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34 U. Kües Peddireddi, S., Velagapudi, R., Hoegger, P.J., Majcherczyk, A., Naumann, A., Olbrich, A., Polle, A. & Kües, U. (2006). Multiple hydrophobin genes in mushrooms. In: Pisabarro, A.G. & Ramírez, L. (Eds.) VI Genetics and cellular biology of Basidiomycetes. Universida Pública de Navarra, Pamplona, Spain, pp. 151-164. Pemmasani, J. K. (2006). Stress responses to wood and wood-derived volatiles usung the yeast Saccharomyces cerevisiae as a model system for biological monitoring. PhD thesis, Georg-August-University Göttingen, Göttingen, Germany (supervisor: U. Kües). Pemmasani, J. K., Holzwart, F., Hoegger, P., Srivilai, P. & Kües, U. (2005). An essential gene for fruiting body initiation in the basidiomycete Coprinopsis cinerea is homologous to bacterial cyclopropane fatty acid synthase genes. Biospektrum, Tagungsband 2005, 155. Polak, E., Aebi, M. & Kües, U. (2001) Morphological variations in oidium formation in the basidiomycete Coprinus cinereus. Mycological Research, 195, 603-610. Porro, D., Sauer, M., Branduardi, O. & Mattanovich, D. (2005). Recombinant protein production in yeasts. Molecular Biotechnology, 31, 245-259. Puhar, E., Lorencez, I., Guerra, L.H. & Fiechter, A. (1982). Limit to cell mass-production in continuous culture of Methylomonas clara. Journal of Fermentation Technology, 60, 321-326. Rensing, C., Kües, U., Stahl, U., Nies, D.H. & Friedrich, B. (1992). Active expression of bacterial mercuric ion reductase in the yeast Saccharomyces cerevisiae. Journal of Bacteriology, 174, 1288-1292. Rühl, M., Kilaru, S., Saathoff, A., Majcherczyk, A., Hoegger, P., Schöpper, C., Müller, C., Zomorrodi, M., Lange, K., Kharazipour, A. & Kües, U. (2005a). Laccases from white-rot fungi in the production of wood composites. Biospektrum, Tagungsband 2005, 155. Rühl, M., Schöpper, C., Kilaru, S., Saathoff, A., Majcherczyk, A., Hoegger, P., Kharazipour, A. & Kües, U. (2005b). Laccases from white-rot fungi in the production of medium density fibre boards. In: Kück, U., Pöggeler, S., Nouwrousian, M. & Hoff, B. (Eds.) 7 th VAAM symposium 2005, Bochum. Program and abstract book.: Molecular biology of fungi. Bochumer Universitätsverlag, Europäischer Universitätsverlag GmbH, Bochum, Germany, p. 51. Rühl, M., Fischer, C., Schöpper, C., Kharazipour, A. & Kües, U. (2006). Lignolytic enzymes in spent substrate of the oyster mushroom Pleurotus ostreatus. Biospektrum, Sonderausgabe 2006, 61. Rühl, M., Kilaru, S., Majcherczyk, A., Hoegger, P.J., Navarro-González, M., Chaisaena, W., Naumann, A., Peddireddi, S., Malik, I. & Kües, U. (2007). Biotechnological research on basidiomycete fungi. In: Kharazipour, A.R., Müller, C. & Schöpper, C. (Eds.) A review of forest, wood products and wood biotechnology of Iran and Germany. Georg-August-University Göttingen, Faculty of Forest Science and Forest Ecology, Institute of Forest Botany, Göttingen, Germany, pp. 58-69. Rüther, B. (2005). NHN macht als Verein weiter. Erfolgreiche Bilanz nach drei Jahren. Holz-Zentralblatt, 131, 1146. Saathoff, A. (2005). Production and characterisation of the recombinant laccase Lcc5 out of C. cinerea and its use in the wood fiber industry. Master thesis, Institute of Forest Botany, Faculty of Forest Science and Forest Ecology, Georg-August-University Göttingen, Göttingen, Germany (supervisors: S. Kilaru & U. Kües). Sánchez Hernández, O. (2007). Characterization and identification of several Coprini isolated from Göttingen University gardens. Bachelor practice report, Institute of Forest Botany, Faculty of Forest Science and Forest Ecology, Georg-August-University Göttingen, Göttingen, Germany (supervisors: M. Navarro-González & U. Kües). Scholtmeijer, K., Janssen, M.I., Gerssen, B., de Vocht, M.L., van Leeuwen, B.M., van Kooten, T.G., Wösten, H.A.B. & Wessels, J.G.H. (2002). Surface modifications created by using engineered hydrophobins. Applied and Environmental Microbiology, 68, 1367-1373. Scholtmeijer, K., Janssen, M.I., van Leeuwen, M.B.M., van Kooten, T.G., Hektor, H. & Wösten, H.A.B. (2004). The use of hydrophobins to functionalize surfaces. Bio-Medical Materials and Engineering, 14, 447-454. Schützendübel, A., Pemmasani, J.K., Kües, U. & Polle, A. (2005): Response of Saccharomyces cerevisiae to wood and wood-product derived volatiles: evaluation of stress-responses by microarray analysis. In: Kück, U., Pöggeler, S., Nouwrousian, M. & Hoff, B. (Eds.) 7 th VAAM symposium 2005, Bochum.
