Growth, Differentiation and Sexuality

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388 M. Feldbrügge et al. Bernards A, Settleman J (2004) GAP control: regulating the regulators of small GTPases. Trends Cell Biol 14:377– 385 Bohlmann R (1996) Isolierung und Charakterisierung von filamentspezifisch exprimierten Genen aus Ustilago maydis. PhD Thesis, Fakultät für Biologie, Ludwig- Maximilians-Universität München, Germany Bohlmann R, Schauwecker F, Basse C, Kahmann R (1994) Genetic regulation of mating and dimorphism in Ustilago maydis. In: Daniels MJ (ed) Advances in Molecular Genetics of Plant-Microbe Interactions, vol 3. Kluwer, Dordrecht, pp 239–245 Bölker M (2001) Ustilago maydis – a valuable model system for the study of fungal dimorphism and virulence. Microbiology 147:1395–1401 Bölker M, Urban M, Kahmann R (1992) The a mating type locus of U. maydis specifies cell signaling components. Cell 68:441–450 Bölker M, Genin S, Lehmler C, Kahmann R (1995) Genetic regulation of mating, and dimorphism in Ustilago maydis. Can J Bot 73:320–325 Bortfeld M, Auffarth K, Kahmann R, Basse CW (2004) The Ustilago maydis a2 mating-type locus genes lga2 and rga2 compromise pathogenicity in the absence of the mitochondrial p32 family protein Mrb1. Plant Cell 16:2233–2248 Bourne HR, Sanders DA, McCormick F (1990) The GTPase superfamily: a conserved switch for diverse cell functions. Nature 348:125–132 Brachmann A, Weinzierl G, Kämper J, Kahmann R (2001) Identification of genes in the bW/bE regulatory cascade in Ustilago maydis. Mol Microbiol 42:1047–1063 Brachmann A, Schirawski J, Müller P, Kahmann R (2003) An unusual MAP kinase is required for efficient penetration of the plant surface by Ustilago maydis. EMBO J 22:2199–2210 Brachmann A, König J, Julius C, Feldbrügge M (2004) A reverse genetic approach for generating gene replacement mutants in Ustilago maydis. MolGenGenomics 272:216–226 Brefort T, Müller P, Kahmann R (2005) The high-mobilitygroup domain transcription factor Rop1 is a direct regulator of prf1 in Ustilago maydis. Eukaryot Cell 4:379– 391 Burbelo PD, Drechsel D, Hall A (1995) A conserved binding motif defines numerous candidate target proteins for both Cdc42 and Rac GTPases. J Biol Chem 270:29071– 29074 Castillo-Lluva S, Garcia-Muse T, Pérez-Martín J (2004) A member of the Fizzy-related family of APC activators is regulated by cAMP and is required at different stages of plant infection by Ustilago maydis. JCellSci 117:4143–4156 Cherfils J, Chardin P (1999) GEFs: structural basis for their activation of small GTP-binding proteins. Trends Biochem Sci 24:306–311 Davey J (1998) Fusion of a fission yeast. Yeast 14:1529–1566 Dürrenberger F, Wong K, Kronstad JW (1998) Identification of a cAMP-dependent protein kinase catalytic subunit required for virulence and morphogenesis in Ustilago maydis. Proc Natl Acad Sci USA 95:5684–5689 Dürrenberger F, Laidlaw RD, Kronstad JW (2001) The hgl1 gene is required for dimorphism and teliospore formation in the fungal pathogen Ustilago maydis. Mol Microbiol 41:337–348 Elion EA (2000) Pheromone response, mating and cell biology. Curr Opin Microbiol 3:573–581 Farfsing JW, Auffarth K, Basse CW (2005) Identification of cis-active elements in Ustilago maydis mig2 promoters conferring high-level activity during pathogenic growth in maize. Mol Plant Microbe Interact 18:75–87 Feldbrügge M, Kämper J, Steinberg G, Kahmann R (2004) Regulation of mating and pathogenic development in Ustilago maydis. Curr Opin Microbiol 7:666–672 Froeliger EH, Leong SA (1991) The a mating-type alleles of Ustilago maydis are idiomorphs. Gene 100:113–122 Fuchs U, Manns I, Steinberg G (2005) The cytoskeleton has essential roles in dimorphic transition in the plant pathogen Ustilago maydis. Mol Biol Cell 16:2746–2758 Garcerá-Teruel A, Xoconostle-Cázares B, Rosas-Quijano R, Ortiz L, León-Ramírez C, Specht CA, Sentandreu R, Ruiz-Herrera J (2004) Loss of virulence in Ustilago maydis by Umchs6 gene disruption. Res Microbiol 155:87–97 Garcia-Muse T, Steinberg G, Pérez-Martín J (2003) Pheromone-induced G2 arrest in the phytopathogenic