Growth, Differentiation and Sexuality

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372 L.A. Casselton and M.P. Challen Day PR (1963a) Mutations affecting the A mating-type factor in Coprinus lagopus. Genet Res Camb 4:55–64 Day PR (1963b) The structure of the A mating type factor in Coprinus lagopus. Wild alleles. Genet Res Camb 4:323– 325 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 Fowler TJ, DeSimone SM, Mitton MF, Kurjan J, Raper CA (1999) Multiple sex pheromones and receptors of a mushroom-producing fungus elicit mating in yeast. Mol Biol Cell 10:2559–2572 Fowler TJ, Mitton MF, Vaillancourt LJ, Raper CA (2001) Changes in mate recognition through alterations of pheromones and receptors in the multisexual mushroom fungus Schizophyllum commune. Genetics 158:1491–1503 Fowler TJ, Mitton MF, Rees EI, Raper CA (2004) Crossing the boundary between the Bα and Bβ mating-type loci in Schizophyllum commune. Fungal Genet Biol 41:89–101 Fraser JA, Heitman J (2004) Evolution of fungal sex chromosomes. Mol Microbiol 51:299–306 Giesy RM, Day PR (1965) The septal pores of Coprinus lagopus (Fr.) sensu Buller in relation to nuclear migration. Am J Bot 52:287–293 Gillissen B, Bergemann J, Sandmann C, Schroeer B, Bolker M, Kahmann R (1992) A 2-component regulatory system for self non-self recognition in Ustilago maydis. Cell 68:647–657 Gold S, 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 Granado JD, Kertesz-Chaloupková K, Aebi M, Kües U (1997) Restriction enzyme-mediated DNA integration in Coprinus cinereus. Mol Gen Genet 256:28–36 Halsall JR, Milner MJ, Casselton LA (2000) Three subfamiliesofpheromoneandreceptorgenesgeneratemultiple B mating specificities in the mushroom Coprinus cinereus. Genetics 154:1115–1123 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. PlantCell 11:1293–1305 Haylock RW, Economou A, Casselton LA (1980) Dikaryon formation in Coprinus cinereus:selectionandidentification of B factor mutants. J Gen Microbiol 121:17–26 Herskowitz I (1988) The life cycle of the budding yeast Saccharomyces cerevisiae. Microbiol Rev 52:536–553 Hiscock SJ, Kües U (1999) Cellular and molecular mechanisms of sexual incompatibility in plants and fungi. Int Rev Cytol Surv Cell Biol 193:165–295 Hull CM, Heitman J (2002) Fungal mating: Candida albicans flips a switch to get in the mood. Curr Biol 12:R782– R784 Hull CM, Davidson RC, Heitman J (2002) Cell identity and sexual development in Cryptococcus neoformans are controlled by the mating-type-specific homeodomain protein Sxi1α. Genes Dev 16:3046–3060 Hull CM, Boily MJ, Heitman J (2005) Sex-specific homeodomain proteins Sxi1α and Sxi2a coordinately regulate sexual development in Cryptococcus neoformans. Eukaryot Cell 4:526–535 Inada K, Morimoto Y, Arima T, Murata Y, Kamada T (2001) The clp1 gene of the mushroom Coprinus cinereus is essential for A-regulated sexual development. Genetics 157:133–140 Iwasa M, Tanabe S, Kamada T (1998) The two nuclei in the dikaryon of the homobasidiomycete Coprinus cinereus change position after each conjugate division. Fungal Genet Biol 23:110–116 Jacobsen S, Wittig M, Pöggeler S (2002) Interaction between mating-type proteins from the homothallic fungus Sordaria macrospora. Curr Genet 41:150–158 James T, Kües U, Cullen D, Vilgalys R (2003) The origins of unifactorial mating systems in Coprinellus disseminatus and Phanerochaete chrysosporium from bifactorial ancestors. Inoculum (MSA abstr) 54:28 James TY, Kües U, Rehner SA, Vilgalys R (2004a) Evolution of the gene encoding mitochondrial intermediate peptidase and its cosegregation with the A mating-type locus of mushroom fungi. Fungal Genet Biol 41:381– 390 James TY, Liou SR, Vilgalys R (2004b) The genetic structure and diversity of theAand B mating-type genes fromthe tropical oyster mushroom, Pleurotus