Growth, Differentiation and Sexuality

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Kück U, Stahl U, Esser K (1981) Plasmid-like DNA is part of mitochondrial DNA in Podospora anserina. Curr Genet 3:151–156 Kück U, Kappelhoff B, Esser K (1985a) Despite mtDNA polymorphism the mobile intron (plDNA) of the COI gene is present in 10 different races of Podospora anserina. Curr Genet 10:59–67 Kück U, Osiewacz HD, Schmidt U, Kappelhoff B, Schulte E, Stahl U, Esser K (1985b) The onset of senescence is affected by DNA rearrangements of a discontinuous mitochondrial gene in Podospora anserina. Curr Genet 9:373–382 Lazarus CM, Küntzel H (1981) Anatomy of amplified mitochondrial DNA in “Ragged” mutants of Aspergillus amstelodami: excision points within protein genes and a common 215 bp segment containing a possible origin of replication. Curr Genet 4:99–107 Lazarus CM, Earl AJ, Turner G, Künzel H (1980) Amplification of a mitochondrial DNA sequence in the cytoplasmatically inherited “Ragged” mutant of Aspergillus amstelodami. Eur J Biochem 106:633–641 Liao X, Butow RA (1993) RTG1 and RTG2: two yeast genes required for a novel path of communication from mitochondria to the nucleus. Cell 72:61–71 Liao XS, Small WC, Srere PA, Butow RA (1991) Intramitochondrial functions regulate nonmitochondrial citrate synthase (CIT2) expression in Saccharomyces cerevisiae. Mol Cell Biol 11:38–46 Linnane AW, Marzuki S, Ozawa T, Tanaka M (1989) Mitochondrial DNA mutations as an important contributor to ageing and degenerative disease. Lancet 1:642–645 Lorin S, Dufour E, Boulay J, Begel O, Marsy S, Sainsard- Chanet A (2001) Overexpression of the alternative oxidase restores senescence and fertility in a long-lived respiration-deficient mutant of Podospora anserina. Mol Microbiol 42:1259–1267 Maas MFPM, de Boer HJ, Debets AJM, Hoekstra RF (2004) The mitochondrial plasmid pAL2-1 reduces calorie restriction mediated life span extension in the filamentous fungus Podospora anserina. Fungal Genet Biol 41:865–871 Marbach K, Fernandez-Larrea J, Stahl U (1994) Reversion of a long-living, undifferentiated mutant of Podospora anserina by copper. Curr Genet 26:184–186 Marcou D (1961) Notion de longévité et nature cytoplasmique du déterminant de la sénescence chez quelques champignons. Ann Sci Nat Bot 12:653–764 McDaniels CPJ, Jensen LT, Srinivasan C, Winge DR, Tullius TD (1999) The yeast transcription factor Mac1 binds to DNA in a modular fashion. J Biol Chem 274:26962–26967 McMurray MA, Gottschling DE (2004) Aging and genetic instability in yeast. Curr Opin Microbiol 7:673–679 Michel F, Lang B (1985) Mitochondrial class I introns encode proteins related to the reverse transcriptases of retroviruses. Nature 316:641–643 Munkres K, Rana RS (1978) Antioxidants prolong life span and inhibit the senescence-dependent accumulation of fluorescent pigment (lipofuscin) in clones ofPodospora anserina. Mech Ageing Dev 7:407–415 Navaraj A, Pandit A, Maheshwari R (2000) Senescent:anew Neurospora crassa nuclear gene mutant derived from nature exhibits mitochondrial abnormalities and a “death” phenotype. Fungal Genet Biol 29:165–173 Fungal Senescence and Longevity 199 Nobrega MP, Bandeira SC, Beers J, Tzagoloff A (2002) Characterization of COX19, a widely distributed gene required for expression of mitochondrial cytochrome oxidase. J Biol Chem 277:40206–40211 Osiewacz HD (1995) Aging and genetic instabilities. In: Esser K, Martin GM (eds) Molecular aspects of aging. Wiley, New York, pp 29–44 Osiewacz HD (2002a) Mitochondrial functions and aging. Gene 286:65–71 Osiewacz HD (2002b) Genes, mitochondria and aging in filamentous fungi. Ageing Res Rev 1:425–442 Osiewacz HD, Esser K (1984) The mitochondrial plasmid of Podospora anserina: a mobile intron of a mitochondrial gene. Curr Genet 8:299–305 Osiewacz HD, Hermanns J (1992) The role of mitochondrial DNA rearrangements in aging and human diseases. Aging (Milano) 4:273–286 Osiewacz HD, Nuber U (1996) GRISEA, a putative copperactivated transcription factor from Podospora anserina involved in differentiation and senescence. Mol