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Figure 1: Percentage weight loss in wood blocks treated with 5 bioactive essential oil metabolites and challenged with three decay fungi in soil bottle culture. Aromatic compounds of dill have been reported to retain 40 constituents that were identified as essential volatiles after more than 35 years storage (Jirovetz et al. 2003). Jirovetz and others (2003) found that the two primary aromatic compounds identified from dill, D-carvone (50.1%) and Dlimonene (44.1%), retained their bioactivity against the mold fungus, Aspergillus niger. To prevent inactivation of the volatile bioactive compounds in this study, propylene oxide was used to sterilize treated specimens for the decay test. Previous findings of Yang and Clausen (2006; 2007; 2008) described mold-inhibiting properties of select therapeutic grade essential oils as dip treatments of southern pine in laboratory tests. Egyptian geranium and white thyme oils demonstrated mold-inhibitory properties as a surface treatment for wood, and volatile components of dill weed and Spanish rosemary oils demonstrated mold inhibition as fumigants. Utilizing purified forms of the bioactive metabolites in essential oils could have broad applications for wood protection, particularly if they retain long-term bioactivity and are efficacious as

surface treatments and fumigants.

3.3 Chemical retention Table 3 summarizes chemical retentions for individual essential oil constituents that demonstrated bioactivity against mold fungi. The percent active ingredient represents the effective concentration against mold fungi and a 1:2 dilution of the effective concentration. A linear dose-response was observed between percent active ingredient and retention in the wood blocks.

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Table 3: Chemical retention rates for five metabolites from bioactive essential oils. Retentions Chemical Carvone

AI [%] 5 2.5 Citronellol 2.5 1.25 Geraniol 2.5 1.25 Thymol 10 5 Borneol 20 8 a AI; active ingredient b PCF, pounds per ft3

a

PCFb 1.35 0.66 0.64 0.34 0.67 0.32 2.86 1.36 5.76 2.69

kg/m3 21.63 10.49 10.19 5.37 10.72 5.14 45.75 21.77 92.12 43.03

4. CONCLUSIONS Primary metabolites, carvone, citronellol, geraniol, thymol and borneol, from four bioactive plant essential oils, were effective inhibitors of mold spore germination for 12 weeks in their purified form. Thymol and borneol inhibited 2 brown-rot fungi and 1 white-rot fungus at the same concentration that inhibited the mold test fungi, but the remaining metabolites did not effectively inhibit the decay fungi. The high price of therapeutic grade plant essential oils is offset by their low effective dose as mold inhibitors. However, purified components of these oils would be more economical, readily available, and subject to even higher quality control than therapeutic essential oils. Utilizing purified forms of select bioactive metabolites from essential oils could have broad applications for wood protection, particularly if they retain long-term bioactivity and are efficacious as surface treatments and fumigants. 5. REFERENCES American Society for Testing Materials (ASTM). (1998): Standard test method for fungicides for controlling sapstain and mould on unseasoned lumber (laboratory method). ASTM D4445–91. In: Annual Book of ASTM Standards, Vol. 4.10. pp. 497-500. ASTM, West Conshohocken, Pennsylvania. American Wood Protection Association Standards. (2009): Standard method of testing wood preservatives by laboratory soil-block cultures. E10–09. In: Annual Book of AWPA Standards, Birmingham, AL. pp. 379–388. Chang, S, Cheng, S (2002): Antitermitic activity of leaf essential oils and components from Cinnamomum osmophleum. Journal of Agricultural and Food Chemistry, 50(6): 1389–1392. Isman, M B, Machial, C M (2006): Pesticides based on plant essential oils: from traditional practice to commercialization. Chapter 3, In: Advances in phytomedicine 3: naturally occurring bioactive compounds. M. Rai and M.C. Carpinella, Eds. Elsevier, New York, NY. Jirovetz, L, Bubhbauer, G, Stoyanova, A S, Geogiev, E V, Danianova, S T (2003): Composition, quality control, and anitmicrobial activity of the essential oil of long-time stored dill (Anethum graveolens L.) seeds from Bulgaria. Journal of Agricultural and Food Chemistry, 51: 3854–3857.

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Kartal, S N, Hwang, W J, Imamura, Y, Sekine, Y (2006): Effect of essential oil compounds and plant extracts on decay and termite resistance of wood. Holz Roh Werkst, 64(6): 455–461. Klaric, M S, Kosalec, I, Mastelic, K J, Pieckova, E, Pepeljnak, S (2006): Antifungal activity of thyme (Thymus vulgaris L.) essential oil and thymol against moulds from damp dwellings. Letters in Applied Microbiology, 44: 36–42. Mater, D K, Karchesy, J J, Kelsey, R G (2006): The sporicidal activity of yellow-cedar heartwood, essential oil and wood constituents towards Phytophthora ramorum in culture. Forest Pathology, 36(5): 297–308. Park, I K, Shin, S C (2005): Fumigant activity of plant essential oils and components from garlic (Allium sativum) and clove bud (Eugenia caryophyllata) oils against the Japanese termite (Reticulitermes speratus Kolbe). Journal of Agricultural and Food Chemistry, 53(11): 4388–4392. Raina, A, Bland, J, Doolittle, M, Lax, A, Boopathy, R, Folkins, M (2007): Effect of orange oil extract on Formosan subterranean termite (Isoptera: Rhinotermitidae). Journal of Economic Entomology, 100(3): 880–885. Shujun Li, C, Freitag, Morrell J J (2007): Preventing fungal attack of freshly sawn lumber using cinnamon extracts. International Research Group on Wood Protection, Stockholm, Sweden. IRG/WP/07-30432. Sim, M J, Choi, D R, Ahn, Y J (2006): Vapor phase toxicity of plant essential oils to Cadra cautella (Lepidopera: Pyralidae). Journal of Economic Entomology, 99(2): 593–598. van Zyl, R L, Seatlholo, S T, van Vuuren, S F (2006): The biological activities of 20 nature identical essential oil constituents. Journal of Essential Oil Research, 18: 129–133. Yang, V W, Clausen, C A (2006): Moldicidal properties of essential oils. International Research Group on Wood Protection, Stockholm, Sweden. IRG/WP/06-30404. Yang, V W, Clausen, C A (2007): Antifungal effect of essential oils on southern yellow pine. International Biodeterioration & Biodegradation, 59: 302–306. Yang, V W, Clausen, C A (2008): Inhibitory effect of essential oils on decay fungi and mold growth on wood. Proceedings for American Wood Protection Society, Birmingham, AL. 103: 62–70. Yi, C G, Choi, B R, Park, H M, Park, C G, Yj, A (2006): Fumigant toxicity of plant essential oils to Thrips palmi (Thysanoptera: Thripidae) and Orius strigicollis (Heteroptera: Anthrocoridae). Journal of Economic Entomology, 99(5): 1733–1738. Zhu, B C R, Henderson, G, Yu, Y, Laine, R A (2003): Toxicity and repellency of patchouli oil and patchouli alcohol against Formosan subterranean termites Coptotermes formosanus Shiraki (Isotera: Rhinotermiditidae). Journal of Agricultural and Food Chemistry, 51(16): 4585–4588.

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