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Developing fungal pigments for “painting” vascular plants

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Abstract

The use of fungal pigments as color additives to wood as a method to increase forest revenue is a relatively new, but quickly developing field. Sugar maple (Acer saccharum) is currently the primary utilized hardwood for spalting and appears to be the best suited North American hardwood for such purposes. The combination of Trametes versicolor and Bjerkandera adusta has been identified in several instances as a strong fungal pairing for zone line production; however, Xylaria polymorpha is capable of creating zone lines without the antagonism of a secondary fungus. Few fungal pigments have been developed for reliable use; Scytalidium cuboideum is capable of producing a penetrating pink/red stain, as well as a blue pigment after extended incubation, and Chlorociboria sp. produces a blue/green pigment if grown on aspen (Populus tremuloides). Several opportunities exist for stimulation of fungal pigments including the use of copper sulfate and changes in wood pH.

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References

  • Blanchette RA, Wilmering AM, Baumeister M (1992) The use of green-stained wood caused by the fungus Chlorociboria in Intarsia masterpieces from the 15th century. Holzforsch 46(3):225–232

    Article  CAS  Google Scholar 

  • Boddy L, Rayner ADM (1981) Fungal communities and formation of heartwood winds in attached oak branches undergoing decay. Ann Bot 47:271–274

    Google Scholar 

  • Campbell AH (1933) Zone lines in plant tissues.1. The black lines formed by Xylaria polymorpha (Pers.) Grev. in hardwoods. An Appl Biol 20:123–145

    Article  Google Scholar 

  • Campbell AH (1934) Zone lines in plant tissues II. The black lines formed by Armillaria mellea. An Appl Biol 21(1):1–22

    Article  Google Scholar 

  • Christensen KW (1982) Improving the working properties of spalted woods through impregnation with methyl methacrylate. Thesis: Master of Science, Brigham Young University

  • Coates D (1984) The biological consequences of somatic incompatibility in wood decaying basidiomycetes and other fungi. Thesis: Ph.D., University of Bath

  • Coates D, Rayner ADM (1985a) Fungal population and community development in cut beech logs. I. Establishment via the aerial cut surface. N Phytologist 101:153–171

    Article  Google Scholar 

  • Coates D, Rayner ADM (1985b) Fungal population and community development in cut beech logs. II. Establishment from the buried cut surface. N Phytologist 101:173–181

    Article  Google Scholar 

  • Coates D, Rayner ADM (1985c) Fungal population and community development in cut beech logs. III. Spatial dynamics, interaction and strategies. N Phytologist 101:183–198

    Article  Google Scholar 

  • Donovan G, Nicholls D (2003) Consumer preference and willingness to pay for character-marked cabinets from Alaska birch. Forest Prod J 53(11/12):27–32

    Google Scholar 

  • Hartig R (1878) Die Zersetzungserscheinungen des Holzes der Nadelholzbaeume und der Eiche. Berlin

  • Li CY (1981) Phenoloxidase and peroxidase activities in zone lines of Phellinus weirii. Mycol Soc of Am 1:811–821

    Article  Google Scholar 

  • Lindquist M (1977) Spalted wood. Rare jewels from death and decay. Fine Woodworking 7:50–53

    Google Scholar 

  • Lopez-Real JM, Swift MJ (1975) The formation of pseudosclerotia (‘zone lines’) in wood decayed by Armillaria mellea and Stereum hirsutum. II. Formation in relation to the moisture content of the wood. Trans Br Mycol Soc 64(3):479–481

    Google Scholar 

  • Lopez-Real JM, Swift MJ (1977) Formation of pseduosclerotia (‘zone lines’) in wood decayed by Armillaria mellea and Stereum hirsutum. III. Formation in relation to the gaseous atmosphere in wood. Trans Br Mycol Soc 66:321–325

    Article  Google Scholar 

  • Maeda M, Yamauchi T, Oshima K, Shimomura M, Miyauchi S, Mukae K, Sakaki T, Shibata M, Wakamatsu K (2003) Extraction of xylindein from Chlorociboria aeruginosa complex and its biological characteristics. Bull Nagaoka Univ of Technol 25:105–111

    Google Scholar 

  • Mallett KI, Hiratsuka Y (1986) Nature of the “black line” produced between different biological species of the Armillaria mellea complex. Can J Bot 64:2588–2590

    Article  Google Scholar 

  • Phillips LW (1987) The nature of spalted wood: analysis of zone line formation between six white rot fungi. Thesis: Master of Science, Brigham Young University

  • Qin L, Guo M, Qiu J, Liu C (2011) Study on the formation of wood zone line pattern induced by fungi. Adv Mater Res 197–198:190–193. doi:10.4028/www.scientific.net/AMR.197-198.190

    Article  Google Scholar 

  • Rayner ADM, Todd NK (1977) Intraspecific antagonism in natural populations of wood-decaying basidiomycetes. J Gen Microbiol 103:85–90