Gen Genet 252:115–124 OsiewaczHD,HermannsJ,MarcouD,TriffiM,EsserK (1989) Mitochondrial DNA rearrangements are correlated with a delayed amplification of the mobile intron (plDNA) in a long-lived mutant of Podospora anserina. Mutat Res 219:9–15 Prillinger H, Esser K (1977) The phenoloxidases of the ascomycete Podospora anserina. XIII. Action and interaction of genes controlling the formation of laccase. Mol Gen Genet 156:333–345 Richter OM, Ludwig B (2003) Cytochrome c oxidase – structure, function, and physiology of a redox-driven molecular machine. Rev Physiol Biochem Pharmacol 147:47–74 Rizet G (1953) Sur l’impossibilité d’obtenir la multiplication végétative ininterrompue et illimitée de l’Ascomycète Podospora anserina. C R Acad Sci Paris 237:838– 840 Samuels DC, Schon EA, Chinnery PF (2004) Two direct repeats cause most human mtDNA deletions. Trends Genet 20:393–398 Schulte E, Kück U, Esser K (1988) Extrachromosomal mutants from Podospora anserina: permanent vegetative growth in spite of multiple recombination events in the mitochondrial genome. Mol Gen Genet 211:342– 349 Sekito T, Thornton J, Butow RA (2000) Mitochondria-tonuclear signaling is regulated by the subcellular localization of transcription factors Rtg1p and Rtg3p. Mol Biol Cell 11:2103–2115 Sellem CH, Lecellier G, Belcour L (1993) Transposition of a group II intron. Nature 366:176–178 Sellem CH, Lemare C, Lorin S, Dujardin G, Sainsard- Chanet A (2005) Interaction between the oxa1 and rmp1 genes modulates respiratory complex assembly and lifespan in Podospora anserina. Genetics 169:1379–1389 Silar P, Koll F, Rossignol M (1997) Cytosolic ribosomal mutations that abolish accumulation of a circular intron in the mitochondria without preventing senescence of Podospora anserina. Genetics 145:697–705 Silar P, Lalucque H, Vierny C (2001) Cell degeneration in the model system Podospora anserina. Biogerontology 2:1–17
200 H.D. Osiewacz and A. Hamann Smith ML, Bruhn JN, Anderson JB (1992) The fungus Armillaria bulbosa is among the largest and oldest living organisms. Nature 356:428–431 Stahl U, Lemke PA, Tudzynski P, Kück U, Esser K (1978) Evidence for plasmid like DNA in a filamentous fungus, the ascomycete Podospora anserina. Mol Gen Genet 162:341–343 Stahl U, Tudzynski P, Kück U, Esser P (1982) Replication and expression of a bacterial-mitochondrial hybrid plasmid in the fungus Podospora anserina.ProcNatlAcad Sci USA 79:3641–3645 Stumpferl SW, Stephan O, Osiewacz HD (2004) Impact of a disruption of a pathway delivering copper to mitochondria on Podospora anserina metabolism and life span. Eukaryot Cell 3:200–211 Sturtz LA, Diekert K, Jensen LT, Lill R, Culotta VC (2001) A fraction of yeast Cu/Zn superoxide dismutase and its metallochaperone, CCS, localize to the intermembrane space of mitochondria: a physical role for SOD1 in guarding against mitochondrial oxidative damage. J Biol Chem 276:38084–38089 Tudzynski P, Esser K (1977) Inhibitors of mitochondrial function prevent senescence in the ascomycete Podospora anserina. Mol Gen Genet 153:111–113 Tudzynski P, Esser K (1979) Chromosomal and extrachromosomal control of senescence in the ascomycete Podospora anserina. Mol Gen Genet 173:71–84 Tudzynski P, Stahl U, Esser K (1982) Development of an eukaryotic cloning system in Podospora anserina. I. Long-lived mutants as potential recipients. Curr Genet 6:219–222 Turker MS, Nelson JG, Cummings DJ (1987) A Podospora anserina longevity mutant with a temperaturesensitive phenotype for senescence. Mol Cell Biol 7:3199–3204 Vierny C, Keller AM, Begel O, Belcour L (1982) A sequence of mitochondrial DNA is associated with the onset of senescence in a fungus. Nature 297:157–159 Wagner AM, Moore AL (1997) Structure and function of the plant alternative oxidase: its putative role in the oxygen defense mechanism. Biosci Rep 17:319–333 Wallace DC (1992) Diseases of mitochondrial DNA. Annu Rev Biochem 6:1175–1212 Wallace DC (2001) Mitochondrial diseases in man and mouse. Science 283:1482–1488 Wright RM, Horrum MA, Cummings DJ (1982) Are mitochondrial structural genes selectively amplified during senescence in Podospora anserina? Cell 29:505–515 Yoshikawa S, Shinzawa-Itoh K, Tsukihara T (1998) Crystal structure of bovine heart cytochrome c oxidase at 2.8 A resolution. J Bioenerg Biomembr 30:7–14 Zhu Z, Labbe S, Pena MM, Thiele DJ (1998) Copper differentially regulates the activity and degradation of yeast Mac1 transcription factor. J Biol Chem 273:1277–1280