Molecular Wood Biotechnology Program and abstract book: Molecular biology of fungi. Bochumer Universitätsverlag, Europäischer Universitätsverlag GmbH, Bochum, Germany, p. 45. Schwarze, F.W.M.R., Engels, J. & Mattheck, C. (2000). Fungal strategies of wood decay in trees. Springer, Berlin, Germany. Soares, E.V. & Seynaeve, J. (2000). Induction of flocculation by brewer´s yeast strains of Saccharomyces cerevisiae by changing the calcium concentration and pH of culture medium. Biotechnology Letters, 22, 1827-1832. Srivilai, P. (2006). Molecular analysis of genes acting in fruiting body development in basidiomycetes. PhD thesis, Georg-August-University Göttingen, Göttingen, Germany (supervisor: U. Kües). Srivilai, P., Chaisaena, W. & Kües, U. (2006a) Genetic analysis of Coprinopsis cinerea mutants with defects in fruiting body development. In: Pisabarro, A.G. & Ramírez, L. (Eds.) VI Genetics and cellular biology of Basidiomycetes. Universida Pública de Navarra, Pamplona, Spain, pp. 177-190. Srivilai, P., James, T.Y., Vilgalys, R., Chaisaena, W. & Kües U. (2006b). Heterologous expression of mating type genes in basidiomycetes. In: Pisabarro, A.G. & Ramírez, L. (Eds.) VI Genetics and cellular biology of Basidiomycetes. Universida Pública de Navarra, Pamplona, Spain, pp. 139-150. Stahl, U., Kües, U. & Esser, K. (1983). Flocculation in yeast, an assay on the inhibition of cell aggregation. European Journal of Applied Microbiology and Biotechnology, 17, 199-202. Svobodová, K. (2005). The implication of lignolytic enzymes in the decolorization of synthetic dyes by the white rot fungus Irpex lacteus. PhD thesis, Charles University of Prague, Prague, Czechia. Svobodová, K., Podgornik, H., Musilkova, E., Novotný, Č., Majcherczyk, A. & Kües, U. (2003). Ligninolytic enzyme production in cultures of Irpex lacteus and Phanerochaete chrysosporium and their implication in dye decolorization. Acta Facultas Rereum Naturalium Universitatis Ostraviensis, Biologie, 10, 125 - 130. Svobodová, K., Majcherczyk, A., Novotný, Č. & Kües, U. (2008). Implication of mycelium-associated laccase from Irpex lacteus in the decolorization of synthetic dyes. Bioresource Technology, 99, 463-471. Tapingkae, T. (2004). Oyster mushroom growing in Thailand. MushWorld, http://www.mushworld.com/oversea/view.asp?cata_id=5178&vid=6473. Thakeow, P., Chaisaena, W., Kües, U. & Schütz, S. (2006). Investigation of volatile organic compounds emitted by Coprinopsis cinerea. Biospektrum, Sonderausgabe 2006, 66. Velagapudi, R. (2006). Extracellular matrix proteins in growth and fruiting body development of straw and wood degrading Basidiomycetes. PhD thesis, Georg-August-University Göttingen, Göttingen, Germany (supervisor: U. Kües). Velagapudi, R., Peddireddi, S., Hoegger, P.J., Majcherczyk, A., Naumann, A., Olbrich, A., Polle, A. & Kües, U. (2005a) The mushroom Coprinopsis cinerea has multiple class I hydrophobins but no class II hydrophobins. In: Kück, U., Pöggeler, S., Nouwrousian, M. & Hoff, B. (Eds.) 7 th