    Google Scholar 

  • Rayner ADM, Todd NK (1979) Population and community structure and dynamics of fungi in decaying wood. Adv in Bot Res 7:333–420

    Article  Google Scholar 

  • Rayner ADM, Webber JF (1983) Interspecific mycelial interactions—an overview. In: Jennings DH, Rayner ADM (eds) The ecology and physiology of the fungal mycelium, British Mycological Society Symposia no 8:383-417

  • Robinson SC (2008) DIY spalting. Fine Woodworking 199:30–32

    Google Scholar 

  • Robinson SC (2010) Spalted wood. Am Woodturner J 25(6):22–28

    Google Scholar 

  • Robinson SC (2011) Destroying uniformity: using fungi to add a tactile and visual experience to functional wood. Leonardo J 44(2):145–151

    Google Scholar 

  • Robinson SC, Laks PE (2010a) Culture age and wood species affect zone line production of Xylaria polymorpha. The Open Mycol J 4:18–21

    Article  Google Scholar 

  • Robinson SC, Laks PE (2010b) Wood species affects colonization rates of Chlorociboria sp. Int Biodeterior and Biodegrad 64:305–308

    Article  Google Scholar 

  • Robinson SC, Laks PE (2011) The effects of copper in large scale mono- and dual-fungus wood systems. Forest Prod J 60(6):490–495

    Google Scholar 

  • Robinson SC, Richter DL, Laks PE (2007a) Colonization of sugar maple by spalting fungi. Forest Prod J 57(4):24–32

    Google Scholar 

  • Robinson SC, Laks PE, Richter DL, Pickens JB (2007b) Evaluating loss of machinability in spalted sugar maple. Forest Prod J 57(4):33–37

    Google Scholar 

  • Robinson SC, Laks PE, Turnquist EJ (2009a) A method for digital color analysis of spalted wood using Scion Image software. Materials 2(1):62–75

    Article  Google Scholar 

  • Robinson SC, Richter DL, Laks PE (2009b) Effects of substrate on laboratory spalting of sugar maple. Holzforsch 63:491–495

    Article  CAS  Google Scholar 

  • Robinson SC, Laks PE, Richter DL (2011a) Stimulating spalting in sugar maple using sub-lethal doses of copper. Eur J Wood and Wood Prod 69(4):527–532

    Article  CAS  Google Scholar 

  • Robinson SC, Tudor D, Cooper PA (2011b) Promoting fungal pigment formation in wood by utilizing a modified decay jar method. Wood Sci Technol. doi:10.1007/s00226-011-0453-8

  • Robinson SC, Tudor D, Cooper PA (2011c) Feasibility of using red pigment producing fungi to stain wood for decorative applications. Canadian J For Res 41:1722–1728

    Article  Google Scholar 

  • Robinson SC, Tudor D, Cooper PA (2011d) Wood preference by spalting fungi in urban hardwood species. Int Biodeterior and Biodegrad 65:1145–1149

    Article  Google Scholar 

  • Robinson SC, Tudor D, Cooper PA (2011e) Utilizing pigment-producing fungi to add commercial value to American beech (Fagus grandifolia). Appl Microbiol Biotechnol. doi:10.1007/s00253-011-3576-9

  • Sharland PR, Rayner ADM (1986) Mycelial interactions in Daldinia concentrica. Trans Brit Mycol Soc 86(4):643–649

    Article  Google Scholar 

  • Soto JMS, Jolles HI, Garland JL (2011) Hypersensitivity pneumonitis secondary to wood spalting. Am J Respir Crit Care Med 183:A4524

    Google Scholar 

  • Tudor D, Robinson SC, Cooper PA (2011) The influence of moisture content and wood pH variation on fungal melanin formation in wood substrates. Int Res Group on Wood Protection IRG/WP 11-10759

  • Tudor D, Robinson SC, Cooper PA (2011) Effects of catechol treatment on fungal melanin stimulation for spalting. Canadian Wood Preservation Association CWPA 32

  • Weir JR (1915) Some observations on abortive sporophores of wood-destroying fungi. Phytopathol 5:48–50

    Google Scholar 

  • White JH (1920) On the biology of Fomes applanatus (Pers.) Wallr Trans Roy Canad Inst XII, 133

  • Worrall JT, Anagnost SE, Zabel RA (1997) Comparison of wood decay among diverse lignicolous fungi. Mycologia 89(2):199–219

    Article  Google Scholar 

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  1. Faculty of Forestry, University of Toronto, 33 Willcocks St., Toronto, ON, M5S 3B3, Canada

    Sara C. Robinson

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  1. Sara C. Robinson
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Correspondence to Sara C. Robinson.

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Robinson, S.C. Developing fungal pigments for “painting” vascular plants. Appl Microbiol Biotechnol 93, 1389–1394 (2012). https://doi.org/10.1007/s00253-011-3858-2

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  • DOI: https://doi.org/10.1007/s00253-011-3858-2

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