Verfügbarkeit: Sex in fungi :: THWS Bibkatalog

Sex in fungi: molecular determination and evolutionary implications

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Bibliographische Detailangaben
Format:	Buch
Sprache:	English
Veröffentlicht:	Washington, D.C. ASM Press c2007
Schlagworte:	Evolution Fungi > Reproduction Fungi > genetics Fungi > physiology Genes, Mating Type, Fungal Reproduction, Asexual Sexualität Pilze Aufsatzsammlung
Online-Zugang:	Table of contents only Inhaltsverzeichnis
Beschreibung:	Includes index.
Beschreibung:	XXV, 542 S. Ill., graph. Darst.
ISBN:	1555814212

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MARC


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245	1	0	\|a Sex in fungi \|b molecular determination and evolutionary implications \|c edited by Joseph Heitman ... [et al.]
264		1	\|a Washington, D.C. \|b ASM Press \|c c2007
300			\|a XXV, 542 S. \|b Ill., graph. Darst.
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500			\|a Includes index.
650		4	\|a Evolution
650		4	\|a Fungi \|x Reproduction
650		4	\|a Fungi \|x genetics
650		4	\|a Fungi \|x physiology
650		4	\|a Genes, Mating Type, Fungal
650		4	\|a Reproduction, Asexual
650	0	7	\|a Sexualität \|0 (DE-588)4054684-6 \|2 gnd \|9 rswk-swf
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Datensatz im Suchindex

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adam_text	Contents Contributors ix Preface xv Dedication: ha Herskowitz xix Appreciation: John and Cardy Raper xxiii I. GENERAL PRINCIPLES 1 The Evolution of MAT: the Ascomycetes 3 Geraldine Butler 2 Evolution of the Mating-Type Locus: the Basidiomycetes 19 James A. Fräser, Yen-Ping Hsueh, Keisha M. Findlev, and Joseph Heitman 3 Mechanisms of Homothallism in Fungi and Transitions between Heterothallism and Homothallism 55 XlAORONG LlN AND JOSEPH HEITMAN 4 Mating-Type Locus Control of Cell Identity 59 Brynne C. Stanton and Christina M. Hui l 5 Rewiring Transcriptional Circuitry: Mating-Type Regulation in Saccharotnyces cerevisiae and Candida albicans as a Model for Evolution 75 Annie E. Tsong, Brian B. Tuch, and Alexander D. Johnson Contents II. ASCOMYCETES: FROM MODEL YEASTS TO PLANT AND HUMAN PATHOGENS 6 Cochliobolus and Podospora: Mechanisms of Sex Determination and the Evolution of Reproductive Lifestyle 93 B. GlLLIAN TURGEON AND ROBERT ÖEBUCHY 7 Sexual Reproduction and Significance of MAT in the Aspergilli 123 Paul S. Dyer 8 The mat Genes of Schizosaccharomyces pombe: Expression, Homothallic Switch, and Silencing 143 Olaf Nielsen and Richard Egel 9 Decisions, Decisions: Donor Preference during Budding Yeast Mating-Type Switching 159 James E. Haber 10 MAT and Its Role in the Homothallic Ascomycete Sordaria macrospora 171 Stefanie Pöggeler 11 Evolution of Silencing at the Mating-Type Loci in Hemiascomycetes 189 Laura N. Rusche and Meleah A. Hickman 12 The Evolutionary Implications of an Asexual Lifestyle Manifested by Penicillium marneffei 201 Matthew C. Fisher ffl. ASCOMYCETES: THE CANDIDA MAT LOCUS AND RELATED TOPICS 13 MAT, Mating, Switching, and Pathogenesis in Candida albicans, Candida dubliniensis, and Candida glabrata 215 David R. Soll and Karla J. Daniels 14 Evolution of MAT in the Candida Species Complex: Sex, Ploidy, and Complete Sexual Cycles in C. lusitaniae, C. guilliermondii, and C. krusei 235 Jennifer L. Reedy and Joseph Heitman 15 Ascomycetes: the Candida MAT Locus: Comparing MAT in the Genomes of Hemiascomycetous Yeasts 247 Heloise Muller, Christophe Hennequin, Bernard Dujon, AND CECILE FäIRHEAD IV. BASEDIOMYCETES: THE MUSHROOMS 16 Cloning the Mating-Type Genes of Schizophyllum commune: a Historical Perspective 267 