Growth, Differentiation and Sexuality

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32 L.J. García-Rodríguez et al. the ER (Titorenko et al. 2000). This suggests that ER-derived vesicles can fuse with preexisting peroxisomes or mature into peroxisomes themselves (Erdmann et al. 1997; Titorenko and Rachubinski 1998; Tabak et al. 1999). Finally, in S. cerevisiae, peroxisomes segregate in a cell cycle-dependent manner. Time-lapse microscopy experiments revealed that they move along the cell cortex before bud formation, and from the incipient bud site into the bud during bud growth. In small buds, peroxisomes are present at the bud tip, and as the bud grows they move to the bud cortex (Hoepfner et al. 2001). Peroxisomes colocalize with actin cables, and depolymerization of the actin cytoskeleton after Lat-A treatment results in a loss of peroxisome-directed movement. Moreover, the type V myosin Myo2p is involved in peroxisome movement and inheritance in S. cerevisiae, as peroxisome localization in the buds isdelayeduponincubationofaconditionalMYO2 mutant at restrictive conditions. V. Conclusions Organelle inheritance has emerged as an active and fundamentally important branch of cell biology. As a result of advances in our understanding of organelle biogenesis, cell cycle progression, cytoskeletal dynamics, establishment of cell polarity, and membrane–cytoskeletal interactions, we are now in a position to uncover the molecular basis for organelle inheritance. Diversity appears to be a theme in organelle inheritance, from the use of immobilization versus selective mobilization for control of organelle position, in the type of force-generating machinery that is used to drive organelle motility, and in the type of cytoskeletal network used for all forms of positional control. Fungiwillcontinuetoplayacentralroleasmodel systems to understand the mechanisms that ensure proper organelle segregation during cell division in dividing cells. Acknowledgements. We would like to thank the members of the Pon laboratory for support and critical evaluation, and Thomas Huckaba (Columbia University), Mark Winey (University of Colorado), and Berl Oakley (Ohio State University) for providing images and schematics. This work was supported by research grants to L. Pon from the National Institutes of Health (GM45735 and GM66307) and the American Cancer Society (RPG-97-163-04-CSM), and by a post-doctoral fellowship to L. García-Rodríguez from the Ramon Areces Foundation. References Adams AEM, Botstein D, Drubin DG (1991) Requirement of yeast fimbrin for actin organization and morphogenesis in vivo. Nature 354:404–408 Aist JR, Bayles CJ (1991) Organelle motility within mitotic asters of the fungus Nectria haematococca. EurJCell Biol 56:358–363 Alberti-Segui C, Dietrich F, Altmann-Johl R, Hoepfner D, Philippsen P (2001) Cytoplasmic dynein moves nuclei towards the hyphal tip in the filamentous ascomycete Ashbya gossypii. J Cell Sci 114:975–986 Asakura T, Sasaki T, Nagano F, Satoh A, Obaishi H, Nishioka H, Imamura H, Hotta K, Tanaka K, Nakanishi H et al. (1998) Isolation and characterization of a novel actin filament-binding protein from Saccharomyces cerevisiae. Oncogene 16:121–130 Baba M, Osumi M (1987) Transmission and scanning electron microscopy examination of intracellular organelles in freeze-substituted Kloeckera and Saccharomyces cerevisiae yeast cells. J Electron Microsc 5:249–261 Banuett F, Herskowitz I (2002) Bud morphogenesis and the actin and microtubule cytoskeletons during budding in the corn smut fungus Ustilago maydis. Fungal Genet Biol 37:149–170 Barelle CJ, Bohula EA, Kron SJ, Wessels D, Soll DR, Schafer A, Brown AJ, Gow NA (2003) Asynchronous cell cycle and asymmetric vacuolar inheritance in true hyphae of Candida albicans. Eukaryot Cell 2:398–410 Beach DL, Thibodeaux J, Maddox P, Yeh E, Bloom K (2000) TheroleoftheproteinsKar9andMyo2inorientingthe mitotic spindle of budding yeast. Curr Biol 10:1497– 1506 Beams HW, Kessel RG (1968) The Golgi apparatus: structure and function. Int Rev Cytol 23:209–276 Bellu AR, Komori M, van der Klei IJ, Kiel JA, Veenhuis M (2001) Peroxisome biogenesis and selective degradation converge at Pex14p. J Biol Chem 276:44570–44574 Berger KH, Sogo LF, Yaffe MP (1997) Mdm12p, a component required for mitochondrial inheritance that is conserved between budding and fission yeast. J Cell Biol 136:545–553 Bertrand E, Chartrand P, Schaefer M, Shenoy SM, Singer RH, Long RM (1998) Localization of ASH1 mRNA particles in living yeast. Mol Cell 2:437–445 Bevis BJ, Hammond AT, Reinke CA, Glick BS (2002) De novo formation of transitional ER sites and Golgi structures in Pichia pastoris. Nat Cell Biol 4:750–756 Bohl F, Kruse C, Frank A, Ferring D, Jansen RP (2000) She2p, a novel RNA-binding protein tethers ASH1 mRNA to the Myo4p myosin motor via She3p. EMBO J 19:5514–5524 Boldogh IR, Yang HC, Nowakowski WD, Karmon SL, Hays LG, Yates JR III, Pon LA (2001a) Arp2/3 complex and actin dynamics are required for actin-based mitochondrial motility in yeast. Proc Natl Acad Sci USA 98:3162–3167 Boldogh IR, Yang HC, Pon LA (2001b) Mitochondrial inheritance in budding yeast. Traffic 2:368–374