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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
Page 162 and 163: active phenotype het-s. The neutral
Page 164 and 165: Table. 8.1. (continued) Fungal Hete
Page 166 and 167: is a complex genetic trait controll
Page 168 and 169: indicate how speciation may be init
Page 170 and 171: ility controlled by multiple allele
Page 172 and 173: dependonthematingtypegenes,wasobser
Page 174 and 175: 6. Relation with Histo-Incompatibil
Page 176 and 177: Semi-Incompatibilität. Z Indukt Ab
Page 178 and 179: Micali CO, Smith ML (2003) On the i
Page 180 and 181: Vilgalys RJ, Miller OK (1987) Matin
Page 182 and 183: 168 B.C.K. Lu (Esser et al. 1980; K
Page 184 and 185: 170 B.C.K. Lu enterthePCDpathway,wi
Page 186 and 187: 172 B.C.K. Lu et al. 2004). It is l
Page 188 and 189: 174 B.C.K. Lu (MMP), through ruptur
Page 190 and 191: 176 B.C.K. Lu Fig. 9.1. Effects of
Page 192 and 193: 178 B.C.K. Lu drial fission during
Page 194 and 195: 180 B.C.K. Lu Although the cytologi
Page 196 and 197: 182 B.C.K. Lu be arrested at diffus
Page 198 and 199: 184 B.C.K. Lu Harris MH, Thompson C
Page 200 and 201: 186 B.C.K. Lu oxygen species, in Kl
Page 202 and 203: 10 Senescence and Longevity H.D. Os
Page 204 and 205: the amplification of plDNA is not a
Page 206 and 207: GRISEA is an orthologue of the yeas
Page 208 and 209: Fig. 10.3. Copper delivery to the c
Page 210 and 211: have been identified, for example,
Page 214 and 215: Signals in Growth and Development
Page 216 and 217: 204 U. Ugalde II. Germination The p
Page 218 and 219: 206 U. Ugalde Fig. 11.2.A-C Drawing
Page 220 and 221: 208 U. Ugalde duction (Schimmel et
Page 222 and 223: 210 U. Ugalde position, possibly in
Page 224 and 225: 212 U. Ugalde Champe SP, Rao P, Cha
Page 226 and 227: 12 Pheromone Action in the Fungal G
Page 228 and 229: sibly due to displacement of the hy
Page 230 and 231: all these compounds, the B-derivate
Page 232 and 233: shows the same activity in M. muced
Page 234 and 235: C. Oomycota In the non-mycotan phyl
Page 236 and 237: following sequence of events has be
Page 238 and 239: the standard Mendelian segregation
Page 240 and 241: Elliott CG, Knights BA (1981) Uptak
Page 242 and 243: constitutively transcribed but its
Page 244 and 245: 234 L.M. Corrochano and P. Galland
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252 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
Page 328 and 329:
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
Page 336 and 337:
Table. 16.1. (continued) Fruiting B
Page 338 and 339:
(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
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the balance between sexual and asex
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ductionofeitherpheromoneisdirectlyc
Page 348 and 349:
(Catlett et al. 2003). Eleven genes
Page 350 and 351:
negative mutation of KREV-1 resulte
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through MAP kinase modules to cell-
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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 366 and 367:
Page 368 and 369:
Page 370 and 371:
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Page 374 and 375:
Page 376 and 377:
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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
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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
Page 446 and 447:
violaceum 153 Microsporum 149 Mimos
Page 448 and 449:
Subject Index ABC transporter 382 a
Page 450 and 451:
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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