Mary M. Stankis and Charles A. Specht 17 The Origin of Multiple Mating Types in the Model Mushrooms Coprinopsis cinerea and Schizophyllum commune 283 Lorna A. Casselton and Ursula Kües Contents vü 18 Pheromones and Pheromone Receptors in Schizophyllum commune Mate Recognition: Retrospective of a Half-Century of Progress and a Look Ahead 301 Thomas J. Fowler and Lisa J. Vaillancourt 19 Analysis of Mating-Type Locus Organization and Synteny in Mushroom Fungi: Beyond Model Species 317 Timothy Y. James 20 Dikaryons, Diploids, and Evolution 333 James B. Anderson and Linda M. Kohn V. BASIDIOMYCETES: PLANT AND ANIMAL PATHOGENIC YEASTS 21 History of the Mating Types in Ustilago maydis 351 Flora Banuett 22 Mating in the Smut Fungi: from a to b to the Downstream Cascades 377 Regine Kahmann and Jan Schirawski 23 Bipolar and Tetrapolar Mating Systems in the Ustilaginales 389 Guus Bakkeren and James W. Kronstad VI. ZYGOMYCETES, CHYTRIDIOMYCETES, AND OOMYCETES: THE FRONTIERS OF KNOWLEDGE 24 Sex in the Rest: Mysterious Mating in the Chytridiomycota and Zygomycota 407 Alexander Idnurm, Timothy Y. James, and Rytas Vilgalys 25 How the Genome Is Organized in the Glomeromycota 419 Teresa E. Pawlowska 26 Trisporic Acid and Mating in Zygomycetes 431 Johannes Wöstemeyer and Christine Schimek 27 Sexual Reproduction in Plant Pathogenic Oomycetes: Biology and Impact on Disease 445 Howard S. Judelson VII. THE IMPLICATIONS OF SEX 28 Origin, Evolution, and Extinction of Asexual Fungi: Experimental Tests Using Cryptococcus neoformans 461 JlANPING XU 29 Sex in Natural Populations of Cryptococcus gattii All Dee Carter, Nathan Saul, Leona Campbell, Tien Bui, and Mark Krockenberger 30 Why Bother with Sex? Answers from Experiments with Yeast and Other Organisms 489 Matthew R. Goddard viii Contents 31 Ploidy and the Sexual Yeast Genome in Theory, Nature, and Experiment 507 Clifford Zeyl 32 Why Sex Is Good: on Fungi and Beyond 527 Duur K. Aanen and Rolf F. Hoekstra Index 535 Index A Absidia glauca, 413. 434. 437, 438, 440 Adaptation, rates of. 520 Agancns bisporus var. bisporus, 46-47 Agaricus bisporus var. eurotetrasporus, 4 Agrucybe aegenta, 46 Atlomyces macrogynm, 409, 411,415 Allomyces sp.. 41(5-411 Alternaria jlternata, MAT locus of. 102-103 AMBM \| Amut Bmut) strains, of Coprtnellus anerea, 294-296 Amphimixis, 490 Arbuscular mycorrhizal (AM) fungi. see Giomeromycota Armillana A. gallua, 335-336 diploidy in. 343-344 Ascocbyta lentis, 98 Ascomycetes, see also specific species cell identity control, 60-66 dikaryon in. 333-335 evolution of MAT Candida species, 8-13 filamemous ascomycetes (Pezizomycotina), 13-15 HMG domain protein function, 10, 13 HO endonuclease gene, 7-8 Saccharotnyces lineage. ?-8 male and female functions, 334—335 MAT and genome compansons in hemiascomycetous yeasts, 247-261 MAT locus location, J-5 phylogenetic relationships, 4 sexual cycles, 39-46 heterothjllism diagram of, 36 heterothallic fungi with homothallic life cycles, 45-46 homorballism homothallic fungi with heterothallic life cycles, 45 primary, 41-45 pseudohomothallism, 39, 40 primary homothallism. 41—45 MAT absence, 44-45 one MAT idiomorph in genome, 43-44 two MAT idiomorphs in same genome, 41—43 Ascospore formation in Emericella niduhns, genetics of. 134 Asexual reproduction in Aspergillus spp., 135-138 in Candida albuans, 216 in Cryptococcus gattü, 4~9 in Dothidomycetes, 101-103 evolution of, 201-210 in Glomeromycota. 419—420 hypotheses about. 463 long-term costs of. 202 in Pemcühum marneffet. 20T-209 speed of. 529 Variation in, 462—463 vegetative firne« decrease in Cryptococcus neoformans. 470—4T3 Ashbya gossypü genome duplication. 