Boldogh IR, Nowakowski DW, Yang HC, Chung H, Karmon S, Royes P, Pon LA (2003) A protein complex containing Mdm10p, Mdm12p, and Mmm1p links mitochondrial membranes and DNA to the cytoskeletonbased segregation machinery. Mol Biol Cell 14:4618– 4627 Boldogh IR, Ramcharan SL, Yang HC, Pon LA (2004) A type V myosin (Myo2p) and a Rab-like G-protein (Ypt11p) are required for retention of newly inherited mitochondria in yeast cells during cell division. Mol Biol Cell 15:3994–4002 Botstein D, Amberg D, Mulholland J, Huffaker T, Adams A, Drubin D, Stearns T (1997) The yeast cytoskeleton. In: Pringle JR, Broach JR, Jones EW (eds) The molecular and cellular biology of the yeast Saccharomyces: cell cycle and cell biology. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, pp 1–90 Burgess SM, Delannoy M, Jensen RE (1994) MMM1 encodes a mitochondrial outer membrane protein essential for establishing and maintaining the structure of yeast mitochondria. J Cell Biol 126:1375–1391 Catlett NL, Weisman LS (1998) The terminal tail region of a yeast myosin-V mediates its attachment to vacuole membranes and sites of polarized growth. Proc Natl Acad Sci USA 95:14799–14804 Catlett N, Duex J, Tang F, Weisman L (2000) Two distinct regions in a yeast myosin-V tail domain are required for the movement of different cargoes. J Cell Biol 150:513– 526 Chang F, Nurse P (1996) How fission yeast fission in the middle. Cell 84:191–194 Chang FS, Stefan CJ, Blumer KJ (2003) A WASp homolog powers actin polymerization-dependent motility of endosomes in vivo. Curr Biol 13:455–463 Conradt D, Shaw J, Vida T, Emr S, Wickner W (1992) In vitro reactions of vacuole inheritance in Saccharomyces cerevisiae. J Cell Biol 119:1469–1479 Dabora SL, Sheetz MP (1988) The microtubule-dependent formation of a tubulovesicular network with characteristics of the ER from cultured cell extracts. Cell 54:27–35 Distel B, Erdmann R, Gould SJ, Blobel G, Crane DI, Cregg JM, Dodt G, Fujiki Y, Goodman JM, Just WW et al. (1996) A unified nomenclature for peroxisome biogenesis factors. J Cell Biol 135:1–3 Drees B, Brown C, Barrell BG, Bretscher A (1995) Tropomyosin is essential in yeast, yet the TPM1 and TPM2 proteins perform distinct functions. J Cell Biol 128:383–392 Drubin DG, Jones HD, Wertman KF (1993) Actin structure and function: roles in mitochondrial organization and morphogenesis in budding yeast and identification of the phalloidin-binding site. Mol Biol Cell 4:1277–1294 Du Y, Pypaert M, Novick P, Ferro-Novick S (2001) Aux1p/ Swa2p is required for cortical endoplasmic reticulum inheritance in Saccharomyces cerevisiae. Mol Biol Cell 12:2614–2628 Dunphy WG, Rothman JE (1985) Compartmental organization of the Golgi stack. Cell 42:13–21 Eckert JH, Erdmann R (2003) Peroxisome biogenesis. Rev Physiol Biochem Pharmacol 147:75–121 Efimov VP (2003) Roles of NUDE and NUDF proteins of Aspergillus nidulans: insights from intracellular localization and overexpression effects. Mol Biol Chem 14:871– 888 Organelle Inheritance in Fungi 33 Einerhand AW, van der Leij I, Kos WT, Distel B, Tabak HF (1992) Transcriptional regulation of genes encoding proteins involved in biogenesis of peroxisomes in Saccharomyces cerevisiae. Cell Biochem Funct 10:185–191 Eitzen G, Wang L, Thorngren N, Wickner W (2002) Remodeling of organelle-bound actin is required for yeast vacuole fusion. J Cell Biol 158:669–679 Engqvist-Goldstein AE, Drubin DG (2003) Actin assembly and endocytosis: from yeast to mammals. Annu Rev Cell Dev Biol 19:287–332 Erdmann R, Blobel G (1995) Giant peroxisomes in oleic acid-induced Saccharomycs cerevisiae lacking the peroxisomal membrane protein Pmp27p. J Cell Biol 128:509–523 Erdmann R, Veenhuis M, Kunau WH (1997) Peroxisomes: organelles at the crossroads. Trends Cell Biol 7:400–407 EstradaP,KimJ,ColemanJ,WalkerL,DunnB,TakizawaP, Novick P, Ferro-Novick S (2003) Myo4p and She3p are required for cortical ER inheritance in Saccharomyces cerevisiae. J Cell Biol 163:1255–1266 EvangelistaM,PruyneD,AmbergDC,BooneC,BretscherA (2002) Formins direct Arp2/3-independent actin filament assembly to polarize cell growth in yeast. Nat Cell Biol 4:260–269 Fehrenbacher KL, Davis D, Wu M, Boldogh I, Pon LA (2002) Endoplasmic reticulum dynamics, inheritance, and cytoskeletal interactions in budding yeast. Mol Cell Biol 13:854–865 Fehrenbacher KL, Bodogh IR, Pon LA (2003) Taking the Atrain: actin-based force generators and organelle targeting. Trends Cell Biol 13:472–477 Fehrenbacher KL, Yang HC, Gay AC, Huckaba TM, Pon LA (2004) Live cell imaging of mitochondrial movement along actin cables in budding yeast. Curr Biol 14:1996– 2004 GallWE,HigginbothamMA,ChenC,IngramMF,CyrDM, Graham TR (2000) The auxilin-like phosphoprotein Swa2p is required for clathrin function in yeast. Curr Biol 10:1349–1358 Graia F, Berteaux-Lecellier V, Zickler D, Picard M (2000) ami1, an orthologue of the Aspergillus nidulans apsA gene, is involved in nuclear migration throughout the life cycle of Podospora anserine. Genetics 155:633–646 Grote E, Carr CM, Novick PJ (2000) Ordering the final events in yeast exocytosis. J Cell Biol 151:439–452 GuoT,KitYY,NicaudJM,LeDallMT,SearsSK,ValiH, Chan H, Rachubinski RA, Titorenko VI (2003) Peroxisome division in the yeast Yarrowia lipolytica is regulated by a signal from inside the peroxisome. J Cell Biol 162:1255–1266 Hagan IM (1998) The fission yeast microtubule cytoskeleton. J Cell Sci 111:1603–1612 Han G, Liu B, Zhang J, Zuo W, Morris NR, Xiang X (2001) The Aspergillus cytoplasmic dynein heavy chain and NUDF localize to microtubule plus ends and affect microtubule dynamics. Curr Biol 11:719–724 Harris SD (2001) Septum formation in Aspergillus nidulans. Curr Opin Microbiol 4:736–739 Heath IB, Heath MC, Herr F (1982) Motile systems in fungi. Symp Soc Exp Biol 35:563–587 Hedge RS, Lingappa VR (1999) Regulation of protein biogenesis at the endoplasmic reticulum membrane. Trends Cell Biol 9:132–137
Page 2 and 3: The Mycota Edited by K. Esser
Page 4 and 5: The Mycota A Comprehensive Treatise
Page 6 and 7: Karl Esser (born 1924) is retired P
Page 8 and 9: VIII Series Preface Class: Saccharo
Page 10 and 11: Addendum to the Series Preface In e
Page 12 and 13: XIV Volume Preface to the First Edi
Page 14 and 15: XVI Volume Preface to the Second Ed
Page 16 and 17: XVIII Contents Reproductive Process
Page 18 and 19: XX List of Contributors André Flei
Page 20 and 21: Vegetative Processes and Growth
Page 22 and 23: 4 K.J. Boyce and A. Andrianopoulos
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Page 56 and 57: 38 S.D. Harris dle organization tha
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Page 60 and 61: 42 S.D. Harris terized in A. nidula
Page 62 and 63: 44 S.D. Harris astral microtubules
Page 64 and 65: 46 S.D. Harris entry, and the CDK N
Page 66 and 67: 48 S.D. Harris and Hamer 1997), the
Page 68 and 69: 50 S.D. Harris Murray AW (2004) Rec
Page 70 and 71: 4 Apical Wall Biogenesis J.H. Siets
Page 72 and 73: fungi can be regarded as “tube-dw
Page 74 and 75: In agreement with an essential role
Page 76 and 77: Kopecka and Gabriel 1992). They als
Page 78 and 79: nearly all the label was present in
Page 80 and 81: ingredients such as wall components
Page 82 and 83: in membrane enlargement and exocyto
Page 84 and 85: sis occurs, coinciding with a gradi
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Page 88 and 89: Sietsma JH, Wessels JGH (1977) Chem
Page 90 and 91: 5 The Fungal Cell Wall J.P. Latgé
Page 92 and 93: polymers (chitosan) and glucuronic
Page 94 and 95: Whereas the structural branched β1
Page 96 and 97: their structural role in the cell w
Page 98 and 99: 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
Page 194 and 195:
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,
Page 212 and 213:
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
Page 224 and 225:
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
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
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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
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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
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,
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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
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
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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
Page 418 and 419:
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
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
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observed when the mammal LE compone
Page 434 and 435:
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
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Rossignol J-L, Faugeron G (1995) MI
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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
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MAT protein interaction 308, 315 ma
Page 454:
sporangiophore 234, 242, 246-252, 2
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