fungus Ustilago maydis. Eukaryot Cell 2:494–500 Garcia-Pedrajas MD, Klostermann SJ, Andrews DL, Gold SE (2004) The Ustilago maydis–maize interaction. In: Talbot NJ (ed) Plant-Pathogen Interactions, vol 11. CRC Press, London, pp 166–201 Garrido E, Pérez-Martín J (2003) The crk1 gene encodes an Ime2-related protein that is required for morphogenesis in the plant pathogen Ustilago maydis. Mol Microbiol 47:729–743 Garrido E, Voß U, Müller P, Kahmann R, Pérez-Martín J (2004) The induction of sexual development and virulence in the smut fungus Ustilago maydis on Crk1, a novel MAPK protein. Genes Dev 18:3117–3130 Geitmann A, Emons AM (2000) The cytoskeleton in plant and fungal cell tip growth. J Microsc 198:218–245 Gillissen B, Bergemann J, Sandmann C, Schroeer B, Bölker M, Kahmann R (1992) A two-component regulatory system for self/non-self recognition in Ustilago maydis. Cell 68:647–657 Gold SE, Duncan G, Barrett K, Kronstad J (1994) cAMP regulates morphogenesis in the fungal pathogen Ustilago maydis. Genes Dev 8:2805–2816 Gold SE, Brogdon SM, Mayorga ME, Kronstad JW (1997) The Ustilago maydis regulatory subunit of a cAMPdependent protein kinase is required for gall formation in maize. Plant Cell 9:1585–1594 Gow NAR (1995) Tip growth and polarity. In: Gow NAR, Gadd GM (eds) The growing fungus. Chapman and Hall, London, pp 99–134 Grimshaw SJ, Mott HR, Stott KM, Nielsen PR, Evetts KA, Hopkins LJ, Nietlispach D, Owen D (2004) Structure of the sterile alpha motif (SAM) domain of the Saccharomyces cerevisiae mitogen-activated protein kinase pathway-modulating protein STE50 and analysis of its interaction with the STE11 SAM. J Biol Chem279:2192– 2201 Harold FM (1990) To shape a cell: an inquiry into the causes of morphogenesis of microorganisms. Microbiol Rev 54:381–431 Hartmann HA, Kahmann R, Bölker M (1996) The pheromone response factor coordinates filamentous
growth and pathogenicity in Ustilago maydis.EMBOJ 15:1632–1641 Hartmann HA, Krüger J, Lottspeich F, Kahmann R (1999) Environmental signals controlling sexual development of the corn smut fungus Ustilago maydis through the transcriptional regulator Prf1. Plant Cell 11:1293–1306 Heath IB (1995) The cytoskeleton. In: Gow NAR, Gadd GM (eds) The growing fungus. Chapman and Hall, London, pp 99–134 Horio T, Oakley BR (2005) The role of microtubules in rapid hyphaltipgrowthofAspergillus nidulans. Mol Biol Cell 16:918–926 Huber SM, Lottspeich F, Kämper J (2002) A gene that encodes a product with similarity to dioxygenases is highly expressed in teliospores of Ustilago maydis.Mol Gen Genomics 267:757–771 Huckaba TM, Gay AC, Pantalena LF, Yang HC, Pon LA (2004) Live cell imaging of the assembly, disassembly, and actin cable-dependent movement of endosomes and actin patches in the budding yeast, Saccharomyces cerevisiae. J Cell Biol 167:519–530 Huffaker TC, Thomas JH, Botstein D (1988) Diverse effects of beta-tubulin mutations on microtubule formation and function. J Cell Biol 106:1997–2010 Johnston GC, Prendergast JA, Singer RA (1991) The Saccharomyces cerevisiae MYO2 gene encodes an essential myosin for vectorial transport of vesicles. J Cell Biol 113:539–551 Kaffarnik F, Müller P, Leibundgut M, Kahmann R, Feldbrügge M (2003) PKA and MAPK phosphorylation of Prf1 allows promoter discrimination in Ustilago maydis. EMBO J 22:5817–5826 Kahmann R, Kämper J (2004) Ustilago maydis: howitsbiology relates to pathogenic development. New Phytol 164:31–42 Kahmann R, Basse C, Feldbrügge M (1999) Fungal-plant signalling in the Ustilago maydis-maize pathosystem. Curr Opin Microbiol 2:647–650 Kaksonen M, Sun Y, Drubin DG (2003) A pathway for association of receptors, adaptors, and actin during endocytic internalization. Cell 115:475–487 Kämper J (2004) A PCR-based system for highly efficient generation of gene replacement mutants in Ustilago maydis. Mol Gen Genomics 271:103–110 Kämper J, Reichmann M, Romeis T, Bölker M, Kahmann R (1995) Multiallelic recognition: nonself-dependent dimerization of the bE and bW homeodomain proteins in Ustilago maydis. Cell 81:73–83 Klose J, de Sa MM, Kronstad JW (2004) Lipid-induced filamentous growth in Ustilago maydis. MolMicrobiol 52:823–835 Kronstad JW, Leong SA (1990) The b mating-type locus of Ustilago maydis contains variable and constant regions. Genes Dev 4:1384–1395 Krüger J, Loubradou G, Regenfelder E, Hartmann A, Kahmann R (1998) Crosstalk between cAMP and pheromone signalling pathways in Ustilago maydis. Mol Gen Genet 260:193–198 Krüger J, Loubradou G, Wanner G, Regenfelder E, Feldbrügge M, Kahmann R (2000) Activation of the cAMP pathway in Ustilago maydis reduces fungal proliferation and teliospore formation in plant tumors. Mol Plant Microbe Interact 13:1034–1040 Regulatory and Structural Networks in Ustilago maydis 389 Kübler E, Riezman H (1993) Actin and fimbrin are required for the internalization step of endocytosis in yeast. EMBO J 12:2855–2862 Lee N, Kronstad JW (2002) ras2 controls morphogenesis, pheromone response, and pathogenicity in the fungal pathogen Ustilago maydis. Eukaryot Cell 1:954– 966 Lee N, D’Souza C, Kronstad JW (2003) Of smuts, blasts, mildews, and blights: cAMP signalling in phytophatogenic fungi. Annu Rev Phytopathol 41:399–427 Lehmler C, Steinberg G, Snetselaar KM, Schliwa M, Kahmann R, Bölker M (1997) Identification of a motor protein required for filamentous growth in Ustilago maydis. EMBO J 16:3464–3473 Leveleki L, Mahlert M, Sandrock B, Bölker M (2004) The PAK family kinase Cla4 is required for budding and morphogenesis in Ustilago maydis. Mol Microbiol 54:396–406 Loubradou G, Brachmann A, Feldbrügge M, Kahmann R (2001) A homolog of the transcriptional repressor Ssn6p antagonizes cAMP signalling in Ustilago maydis. Mol Microbiol 40:719–730 MahlertM,LevelekiL,HlubekA,SandrockB,BölkerM (2005) Rac1 and Cdc42 regulate hyphal growth and cytokinesis in the dimorphic fungus Ustilago maydis. Mol Microbiol (in press) Martinez-Espinoza AD, Ruiz-Herrera J, Leon-Ramirez CG, Gold SE (2004) MAP kinase and cAMP signaling pathways modulate the pH-induced yeast-to-mycelium dimorphic transition in the corn smut fungus Ustilago maydis. Curr Microbiol 49:274–281 Mayorga ME, Gold SE (1999) A MAP kinase encoded by the ubc3 gene of Ustilago maydis is required for filamentous growth and full virulence. Mol Microbiol 34:485–497 Mayorga ME, Gold SE (2001) The ubc2 gene of Ustilago maydis encodes a putative novel adaptor protein required for filamentous growth, pheromone response and virulence. Mol Microbiol 41:1365–1379 Müller P, Aichinger C, Feldbrügge M, Kahmann R (1999) The MAP kinase Kpp2 regulates mating and pathogenic development in Ustilago maydis. Mol Microbiol 34:1007–1017 Müller P, Katzenberger JD, Loubradou G, Kahmann R (2003a) Guanyl nucleotide exchange factor Sql2 and Ras2 regulate filamentous growth in Ustilago maydis. Eukaryot Cell 2:609–617 Müller P, Weinzierl G, Brachmann A, Feldbrügge M, Kahmann R (2003b) Mating and pathogenic development ofthe smutfungus Ustilago maydis are regulatedbyone mitogen-activated protein kinase cascade. Eukaryot Cell 2:1187–1199 Müller P, Leibbrandt A, Teunissen H, Cubasch S, Aichinger C, Kahmann R (2004) The Gß-subunit-encoding gene bpp1 controls cyclic-AMP signaling in Ustilago maydis. Eukaryot Cell 3:806–814 Nugent KG, Choffe K, Saville BJ (2004) Gene expression during Ustilago maydis diploid filamentous growth: EST library creation and analyses. Fungal Genet Biol 41:349–360 Oakley BR, Akkari YN (1999) Gamma-tubulin at ten: progress and prospects. Cell Struct Funct 24:365–372
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The Mycota Edited by K. Esser
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The Mycota A Comprehensive Treatise
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Karl Esser (born 1924) is retired P
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VIII Series Preface Class: Saccharo
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Addendum to the Series Preface In e
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XIV Volume Preface to the First Edi
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XVI Volume Preface to the Second Ed
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XVIII Contents Reproductive Process