520 homothallism, 44 MAT locus, 5. 6. 7, 8. 193 Sir proteins in, 192 Ashbya waltu. 250-256, 258 Aspergilliis asexualiry in. 135-138 evolution of homothallism and heterorhallism in. 138-139 HMG-domain genes. 15 MAT genes expression, 132 presence and distribution, 136-13 structure, 15, 131-132 sexual development, genetics of, 126-132 COP9 Signal. 131 cpcA. 12 cpcB, 12 DopA protein, 130 environmentai signal perception. 126-12 FpkA. 126 G-protein subumts, 128-129 isdA, 12 MAP kmase cascade. 129 MAT1 and MAT2, 131-132 MedA protein. 130 NosA prorein, 130-131 NsdD protein. 130 overview, 134-135 pheromone precursors PpgA/Pp%B , 127-128 pheromone receprors iPreA GprB and PreB/GprA). 128 phoA, 127 RosA protein, 1 ^0-131 Signal transducrion pathways, 12~-130 StuA protein. 130 transcriptton factors/regulatorv proteins, 130-132 YeA. 126-12 535 156 Index Aspergdhts {(.ontimwil) sexual development, morphology of, 124-125 sexual development, physiology of, 133-154 asfosporc production, 134 carbohydrate metabolism, 133 lipid metabolism, 133 overview, 1.34-135 oxidation state, 133-134 psi hormonal signaling, 133 taxonomy, 123-124 teleomorphs, 124 Aspergillus flai-its, I ^ -137 Aspergillus fumigatus asexuality and, 135-136 genome sequence data, 136 MAT genes, 135-139 transgenic /VLATstrain, 41 Aspergillus nidulans GprD receptor, 40 homothallism, 42, 43 outcrossing, 45 sexual cycle as a selection arena, 531 Aspergillus niger, 135-138 Aspergillus oryzae, 135-139 ,4X7./, in Saccharomyces cerevisiae, 76 B Basalfungi, 407-415 Chytridiomycota, 409-411 Dikarya compared, 414 importance of, 407-409 Microsporidia, 413 Zygomycota, 411-413, 431-141 Basidiomycetes, See also specific species cell identity control, 66-70 cost of sex, 529-530 dikaryon in, 333-335 life cycle, 20 male and female functions, 334-335 mating-type loci cloning, 318-319, 323-324 organization and synteny, 317-318 MAT (mating-type locus), evolution of, 19-32 Coprinellus disseminatus, 26 Coprinopsis cinerea, 24—25 Cryptococcus neoformans, 27-30 homeodomain locus, 22 Microbotryum violaceum, 27 multiallelic bipolar basidiomycetes, 26-27 pheromone/receptor locus, 21 Pholiata nameko, 26 recombination, 29-30, 31 Schizopbyllum cammune, 25—26 Sporisorium reiliamtm, 23-24, 25 tetrapolar maring System, 20, 22—23 transitions between heterothallic and homothallic cycles, 30—32 Ustilago hordei, 26—27 Vstilago maydis, 22—24 phylogeny, 318-319, 323-324 regularion of mating in, 20—21 sexual cycles heterothailic fungi with homothallic life cycles, 47-50 heterothallism, diagram of, 36 primary homothallism, 47 secondary homothallism, 46-47 Batrachachytrium dendrobatidis, 409, 410 Bensaude, Mathilde, 283 BGl.l ß-glucosidase gene, 96 Biotilm formation, by Candida albicans, 223-224,225 Bipolaris sacchari, MAT locus of, 101-103 Birth-and-death model, 423 Blakeslea trispora, 413, 434^(39 Blastocladiella variabilis, 411 Botryotinia fuckeliana, 108 Botrytis, MAT locus, 14 Bottlenecks, in Glomeromycota, 420—421 Bremia, 446, 449, 450 Buller phenomenon, 337-338, 345, 529 Camptothecin, 409 Candida CUG codon reassignment, 237 evolution of MAT locus, 8-13, 235-242 MTL locus structure in, 240-242 phylogeny, 235-237 teleomorphs, 237 Candida albicans Candida dubliniensis, in vitro mating with, 229 cell identity control, 62-64 centromere structure, 193-194 mating-type regulation, 79-87 asg regulon evolution, 85-87 regulatory circuit, 81-85 Saccbaromyces cerevisiae compared, 81-87 white-opaque switching and, 80-81, 82-83, 84-85 MAT locus, 79-80 MTL locus discovery of, 62, 216 evolution and structure of, 240-241 heterozygosity and virulence, 224-228 white-opaque switching and, 216-217, 222, 223 overview of mating