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have been identified, for example, AOX, CTR3, COX, SOD1 and SOD2. However, most of these have been identified only in homology searches of the P. anserina raw sequence available at http:// podospora.igmors.u-psud.fr/index.html, and remain to be investigated in more detail. The indepth elucidation of all pathways affecting life span is a prerequisite for the understanding of many age-related diseases, which reduce quality of life in particular in the elderly. However, today we are far from understanding these complex molecular networks in any biological system. Also in the future, research on aging models like P. anserina can be expected to provide important clues which are relevant for aging processes in general. Acknowledgements. We greatly acknowledge the P. anserina Genome Sequencing Consortium funded from CNRS/ Ministry of Research, and Génoscope, France (project coordinator Philippe Silar, http://podospora.igmors.upsud.fr/index.html). The availability of the raw sequence allowed us to screen for homologous genes involved in the regulation of copper homeostasis. References Almasan A, Mishra NC (1988) Molecular characterization of the mitochondrial DNA of a stopper mutant ER-3 of Neurospora crassa. Genetics 120:935–945 Barros MH, Johnson A, Tzagoloff A (2004) COX23, a homologue of COX17, is required for cytochrome oxidase assembly. J Biol Chem 279:31943–31947 Belcour L, Begel O (1980) Life-span and senescence in Podospora anserina: effect of mitochondrial genes and function. J Gen Microbiol 119:505–515 Belcour L, Vierny C (1986) Variable DNA splicing sites of a mitochondrial intron: relationship to the senescence process in Podospora. EMBO J 5:609–614 Belcour L, Begel O, Mosse MO, Vierny (1981) Mitochondrial DNAamplificationinsenescentculturesofPodospora anserina: variability between the retained, amplified sequences. Curr Genet 3:13–21 Belcour L, Begel O, Keller AM, Vierny C (1982) Does senescence in Podospora anserina result from instability of the mitochondrial genome? In: Slominski PP, Borst P, Attardi G (eds) Mitochondrial genes. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY, pp 415– 422 Belcour L, Koll F, Vierny C, Sainsard-Chanet AS, Begel O (1986) Are proteins encoded in mitochondrial introns involved in the process of senescence in the fungus Podospora anserina? In: Courtois Y, Faucheuy B, Forette B, Knook DL, Tréton JA (eds) Modern trends in aging research. John Libbey Eurotext, London, pp 68– 71 Bertrand H (2000) Role of mitochondrial DNA in the senescence and hypovirulence of fungi and potential for plant disease control. Annu Rev Phytopathol 38:397– 422 Fungal Senescence and Longevity 197 Bertrand H, Collins RA, Stohl LL, Goff SC, Lambowitz AM (1985) Deletion mutants of Neurospora crassa mitochondrial DNA and their relationship to the “stop-start” growth phenotype. Proc Natl Acad Sci USA 77:6032–6036 Bertrand H, Griffiths AJ, Court DA, Cheng CK (1986) An extrachromosomal plasmid is the etiological precursor of kalDNA insertion sequences in the mitochondrial chromosome of senescent Neurospora. Cell 47:829–837 Böckelmann B, Esser K (1986) Plasmids of mitochondrial origin in senescent mycelia of Podospora curvicolla. Curr Genet 10:803–810 Borghouts C, Osiewacz HD (1998) GRISEA, a coppermodulated transcription factor from Podospora anserina involved in senescence and morphogenesis is an ortholog of MAC1 in Saccharomyces cerevisiae. Mol Gen Genet 260:492–502 Borghouts C, Kimpel E, Osiewacz HD (1997) Mitochondrial DNA rearrangements of Podospora anserina are under the control of the nuclear gene grisea. Proc Natl Acad Sci USA 94:10768–10773 Borghouts C, Kerschner S, Osiewacz HD (2000) Copperdependence of mitochondrial DNA rearrangements in Podospora anserina. 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198 H.D. Osiewacz and A. Hamann Cummings DJ, Domenico JM, Turker MS (1987) Mitochondrial genomic changes during senescence in fungi. In: Thomson WW, Nothnagel EA, Huffacker RD (eds) Plant senescence: its biochemistry and physiology. American Society of Plant Physiologists, Bethesda, MD, pp 31–42 Dancis A, Haile D, Yuan DS, Klausner RD (1994) The Saccharomyces cerevisiae copper transport protein (Ctr1p). Biochemical characterization, regulation by copper, and physiologic role in copper uptake. J Biol Chem 269:25660–25667 Debets F, Yang X, Griffiths AJ (1995) The dynamics of mitochondrial plasmids in a Hawaiian population of Neurospora intermedia. Curr Genet 29:44–49 