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XX List of Contributors André Flei
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Vegetative Processes and Growth
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4 K.J. Boyce and A. Andrianopoulos
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22 L.J. García-Rodríguez et al. I
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24 L.J. García-Rodríguez et al. F
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26 L.J. García-Rodríguez et al. 2
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28 L.J. García-Rodríguez et al. M
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30 L.J. García-Rodríguez et al. a
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32 L.J. García-Rodríguez et al. t
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34 L.J. García-Rodríguez et al. H
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36 L.J. García-Rodríguez et al. T
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38 S.D. Harris dle organization tha
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40 S.D. Harris 2001; Borkovich et a
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42 S.D. Harris terized in A. nidula
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44 S.D. Harris astral microtubules
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46 S.D. Harris entry, and the CDK N
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48 S.D. Harris and Hamer 1997), the
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50 S.D. Harris Murray AW (2004) Rec
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4 Apical Wall Biogenesis J.H. Siets
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fungi can be regarded as “tube-dw
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In agreement with an essential role
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Kopecka and Gabriel 1992). They als
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nearly all the label was present in
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ingredients such as wall components
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in membrane enlargement and exocyto
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sis occurs, coinciding with a gradi
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pling of two (1-3)-alpha-glucan seg
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Sietsma JH, Wessels JGH (1977) Chem
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5 The Fungal Cell Wall J.P. Latgé
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polymers (chitosan) and glucuronic
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Whereas the structural branched β1
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their structural role in the cell w
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eight chitin synthases of A. fumiga
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Characterization of the chs4 mutant
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Fig. 5.8. Experimental data and hyp
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Fig. 5.9. Elongation of the mannan
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end of linear β1,3 glucans, and tr
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Fig. 5.12. Signal transduction in f
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shock,lowosmolarityaswellasotherfac
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ditions. Accordingly, enzymes and r
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Calonge TM, Arellano M, Coll PM, Pe
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Hiura N, Nakajima T, Matsuda K (198
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Martin-Yken H, Dagkessamanskaia A,
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Saporito-Irwin SM, Birse CE, Sypher
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6 Septation and Cytokinesis in Fung
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Septation in Fungi 107 Table. 6.1.