in, 79-80 recombination, 215, 216 Saccharomyces cerevisiae compared, 216, 217,220-222 Sir proteins in, 192 white-opaque switching, 63-64, 80-81, 82-83,84-85,217-224 biofilm formation, 223-224, 225 featuresof, 218-219 reasons for, 222-223 temperarure and, 219-220 Candida dubliniensis Candida albicans, in vitro mating with, 229 switching and mating in, 228-229 Candida glabrata MAT and genome comparison in hemiascomycetes, 250-257 mating in, 230-231 AMT locus, 5, 6, 7, 8 Saccharomyces cerevisiae compared, 230-231,240 siiencing of mating-type loci, 194 Sir proteins in, 192, 194 Candida guilliermondii (teleomorph Pichia guilliermondü), 239-240, 241, 242 Candida knisei (teleomorph Issatchenkia orientalisIPichia kudriavzevii), 240 Candida lusitaniae (teleomorph Clavispora lusitaniae), 237-239, 241, 242 Candida parapsilosis, 215, 229-230, 241, 242, 258 Carbohydrate metabolism, in Emericella nidulans, 133 ß-Carotene, 434-436, 439 Cell identity, MAT locus and, 59-70 ascomycetes, 60-66 Candida albicans, 62—64 Cochliobolus heterostrophus, 64-65 Neurospora crassa, 65-66 Podospora anseria, 65 Saccharomyces cerevisiae, 60-61 Schizosaccharomyces pombe, 61-62 asidiomycetes Coprino cinerea, 66-68 Cryptococcus neoformans, 69-70 Ustilago maydis, 66, 67 basidiomycetes, 66-70 overview, 59-60 cenH, in Schizosaccharomyces pombe, 190 Ceratocystis coerulescens, 108 Chaetocladium brefeldi, 409 Chaetocladium jonesii, 434 Chimerism, in Glomeromycota formation, general principles of, 425 overview, 424—425 in parasexual cycle, 426 resource partitioning mechanisms, 425-426 vegetative, 426 Chlamydomonas reinhardtii, 496, 516 Choanephora cucurbitarum, 433,437—438 Chromocrea spinulosa, 107-108 Chromosomal rearrangements, 509 Chytridiomycetes diseases caused by, 409 sexual mechanisms, 409—411 Chytriomyces hyalinus, 410 cla4 gene, 320, 322-323, 325, 327 Clr4, in Schizosaccharomyces pombe, 190-191 Coccidioides, MAT locus, 14 Cochliobolus mating-type structure and function, 95-107 conserved motifs in MATl-1-1 and MAT1-2-1, 107 conversion self-compatible to self- incompatible, 105-107 conversion self-incompatible to self- compatible, 105 phylogenetic and structurai analyses, 104 self-compatible species, 99-101 self-incompatible species, 95-98 MAT locus evolution, 15 structure, 14, 15 primary homothallism, 42 reproductive biology of, 96 Sordaria compared, 174 transgenic MAT strains, 41 Cochliobolus carbonum, 97-98 Cochliobolus cymbopogonis, 99-101, 102 Index 537 Cochliobolus ellisii, 99-101 Cochliobolus heterostrophus cell identity control, 64-65 MAT locus, structure/organization of, 95-97, 99-101 transgenic studies with Cochliobolus luttrellii, 105-107 Cochliobolus homomorphus, 99-101, 102, 104 Cochliobolus kusanoi, 99-100, 102 Cochliobolus luttrellii, 99-101, 102, 104, 105-107 Cochliobolus victoriae, 97-98 Coelotnotnyces psorophorae, 411 Concerted evolution of rDNA, 423-424 Coniochaeta tetraspora, 107-108 Conjugation tube formation, Ustilago may- dis, 371-372 con mutation, in Schizophyllum conimune, 271 Coprinellus disseminatus, 26, 320, 321, 323-324 Coprinopsis cinerea cell identity control, 66-68 homeodomain locus, 22, 24—25 life cycle, 284-285 mating-type genes, 285—296 AMBM (Amut Bmut) strains, 294-296 cloningof, 318-319 comparison of sequenced, 288 evolution of, 291-293 mutations, 293-296, 324 organization of, 286, 287, 319, 321-324 overview, 285-288 pheromones-receptors, 290-292 origin of multiple mating types in, 283-296 pheromone/receptor Jocus, 21 segmental duplication and evolution of mating types in, 24-25 Coprinopsis scobicola, 319, 320 Coprinus cinereus homothallism in, 49-50 somatic recombination, 339 COP9 signalosome, in