Delay C (1963) Observations inframicroscopiques sur le mycelium ‘senescent’ du Podospora anserina.CRAcad Sci Paris 256:4721–4724 De Vries H, de Jonge JC, van’t Sant S, Agsteribbe E, Arnberg A (1981) A “stopper” mutant of Neurospora crassa containing two populations of aberrant mitochondrial DNA. Curr Genet 3:205–211 De Vries H, Alzner-DeWeerd B, Breitenberger CA, Chang DD, de Jonge JC, RajBhandary UL (1986) The E35 stopper mutant of Neurospora crassa: precise localization of deletion endpoints in mitochondrial DNA and evidence that the deleted DNA codes for a subunit of NADH dehydrogenase. EMBO J 5:779–785 Dufour E, Boulay J, Rincheval V, Sainsard-Chanet A (2000) A causal link between respiration and senescence in Podospora anserina. Proc Natl Acad Sci USA 97:4138– 4143 Esser (1985) Genetic control of ageing: the mobile intron model. In: Bergener M, Emmini M, Stähelin HB (eds) The 1984 Sandoz lectures in gerontology. Academic Press, London, pp 3–20 Esser K, Keller W (1976) Genes inhibiting senescence in the ascomycete Podospora anserina. Mol Gen Genet 144:107–110 Esser K, Tudzynski P (1977) Prevention of senescence in the ascomycete Podospora anserina by the antibiotic tiamulin. Nature 265:454–456 Esser K, Tudzynksi P (1980) Senescence in fungi. In: Thiman KV (ed) Senescence in plants. CRC Press, Boca Raton, pp 67–83 Fassbender S, Bruhl KH, Ciriacy M, Kück U (1994) Reverse transcriptase activity of an intron encoded polypeptide. EMBO J 13:2075–2083 Fox AN, Kennell JC (2001) Association between variant plasmid formation and senescence in retroplasmidcontaining strains of Neurospora spp. Curr Genet 39:92–100 Frese D, Stahl U (1992) Oxidative stress and ageing in the fungus Podospora anserina. Mech Ageing Dev 65:277– 288 Glerum DM, Shtanko A, Tzagoloff A (1996) Characterization of COX17, a yeast gene involved in copper metabolism and assembly of cytochrome oxidase. J Biol Chem 271:14504–14509 Graden JA, Winge DR (1997) Copper-mediated repression of the activation domain in the yeast Mac1p transcription factor. Proc Natl Acad Sci USA 94:5550–5555 Gralla EB, Thiele DJ, Silar P, Valentine JS (1991) ACE1, a copper-dependent transcription factor, activates expression of the yeast copper, zinc superoxide dismutase gene. Proc Natl Acad Sci USA 88:8558–8562 Griffiths AJ (1992) Fungal senescence. Annu Rev Genet 26:351–372 Guarente L (1997) Link between aging and the nucleolus. Genes Dev 11:2449–2455 Guarente L, Kenyon C (2000) Genetic pathways that regulate ageing in model organisms. Nature 408:255–262 Handley L, Caten CE (1973) Vegetative death: a mitochondrial mutation in Aspergillus amstelodami. Heredity 31:136 Harman D (1956) A theory based on free radical and radiation chemistry. J Gerontol 11:298–300 Harman D (1981) The aging process. Proc Natl Acad Sci USA 78:7124–7128 Harman D (1998) Aging and oxidative stress. J Int Fed Clin Chem 10:24–27 Hermanns J, Osiewacz HD (1992) The linear mitochondrial plasmid pAL2-1 of a long-lived Podospora anserina mutant is an invertron encoding a DNA and RNA polymerase. Curr Genet 22:491–500 Hermanns J, Osiewacz HD (1996) Induction of longevity by cytoplasmic transfer of a linear plasmid in Podospora anserina. Curr Genet 29:250–256 Hermanns J, Asseburg A, Osiewacz HD (1994) Evidence for a life span-prolonging effect of a linear plasmid in a longevity mutant of Podospora anserina. MolGen Genet 243:297–307 Jamet-Vierny C, Begel O, Belcour L (1980) Senescence in Podospora anserina: amplification of a mitochondrial DNA sequence. Cell 21:189–194 Jazwinski SM (2000) Metabolic control and ageing. Trends Genet 16:506–511 Jazwinski SM (2001) New clues to old yeast. Mech Ageing Dev 122:865–882 Jazwinski SM (2004) Yeast replicative life span – the mitochondrial connection. FEMS Yeast Res 5:119–125 Jazwinski SM (2005) Yeast longevity and aging – the mitochondrial connection. Mech Ageing Dev 126:243–248 Jinks JL (1959) Lethal suppressive cytoplasm in aged clones of Aspergillus glaucus. J Gen Microbiol 21:397–409 Kim S, Ohkuni K, Couplan E, Jazwinski SM (2004) The histon acetyltransferase GCN5 modulates the retrograde response and genome stability determining yeast longevity. Biogerontology 5:305–316 Kimpel E, Osiewacz HD (1999) PaGrg1, a glucoserepressible gene of Podospora anserina that is differentially expressed during lifespan. Curr Genet 35:557–563 Kirchman PA, Kim S, Lai CY, Jazwinski SM (1999) Interorganelle signaling is determinant of longevity in Saccharomyces cerevisiae. Genetics 152:179–190 Koll F, Begel O, Keller A-M, Vierny C, Belcour L (1984) Ethidium bromide rejuvenation of senescent cultures of Podospora anserina: loss of senescence-specific DNA and recovery of normal mitochondrial DNA. Curr Genet 8:127–134 Koll F, Belcour L, Vierny C (1985) A 1100-bp sequence of mitochondrialDNAisinvolvedinsenescenceprocess in Podospora: study of senescent and mutant cultures. Plasmid 14:196–117 Krause F, Scheckhuber CQ, Werner A, Rexroth S, Reifschneider NH, Dencher NA, Osiewacz HD (2004) Supramolecular organization of cytochrome c oxidase- and alternative oxidase-dependent respiratory chains in the filamentous fungus Podospora anserina. J Biol Chem 279:26453–26461