VAAM symposium 2005, Bochum. Program and abstract book: Molecular biology of fungi. Bochumer Universitätsverlag, Europäischer Universitätsverlag GmbH, Bochum, Germany, p. 39. Velagapudi R., Peddireddi S., Hoegger P., Majcherczyk A., Polle A. & Kües U. (2005b). How many hydrophobins does a mushroom need? Fungal Genetics Newsletter, 52 (Supplement), 187. Velagapudi, R., Kilaru, S., Pemmasani, J.K., Kaur, K., Hoegger, P.J., & Kües, U. (2006). Spatial and temporal expression of laccase in Coprinopsis cinerea using galectin promoters. In: Pisabarro, A.G. & Ramírez, L. (Eds.) VI Genetics and cellular biology of Basidiomycetes. Universida Pública de Navarra, Pamplona, Spain, pp. 191-206. Walser, P.J., Hollenstein, M., Klaus, M.J. & Kües, U. (2001). Genetic analysis of basidiomycete fungi. In: Talbot, N.J. (Ed.) Molecular and cell biology of filamentous fungi: a practical approach. Practical Approach Series, IRL Press, Oxford, UK, pp. 59-90. Walser, P.J., Velagapudi, R., Aebi, M. & Kües, U. (2003). Extracellular matrix proteins in mushroom development. Recent Research Developments in Microbiology, 7, 381-415. Walser, P.J., Haebel, P.W., Sargent, D., Künzler, M., Kües, U., Aebi, M. & Ban, N. (2004). Structure and functional analysis of the fungal galectin CGL2. Structure, 12, 689-702. Walser, P.J., Kües, U., Aebi, M. & Künzler, M. (2005). Ligand interactions of the Coprinopsis cinerea galectins. Fungal Genetics and Biology, 42, 293-305. 35
Page 1: 108 r Universitätsverlag Göttinge
Page 4 and 5: erschienen im Universitätsverlag G
Page 6 and 7: Bibliographische Information der De
Page 8 and 9: 2 Contents 4. Dohrenbusch, A. & Bol
Page 11 and 12: Contributors Contributors Michael B
Page 13 and 14: Contributors Prof. Dr. Ursula Kües
Page 15: Contributors Dr. Thomas Teichmann:
Page 19: Part I Part I - Prologue to this Bo
Page 22 and 23: 16 U. Kües A special programme of
Page 24 and 25: 18 U. Kües ground on flocculation
Page 26 and 27: 20 U. Kües research as in the case
Page 28 and 29: 22 U. Kües riments for environment
Page 30 and 31: 24 U. Kües modern logistic and eff
Page 32 and 33: 26 U. Kües Prof. Dr. S. Schütz: F
Page 34 and 35: 28 U. Kües Prof. Dr. B.C. Lu (Univ
Page 36 and 37: 30 U. Kües Eggen, T. & Majcherczyk
Page 38 and 39: 32 U. Kües Kothe, E. (2001). Matin
Page 42 and 43: 36 U. Kües Wasser, S.P. (2002). Me
Page 44 and 45: 38 U. Kües Jenkner, P., Standke, B
Page 46 and 47: 40 U. Kües Rekangalt, D., Verner,
Page 49 and 50: Wood Supply 2. The Wood Supply in t
Page 51 and 52: Wood Supply Sweden Germany France P
Page 53 and 54: Wood Supply Growing stock (m 3 / ha
Page 55 and 56: Wood Supply In Germany, the wood ba
Page 57 and 58: Wood Supply 15 million m 3 and the
Page 59 and 60: Wood Supply Potential (m 3 u.b./ha/
Page 61: Wood Supply FAO (Food and Agricultu
Page 64 and 65: 58 U. Muuss & T. Lam Congo, Côte d
Page 66 and 67: 60 U. Muuss & T. Lam cooking, heati
Page 68 and 69: 62 A B C Volume (‘000,000 m 3 ) V
Page 70 and 71: 64 U. Muuss & T. Lam three regions.