aspergilli, 131 Corn smut disease, 351 Cost of sex, 528-530 cpcA, in aspergilli, 127 cpcB, in aspergilli, 127 Crivellia C. papaveracea, 98 MAT locus phylogenetic and structural analyses, 105 structure, 101, 102 Crow, J. F., 491 Croziers, 95, 172, 173 Crypkonectria parasitica heterokaryons, 340-341 self-fertility, 108 Cryptococcus gattii, 477-486 cryptococcosis, 477-478, 484, 486 MLST (multilocus sequence typing), 481, 482, 484 phylogeny, 482-484 recombination, rnethods for detecting, 478 sexual reproducrion basidiospore formation, 478 clinical and veterinary populations, 482-483 environmental population with both mating types, 480 natural populations, 480, 486 Cryptococcus neoformans cell identity control, 69-70 fitness in asexual clones, 470-473 mating interaction, 466^70 mating-type loci organization and synteny, 322, 325 overview, 27-30 mating-type switching, 36, 47-49 mitochondrial inheritance, 326 as model System, 464 mtDNA transmission, 335 mutation accumulation, 464-466, 515-516 recombination hot spots, 341 sexual cycle of, 48 CsnD, in aspergilli, 131 CsnE, in aspergilli, 131 CUG codon reassignment, in Candida, 237 D Debaryomyces hansenü characteristics of, 250 MAT locus evolution, 9 structure, 10, 11, 193, 258, 260 phylogeny of, 8, 250 Sir proteins in, 192 Dicranophora fulva, 438 Didymella rabiei, 98 Didymella zeae-maydis, 101 4-Dihydromethyltrisporate dehydrogenase, 437, 440 4-Dihydrotrisporin dehydrogenase, 440 Dikarya basal fungi compared to, 407, 414 Glomeromycota compared, 426 Dikaryon in Ascomycota, 333-335 in Basidiomycota, 333—335 Buller phenomenon, 337-338 in Coprinellus cinerea, 284 Di-Mon (dikaryon-monokaryon) matings analysis of somatic recombinants, 338-339, 340 nuclear selection in, 338 patterns of somatic recombination, 339-341 evolution and, 343—345 iife cycle Variation, 343-344 long-term changes in, 342-343 male potential, 529 mitochondrial DNA and, 335-337 nuclear escape from, 337 nuclear reassociation, 337 overview of, 333-334 in Schizophyllum commune, 268-270, 284,302-303,312 somatic recombination in, 341—342 in Ustilago maydis, 359 Diploids adaptarion rate, 520 dikaryosis and, 343-344 evolution and, 343-345, 517 masking of deleterious mutations, 518-520 of oomycetes, 446 physiological effects of ploidy, 517-518 Ustilago maydis, 357, 370-372 Dispira americana, 409 DopA, in aspergilli, 130 Dothideomycetes, see also Cochliobolus het- erostrophus evolution of MAT, 12, 103-105 mating-type (MAT) locus structure, 12, 14 asexual species, 101-103 self-compatible species, 99-101 self-incomparible species, 98-99 Double-stranded break repair, in Saccha- romyces cerevisiae MAT switching, 161-163 Downy mildew of grape, 453^154 of sorghum, 454 Dynein moror proteins, 334 Effective population size estimating in fungi, 202-204 Penicillium marneffei, 206, 210 in Wright-Fisher model of evolution, 202 Emericella nidulans, see also Aspergillus nidnlans MAT locus, 131-132 sexual development genetics of, 126-132 morphology of, 124—125 overview of, 133-134 physiology of, 133-134 Emericella species, morphology of sexual development, 124 Encephalitozoon cuniculi, 415 Epistasis, 509-510 Eremothecium coryli, homothallism in, 44 Euascomycetes, postfertilization functions of mating-type genes in, 116 Eurotiomycetes, MAT locus in, 4, 12, 14 Eurotium species, morphology of sexual development, 124 Evolution asexual reproduction, 201-210 asg regulon, 85-87 concerted, 423-424 Glomeromycota, 419-424, 426^27 homothallism, mutations in A and B genes and, 293-294 homothallism and heterothallism in aspergilli, 138-139 horizontal transmission, role of, 515 maintenance of sex, 489-505 mating type in the Dothideomycetes, 