djamor. Fungal Genet Biol 41:813–825 Johnson AD (1995) Molecular mechanisms of cell-type determination in budding yeast. Curr Opin Genet Dev 5:552–558 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, Steinberg G, Basse C, Feldbrügge M, Kämper J (2000) Ustilago maydis, thecausativeagentofcorn smut disease. In: Kronstad JW (ed) Fungal pathology. Kluwer, Dordrecht, pp 347–371 Kamada T (2002) Molecular genetics of sexual development in the mushroom Coprinus cinereus. BioEssays 24:449– 459 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 Kim H, Borkovich KA (2004) A pheromone receptor gene, pre-1, is essential for mating type specific directional growth and fusion of trichogynes and female fertility in Neurospora crassa. MolMicrobiol 52:1781–1798 Koltin Y, Stamberg J, Lemke P (1972) Genetic structure and evolution of the incompatibility factors in higher fungi. Bacteriol Rev 36:156–171 Kües U (2000) Life history and developmental processes in the basidiomycete Coprinus cinereus.MicrobiolMol Biol Rev 64:316–353 Kües U, Casselton LA (1992) Homeodomains and regulation of sexual development in basidiomycetes. Trends Genet 8:154–155
KüesU,RichardsonWV,TymonAM,MutasaES,GöttgensB, Gaubatz S, Gregoriades A, Casselton LA (1992) The combination of dissimilar alleles of the Aα and Aβ gene complexes, whose proteins contain homeo domain motifs, determines sexual development in the mushroom Coprinus cinereus. Genes Dev 6:568–577 Kües U, Göttgens B, Stratmann R, Richardson WVJ, Oshea SF, Casselton LA (1994) A chimeric homeodomain protein causes self compatibility and constitutive sexual development in the mushroom Coprinus cinereus. EMBO J 13:4054–4059 Kües U, James TY, Vilgalys R, Challen MP (2001) The chromosomal region containing pab-1, mip, andthe A mating type locus of the secondarily homothallic homobasidiomycete Coprinus bilanatus. CurrGenet 39:16–24 Kües U, Walser PJ, Klaus MJ, Aebi M (2002) Influence of activated A and B mating-type pathways on developmental processes in the basidiomycete Coprinus cinereus.Mol Genet Genomics 268:262–271 Kwon-Chung KJ (1975) A new genus Filobasidiella, the perfect state of Cryptococcus neoformans. Mycologia 67:1197–1200 Kwon-Chung KJ (1980) Nuclear genotypes of spore chains in Filobasidiella neoformans (Cryptococcus neoformans). Mycologia 72:418–422 Kwon-Chung KJ, Bennett JE (1978) Distribution of α and a mating types of Cryptococcus neoformans among natural and clinical isolates. Am J Epidemiol 108:337– 340 LeeN,BakkerenG,WongK,SherwoodJE,KronstadJW (1999) The mating-type and pathogenicity locus of the fungus Ustilago hordei spans a 500-kb region. Proc Natl Acad Sci USA 96:15026–15031 Lengeler KB, Davidson RC, D’Souza C, Harashima T, Shen WC, Wang P, Pan XW, Waugh M, Heitman J (2000) Signal transduction cascades regulating fungal development and virulence. Microbiol Mol Biol Rev 64:746–785 Lengeler KB, Fox DS, Fraser JA, Allen A, Forrester K, Dietrick FS, Heitman J (2002) Mating-type locus of Cryptococcus neoformans: a step in the evolution of sex chromosomes. Eukaryot Cell 1:704–718 Li Y, Challen MP, Elliott TJ, Casselton LA (2004) Molecular analysis of breeding behaviour in Agaricus species. Mushroom Sci 16:103–109 Lin X, Hull CM, Heitman J (2005) Sexual reproduction betweenpartnersofthesamematingtypeinCryptococcus neoformans. Nature 434:1017–1021 Magae Y, Novotny C, Ullrich R (1995) Interaction of the Aα Y and Z mating-type homeodomain proteins of Schizophyllum commune detected by the two-hybrid system. Biochem Biophys Res Commun 211:1071–1076 Makino R, Kamada T (2004) Isolation and characterization of mutations that affect nuclear migration for dikaryosis in Coprinus cinereus. Curr Genet 45:149– 156 Martinez D, Larrondo LF, Putnam N, Gelpke MDS, Huang K, Chapman J, Helfenbein KG, Ramaiya P, Detter