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Fig. 6.1. Selection of a cell divis
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Calderone, Chap. 5, this volume, an
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permissive temperature, multiple se
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eports suggested such a function fo
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understood mechanism of mitotic exi
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Implication in cytokinesis in Sacch
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Trinci APJ, Morris NR (1979) Morpho
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124 N.L. Glass and A. Fleissner ter
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126 N.L. Glass and A. Fleissner 188
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128 N.L. Glass and A. Fleissner Fig
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130 N.L. Glass and A. Fleissner sub
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132 N.L. Glass and A. Fleissner dur
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134 N.L. Glass and A. Fleissner G1
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136 N.L. Glass and A. Fleissner Bri
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138 N.L. Glass and A. Fleissner Mat
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8 Heterogenic Incompatibility in Fu
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Fungal Heterogenic Incompatibility
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B. Genetic Control The genetic back
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active phenotype het-s. The neutral
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Table. 8.1. (continued) Fungal Hete
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is a complex genetic trait controll
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indicate how speciation may be init
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ility controlled by multiple allele
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dependonthematingtypegenes,wasobser
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6. Relation with Histo-Incompatibil
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Semi-Incompatibilität. Z Indukt Ab
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Micali CO, Smith ML (2003) On the i
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Vilgalys RJ, Miller OK (1987) Matin
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168 B.C.K. Lu (Esser et al. 1980; K
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170 B.C.K. Lu enterthePCDpathway,wi
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172 B.C.K. Lu et al. 2004). It is l
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174 B.C.K. Lu (MMP), through ruptur
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176 B.C.K. Lu Fig. 9.1. Effects of
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178 B.C.K. Lu drial fission during
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180 B.C.K. Lu Although the cytologi
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182 B.C.K. Lu be arrested at diffus
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184 B.C.K. Lu Harris MH, Thompson C
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186 B.C.K. Lu oxygen species, in Kl
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10 Senescence and Longevity H.D. Os
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the amplification of plDNA is not a
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GRISEA is an orthologue of the yeas
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Fig. 10.3. Copper delivery to the c
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have been identified, for example,
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Kück U, Stahl U, Esser K (1981) Pl
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Signals in Growth and Development
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204 U. Ugalde II. Germination The p
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206 U. Ugalde Fig. 11.2.A-C Drawing
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208 U. Ugalde duction (Schimmel et
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210 U. Ugalde position, possibly in
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212 U. Ugalde Champe SP, Rao P, Cha
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12 Pheromone Action in the Fungal G
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sibly due to displacement of the hy
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all these compounds, the B-derivate
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shows the same activity in M. muced
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C. Oomycota In the non-mycotan phyl
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following sequence of events has be
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the standard Mendelian segregation
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Elliott CG, Knights BA (1981) Uptak
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constitutively transcribed but its
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234 L.M. Corrochano and P. Galland
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Reproductive Processes
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264 R. Fischer and U. Kües 2. Chla
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266 R. Fischer and U. Kües resourc
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268 R. Fischer and U. Kües ular le
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270 R. Fischer and U. Kües pathway
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272 R. Fischer and U. Kües and con
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274 R. Fischer and U. Kües Timberl
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276 R. Fischer and U. Kües PsiB le
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278 R. Fischer and U. Kües Table.
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280 R. Fischer and U. Kües tein ki
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282 R. Fischer and U. Kües nitroge
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284 R. Fischer and U. Kües tion, t
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286 R. Fischer and U. Kües Busch S
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288 R. Fischer and U. Kües Jeffs L
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290 R. Fischer and U. Kües Pöggel
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292 R. Fischer and U. Kües Yamashi
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294 R. Debuchy and B.G. Turgeon tha
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296 R. Debuchy and B.G. Turgeon loc
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298 R. Debuchy and B.G. Turgeon Tab
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300 R. Debuchy and B.G. Turgeon Fig
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302 R. Debuchy and B.G. Turgeon mai
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304 R. Debuchy and B.G. Turgeon mol
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306 R. Debuchy and B.G. Turgeon gen
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308 R. Debuchy and B.G. Turgeon int
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310 R. Debuchy and B.G. Turgeon Fig
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312 R. Debuchy and B.G. Turgeon pro
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314 R. Debuchy and B.G. Turgeon B.