Page 72 and 73: 66 U. Muuss & T. Lam 3,287,000 m 3
Page 74 and 75: 68 U. Muuss & T. Lam regulate illeg
Page 76 and 77: 70 U. Muuss & T. Lam The genus Pinu
Page 78 and 79: 72 U. Muuss & T. Lam from primary t
Page 80 and 81: 74 A. Dohrenbusch & A. Bolte ment,
Page 82 and 83: 76 A. Dohrenbusch & A. Bolte New fo
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Page 86 and 87: 80 A. Dohrenbusch & A. Bolte are, h
Page 88 and 89: 82 A. Dohrenbusch & A. Bolte shrubs
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Carbon Dioxide and the Kyoto-Proces
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Renewable Energy 6. Wood as Renewab
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Renewable Energy Costs for 1 GJ of
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Renewable Energy tion, while “dry
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Renewable Energy Energy yield [GJ/h
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Renewable Energy into mechanical an
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Renewable Energy alumina, and boron
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Renewable Energy Table 3 Inputs per
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Renewable Energy Bridgwater, A.V.,
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Renewable Energy Mohan, D., Pittman
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Transgenic Trees 7. Transgenic Tree
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Transgenic Trees Table 1 Transgenic
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Transgenic Trees (Birch 1997) and a
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Transgenic Trees CoA HO HO HO S O O
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Transgenic Trees this change allows
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Transgenic Trees Fig. 3 Phenotype o
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Transgenic Trees the transgenic pop
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Transgenic Trees by introducing the
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Transgenic Trees herbicide resistan
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Transgenic Trees antioxidant capaci
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Transgenic Trees Peterson, R.K.D. &
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Transgenic Trees Williams, G.M., Kr
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Molecular Genetic Tools for Wood Id
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Molecular Detection of Fungi 9. Mol
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Molecular Detection of Fungi Pleuro
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Molecular Detection of Fungi ticle
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Molecular Detection of Fungi The SS
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Molecular Detection of Fungi costs
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Molecular Detection of Fungi questi
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Molecular Detection of Fungi become
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Molecular Detection of Fungi Litera
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Molecular Detection of Fungi Humber
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Molecular Detection of Fungi Wilkin
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180 A. Naumann et al. al. 2002, Bau
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182 A. Naumann et al. and twisting
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184 Single Channel Detector FPA Det
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186 A. Naumann et al. the absorbanc
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188 A. Naumann et al. tial least sq
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190 A. Naumann et al. ponding false
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192 A. Naumann et al. copy contribu
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194 A. Naumann et al. Fengel, D. &
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196 A. Naumann et al. Peddireddi, S
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198 P. Thakeow et al. tions over mi
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200 P. Thakeow et al. Farag et al.
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202 P. Thakeow et al. Fig. 1 Distri
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204 P. Thakeow et al. aldehyde emis
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206 P. Thakeow et al. Table 2 VOCs
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208 P. Thakeow et al. Table 3 Low m
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210 P. Thakeow et al. fungi are gro
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212 P. Thakeow et al. ly, the relea
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214 P. Thakeow et al. which are lar
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216 P. Thakeow et al. Revsbech 2005
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218 P. Thakeow et al. bombycina) we
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220 P. Thakeow et al. Campbell, J.I
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222 P. Thakeow et al. Hatanaka, A.
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224 P. Thakeow et al. Mithöfer, A.
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226 P. Thakeow et al. Schnürer, J.
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228 P. Thakeow et al. Zhang, Q.-H.
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230 J.K. Pemmasani et al. sensitive
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232 Tab. 1 Examples of bioindicator
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234 J.K. Pemmasani et al. for examp
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236 J.K. Pemmasani et al. (Humulus
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238 J.K. Pemmasani et al. Another f
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240 J.K. Pemmasani et al. quantity
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242 J.K. Pemmasani et al. developed
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244 Substrate Product Transducer Bi
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246 J.K. Pemmasani et al. in usage.
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248 J.K. Pemmasani et al. De Boever
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250 J.K. Pemmasani et al. Hoogenboo
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252 J.K. Pemmasani et al. ses by me
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254 J.K. Pemmasani et al. Seidling,
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Part IV Part IV - Wood Preservative
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260 C. Mai & H. Militz Table 1 Haza
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262 C. Mai & H. Militz Table 2 Cont
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264 C. Mai & H. Militz Table 3 Clas
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266 C. Mai & H. Militz insect resis
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268 C. Mai & H. Militz Carbamates (
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270 C. Mai & H. Militz be developed
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Biological Wood Protection 14. Biol
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Biological Wood Protection producti
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Biological Wood Protection ple the
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Biological Wood Protection Freely s
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Biological Wood Protection (Enkerli
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Biological Wood Protection mutant i
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Biological Wood Protection living w
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Biological Wood Protection Aronson,
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Biological Wood Protection Fang, W.