JC, Larimer F et al. (2004) Genome sequence of the lignocellulose degrading fungus Phanerochaete chrysosporium strain RP78. Nat Biotechnol 22:695–700 Mating Type Genes in Basidiomycetes 373 May G, Matzke E (1995) Recombination and variation at the A mating-type of Coprinus cinereus. Mol Biol Evol 12:794–802 May G, Shaw F, Badrane H, Vekemans X (1999) The signature of balancing selection: fungal mating compatibility gene evolution. Proc Natl Acad Sci USA 96:9172– 9177 McClelland CM, Chang YC, Varma A, Kwon-Chung KJ (2004) Uniqueness of the mating system in Cryptococcus neoformans. Trends Microbiol 12:208– 212 Moore TDE, Edman JC (1993) The α-mating type locus of Cryptococcus neoformans contains a peptide pheromone gene. Mol Cell Biol 13:1962–1970 Müller P, Weinzierl G, Brachmann A, Feldbrügge M, Kahmann R (2003) Mating and pathogenic development of the smut fungus Ustilago maydis are regulated by one mitogen-activated protein kinase cascade. Eukaryot Cell 2:1187–1199 Murata Y, Fujii M, Zolan ME, Kamada T (1998) Molecular analysis of pcc1, a gene that leads to A-regulated sexual morphogenesis in Coprinus cinereus. Genetics 149:1753–1761 Olesnicky NS, Brown AJ, Dowell SJ, Casselton LA (1999) A constitutively active G-protein-coupled receptor causes mating self-compatibility in the mushroom Coprinus. EMBO J 18:2756–2763 Olesnicky NS, Brown AJ, Honda Y, Dyos SL, Dowell SJ, Casselton LA (2000) Self-compatible B mutants in Coprinus with altered pheromone-receptor specificities. Genetics 156:1025–1033 O’Shea SF, Chaure PT, Halsall JR, Olesnicky NS, Leibbrandt A, Connerton IF, Casselton LA (1998) A large pheromone and receptor gene complex determines multiple B mating type specificities in Coprinus cinereus. Genetics 148:1081–1090 Parag Y (1962) Mutations in the B incompatibility factor of Schizophyllum commune. ProcNatlAcadSciUSA 48:743–750 Pardo EH, Oshea SF, Casselton LA (1996) Multiple versions of the A mating type locus of Coprinus cinereus are generated by three paralogous pairs of multiallelic homeobox genes. Genetics 144:87–94 Pukkila PJ, Casselton LA (1991) Molecular genetics of the agaric Coprinus cinereus. In: Bennett JW, Lasure LL (eds) More gene manipulations in fungi. Academic Press, London, pp 126–150 Quintanilha A, Pinto Lopes J (1950) Aperçu sur l’état actuel de nos connaissances concernant la ‘conduite sexuelle’ des espèces d’Hymenomycetes. Bol Soc Broteriana 24:115–290 Raper JR (1966) Genetics of sexuality in higher fungi. Ronald, New York Raper JR, Krongelb GS, Baxter MG (1958) The number and distribution of incompatibility factors in Schizophyllum commune. Am Nat 92:221–232 Raper JR, Baxter MG, Ellingboe AH (1960) The genetic structure of the incompatibility factors of Schizophyllum commune: theA factor. Proc Natl Acad Sci USA 46:833–842 Raper JR, Boyd DH, Raper CA (1965) Primary and secondary mutations at the incompatibility loci in Schizophyllum. Proc Natl Acad Sci USA 53:1324– 1332
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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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Page 332 and 333: 16 Fruiting-Body Development in Asc
Page 334 and 335: phae originating from the base of a
Page 336 and 337: Table. 16.1. (continued) Fruiting B
Page 338 and 339: (Raju 1992). When male-sterile muta
Page 340 and 341: 1. nsd (never in sexual development
Page 342 and 343: 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 394 and 395: 388 M. Feldbrügge et al. Bernards
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
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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
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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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