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316 R. Debuchy and B.G. Turgeon 2.
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318 R. Debuchy and B.G. Turgeon in
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320 R. Debuchy and B.G. Turgeon be
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322 R. Debuchy and B.G. Turgeon Lee
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16 Fruiting-Body Development in Asc
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phae originating from the base of a
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Table. 16.1. (continued) Fruiting B
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(Raju 1992). When male-sterile muta
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1. nsd (never in sexual development
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egular intervals; both effects requ
Page 344 and 345: the balance between sexual and asex
Page 346 and 347: ductionofeitherpheromoneisdirectlyc
Page 348 and 349: (Catlett et al. 2003). Eleven genes
Page 350 and 351: negative mutation of KREV-1 resulte
Page 352 and 353: through MAP kinase modules to cell-
Page 354 and 355: The fact that fruiting-body formati
Page 356 and 357: Balestrini R, Mainieri D, Soragni E
Page 358 and 359: point mutation of the beta subunit
Page 360 and 361: Mitchell TK, Dean RA (1995) The cAM
Page 362 and 363: YamashiroCT,EbboleDJ,LeeBU,BrownRE,
Page 364 and 365: 358 L.A. Casselton and M.P. Challen
Page 382 and 383: 376 M. Feldbrügge et al. different
Page 384 and 385: 378 M. Feldbrügge et al. Fig. 18.3
Page 386 and 387: 380 M. Feldbrügge et al. et al. 20
Page 388 and 389: 382 M. Feldbrügge et al. for unbia
Page 390 and 391: 384 M. Feldbrügge et al. In U. may
Page 392 and 393: 386 M. Feldbrügge et al. Neurospor
Page 396 and 397: 390 M. Feldbrügge et al. O’Donne
Page 398 and 399: 19 The Emergence of Fruiting Bodies
Page 400 and 401: 2003; Kües et al. 2004) are the fi
Page 402 and 403: (Manachère 1988), C. cinereus (Tsu
Page 404 and 405: emergence of fruiting bodies. In th
Page 406 and 407: Rather, development is arrested in
Page 408 and 409: 10 nm thick is highly insoluble and
Page 410 and 411: it has been suggested that hydropho
Page 412 and 413: expression in the stipe suggests th
Page 414 and 415: Cooper DNW, Boulianne RP, Charlton
Page 416 and 417: Lu BC (1974) Meiosis in Coprinus. R
Page 418 and 419: Takagi Y, Katayose Y, Shishido K (1
Page 420 and 421: 20 Meiosis in Mycelial Fungi D. Zic
Page 422 and 423: Fig. 20.1. A-E Diagrammatic represe
Page 424 and 425: etween dispersed DNA repeats. In N.
Page 426 and 427: Fig. 20.2. Meiotic recombination. S
Page 428 and 429: mechanism whereby homologues locate
Page 430 and 431: An important component of the bouqu
Page 432 and 433: observed when the mammal LE compone
Page 434 and 435: A. Chromosome and Sister-Chromatid
Page 436 and 437: ascus plus ascospore morphogenesis
Page 438 and 439: syndrome)discoveredasageneinvolvedi
Page 440 and 441: Kitajima TS, Kawashima SA, Watanabe
Page 442 and 443: Rossignol J-L, Faugeron G (1995) MI
Page 444 and 445:
Biosystematic Index Absidia glauca
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violaceum 153 Microsporum 149 Mimos
Page 448 and 449:
Subject Index ABC transporter 382 a
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fluffy 270, 276 formin 8, 10, 13, 1
Page 452 and 453:
MAT protein interaction 308, 315 ma
Page 454:
sporangiophore 234, 242, 246-252, 2
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