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Biological Wood Protection Meikle,
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Biological Wood Protection Sun, J.Z
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Part V Part V - Panel Boards and Bi
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298 L. Kloeser et al. Characteristi
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300 L. Kloeser et al. from wood shr
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302 Particle board million m 3 40 3
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304 MDF mililon m³ 12 10 8 6 4 2 0
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306 L. Kloeser et al. Plywood and O
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308 L. Kloeser et al. Table 1 Prope
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310 L. Kloeser et al. In MF resin p
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312 L. Kloeser et al. Not completel
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314 L. Kloeser et al. PMDI is that
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316 L. Kloeser et al. Table 5 Tests
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318 L. Kloeser et al. Fig. 14 Overv
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320 L. Kloeser et al. Fig. 16 MDF p
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322 I J K L L. Kloeser et al. engin
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324 L. Kloeser et al. Fig. 19 Pilot
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326 F G H J I L. Kloeser et al. ano
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328 L. Kloeser et al. et al. 2002),
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330 L. Kloeser et al. emissions fro
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332 L. Kloeser et al. Al Rim, K., L
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334 L. Kloeser et al. Dunky, M. (20
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336 L. Kloeser et al. European stan
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338 L. Kloeser et al. Jenkner, P.,
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340 L. Kloeser et al. Ma, L.F., Pul
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342 L. Kloeser et al. Parham, R.A.
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344 L. Kloeser et al. Speit, G. & S
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346 L. Kloeser et al. Zhang, Y.L.,
Page 354 and 355:
348 C. Müller et al. to twenty and
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350 C. Müller et al. Starch yields
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352 A B C C. Müller et al. Fig. 1
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354 C. Müller et al. 2005). Pectin
Page 362 and 363:
356 C. Müller et al. (EC 3.2.1.4)
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358 C. Müller et al. used for the
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360 C. Müller et al. Soybean prote
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362 C. Müller et al. & Deming 1998
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364 C. Müller et al. reaction cond
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366 C. Müller et al. of convention
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368 C. Müller et al. Acknowledgeme
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370 C. Müller et al. Dix, B. & Rof
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372 C. Müller et al. Grigoriou, A.
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374 C. Müller et al. Kishi, H., Fu
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376 C. Müller et al. Maldas, D. &
Page 384 and 385:
378 C. Müller et al. Rombouts, F.M
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380 C. Müller et al. Wang, S. & Pi
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Wood Degrading Enzymes 17. Enzymes
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Wood Degrading Enzymes al. (1999a),
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Wood Degrading Enzymes Phenolic com
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Wood Degrading Enzymes H or L O HO
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Wood Degrading Enzymes dioxygenase
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Wood Degrading Enzymes glucose unit
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Wood Degrading Enzymes → [4-β-D-
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Wood Degrading Enzymes lanases (EC
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Wood Degrading Enzymes lytic enzyme
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Wood Degrading Enzymes kappa number
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Wood Degrading Enzymes Furthermore,
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Wood Degrading Enzymes genes has be
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Wood Degrading Enzymes rays for hyb
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Wood Degrading Enzymes Doing the sa
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Wood Degrading Enzymes 1,4-β-xylos
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Wood Degrading Enzymes Abelskov, A.
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Wood Degrading Enzymes Camarero, S.
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Wood Degrading Enzymes Eriksson, K.
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Wood Degrading Enzymes Halgasova, N
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Wood Degrading Enzymes Jonsson, L.,
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Wood Degrading Enzymes Larrondo, L.
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Wood Degrading Enzymes Moreira, M.T
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Wood Degrading Enzymes Rast, D.M.,
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Wood Degrading Enzymes Sunna, A. &
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Wood Degrading Enzymes Vianello, F.