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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
Page 160 and 161: 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
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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 212 and 213: Kück U, Stahl U, Esser K (1981) Pl
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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250 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
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the balance between sexual and asex
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ductionofeitherpheromoneisdirectlyc
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(Catlett et al. 2003). Eleven genes
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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
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Balestrini R, Mainieri D, Soragni E
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point mutation of the beta subunit
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Mitchell TK, Dean RA (1995) The cAM
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YamashiroCT,EbboleDJ,LeeBU,BrownRE,
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358 L.A. Casselton and M.P. Challen
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376 M. Feldbrügge et al. different
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378 M. Feldbrügge et al. Fig. 18.3
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380 M. Feldbrügge et al. et al. 20
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382 M. Feldbrügge et al. for unbia
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384 M. Feldbrügge et al. In U. may
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386 M. Feldbrügge et al. Neurospor
Page 394 and 395:
388 M. Feldbrügge et al. Bernards
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390 M. Feldbrügge et al. O’Donne
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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
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emergence of fruiting bodies. In th
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Rather, development is arrested in
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10 nm thick is highly insoluble and
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it has been suggested that hydropho
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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
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Takagi Y, Katayose Y, Shishido K (1
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20 Meiosis in Mycelial Fungi D. Zic
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Fig. 20.1. A-E Diagrammatic represe
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etween dispersed DNA repeats. In N.
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Fig. 20.2. Meiotic recombination. S
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mechanism whereby homologues locate
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An important component of the bouqu
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observed when the mammal LE compone
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A. Chromosome and Sister-Chromatid
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ascus plus ascospore morphogenesis
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syndrome)discoveredasageneinvolvedi
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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
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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
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sporangiophore 234, 242, 246-252, 2
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