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Enzymatically Modified Wood 18. Enz
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Enzymatically Modified Wood (helica
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Enzymatically Modified Wood inner c
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Enzymatically Modified Wood fibre s
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Enzymatically Modified Wood Glue =
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Enzymatically Modified Wood thickne
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Enzymatically Modified Wood D E F p
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Enzymatically Modified Wood guez Co
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Enzymatically Modified Wood al. 200
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Enzymatically Modified Wood Fig. 9
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Enzymatically Modified Wood this bo
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Enzymatically Modified Wood MDF wer
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Enzymatically Modified Wood of boar
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Enzymatically Modified Wood Dorris,
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Enzymatically Modified Wood Hernán
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Enzymatically Modified Wood Lang, C
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Enzymatically Modified Wood Sabouri
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Enzymatically Modified Wood Zavarin
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470 Extraction of enzyme Filtration
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472 A E P D B tray humidified air s
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474 M. Rühl et al. the systems, st
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476 M. Rühl et al. biopulping and
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478 M. Rühl et al. Nieves et al. (
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480 M. Rühl et al. Table 3 Example
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482 M. Rühl et al. are easily adap
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484 M. Rühl et al. et al. 2002, Xu
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486 M. Rühl et al. Nyanhongo et al
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488 M. Rühl et al. amounts by mixt
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490 M. Rühl et al. combinant enzym
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492 M. Rühl et al. The C. cinerea
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494 M. Rühl et al. Azin, M., Morav
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496 M. Rühl et al. Diáz-Godínez,
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498 M. Rühl et al. Hong, F., Meina
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500 M. Rühl et al. Leonowicz, A.,
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502 M. Rühl et al. Palmieri, G., G
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504 M. Rühl et al. Saraswat, V. &
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506 M. Rühl et al. Vasconcelos, A.
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Wood Composite and Wood Recycling 2
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Wood Composite and Wood Recycling t
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Wood Composite and Wood Recycling 1
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Wood Composite and Wood Recycling F
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Wood Composite and Wood Recycling R
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Wood Composite and Wood Recycling w
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Wood Composite and Wood Recycling C
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Wood Composite and Wood Recycling t
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Wood Composite and Wood Recycling T
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Wood Composite and Wood Recycling M
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Wood Composite and Wood Recycling S
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Fodder for Ruminants 21. Conversion
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Fodder for Ruminants CH2OH O OH H O
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Fodder for Ruminants macrofibril mi
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Fodder for Ruminants Fig. 7 Raster
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Fodder for Ruminants judge the impr
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Fodder for Ruminants straw pump fre
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Fodder for Ruminants Fig. 10 Rahman
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Fodder for Ruminants Akin, D.E. (20
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Fodder for Ruminants Kakkar, V.K. &
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Mushrooms 22. Mushroom Production M
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Mushrooms Table 1 Estimated worldwi
Page 565 and 566:
Mushrooms see Braaksma & Schaap 199
Page 567 and 568:
Mushrooms outbreeding (sexual repro
Page 569 and 570:
Mushrooms performed by four success
Page 571 and 572:
Mushrooms nic matter into nutrients
Page 573 and 574:
Mushrooms Fig. 5 A former army bunk
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Mushrooms Table 4 Efficiencies in m
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Mushrooms Table 5 Cultivation condi
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Mushrooms further serve as animal f
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Mushrooms mordia formation and prev
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Mushrooms Fig. 10 Fruiting bodies o
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Mushrooms Blanchette, R.A. (1997).
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Mushrooms Hall, I.R., Yun, W. & Ami
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Mushrooms Nwanze, P.I., Khna, A.U.,
Page 591 and 592:
Mushrooms Stoop, J.M.H. & Mooibroek
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Mushroom Biology and Genetics 23. M
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Mushroom Biology and Genetics easy
Page 597 and 598:
Mushroom Biology and Genetics Fig.
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Mushroom Biology and Genetics A B C
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Mushroom Biology and Genetics Other
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Mushroom Biology and Genetics studi
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Mushroom Biology and Genetics study
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Mushroom Biology and Genetics Chiu,
Page 609 and 610:
Mushroom Biology and Genetics Kües
Page 611 and 612:
Mushroom Biology and Genetics Pardo
Page 613:
Mushroom Biology and Genetics Velag
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610 A. Kharazipour et al. Peat howe
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612 A. Kharazipour et al. were muni
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614 A. Kharazipour et al. grade of
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616 A. Kharazipour et al. Fig. 1 Gl
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618 A. Kharazipour et al. Fig. 2 Vi
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620 A. Kharazipour et al. Table 1 S
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622 A. Kharazipour et al. Pot plant
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624 A B A. Kharazipour et al. Fig.
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626 A B C D A. Kharazipour et al. F
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628 Literature A. Kharazipour et al
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630 A. Kharazipour et al. Delatour,
Page 638 and 639:
632 A. Kharazipour et al. Kullmann,
Page 640 and 641:
634 A. Kharazipour et al. Rieger, S
Page 643:
Projects presented in this book wer
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In the year 2001, Prof. Dr. Ursula
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