103-105 mating-type locus (MAT) ascomycetes, 3—15 basidiomycetes, 19-32 Candida species complex, 235-242 complex, 291-293 silencing in Hemiascomycetes, 189-197 mating-type switching, 36, 38-39 merits of diploidy and dikaryosis, 344-345 of ploidy, 517 Scbiiosaccharoniyces pombe, 152-154 SIS Index Kvolutinn (C.ontinited) of scx, hmgal modeis and, 532 ot silencing at rhc m.uing-rype loci in Hcmiascomycetes, IK9-I97 l voiutionarv diit.iucc, between Ustilago hordei and Ustibiio maydis, 399-400 FadA, in aspergilli, I2X Filamentous ascomycetes, cell identity con- trol, 64-66 Hlnbasidiella dcpauperata, 49 Fishcr, R. A., 490-491 Fisher-Muller theory, 491, 492, 495 Fission yeast, see Schizosaccharomyces pombe Fkhl, in Saccharomyces cerevisiae, 165-166, 167 FMR I, in Podospora anserina, 109-1 15 FphA, in aspergilli, 126 FPRl, in Podospora anserina, 109-115 Frequency-dependent selection, 492-493 Fungal Trec of Life (AFTOL) projecr, 415 Generic drift, role in evolution of asexuality, 202 Getieftes o/ Sexuality in Higher tungi (Raper), 26 , 268, M3, 461 Genome duplication, 520-521 Gihberella species homothallism, 42 MAT locus, 15 Gilbertella persicaria, 438 Git3, in Scbizosaccharomyces pombe, 147 Glomerella species, MAT locus in, 14 Glomeromycota. 419-427 chimensm formation, general principles of, 425 overview, 424-425 in parasexual cycle, 426 resource partitioning mechanisins, 425-426 vegetative, 426 evolution and, 419-424, 426-427 multigenomic strueture, 424—426 muldnucleate spore srrueture, 426—427 phyiogeny of PLSI variants, 422 polymorphism, intraindividual, 420-421, 424 ribosomal DNA (rDNA), 420, 423-425 spores as Surrogate individuals in studies of, 419-420 Glomus caledonium, 423, 424 Clomus claroideum, 424 Glomus etunicatum, 421—422, 424 Glomus geosporwn, 422, 424 Glomus intraradices, 415, 421-422 Glomus mosseae, 424, 426 ß-Glucosidase gene, 99 Gpal, in Schizosaccharomyces pomhe, 147 GpgA, in aspergilli, 128 gprA, in aspergiili, 128 gprB, in aspergilii, 128 gprC, D, E. G, K genes, in aspergilli, 40, 129-130 Grape, downy müdew of, 453—454 H Hjploids, adaptation rate and, 520 Hi beloma crustuliniforme, 337 HF.Gs (homing endunuclease genes), 8 Hemiascomycetes evolution of silencing at macing-type loci, 189-197 MAT and genome comparisons, 247-261 conservation of synteny, 256 gene identification, 249-251 HO endonudease, 257-258 M/^Tand silenced cassettes, 251-257 multiple sequence alignments, 252-253 overvievv, 258-261 species with multiple MAT loci, 249-258 species with Single MAT locus, 258 phyiogeny of, 191 Heterobasidion annosum, 337 Heterochromatin, silencing of storage cas- settes in Schizosaccharomyces pombe, 151-152 Heterokaryosis chimerism and, 425 in Glomeromycota, 420—421 in parasexual cycle, 426 Heterothallic-homothallic transitions, see Mating-type switching Heterothallism defined, 35, 462 homothallism transition, 30—32, 35-53 in Mucorales, 411—412 oomycetes, 446, 447 recognition and karyogamy in ascomycetes, 94 in Schizosaccharomyces pombe, 145 Ustilago maydis, discovery in, 354 Heterozygosity, of MAT alleles, 518 HMG-domain proteins, 10, 13, 15 Ho endonuclease acquisition of gene, 7-8, 38 in hemiascomycetous yeasts, 257-258 in Saccharomyces cerevisiae, 37-38, 161-163,231,514 silencing of HML and HMR cassettes and, 37-38 Homeodomain locus, in basidiomycetes, 22 Homing endonuclease genes (HEGs), 8 Homobasidiomycetes cost of sex, 529-530 internuclear recognition in, 114 MAT loci organization, 324—325 Homokaryosis, in Glomeromycota, 420-421 Homothallism defined, 35, 462 heterothallism transition, 30-32, 35-51 mechanisms of, 35 in Mucorales, 411-412 mutations in A and ß genes and evolution of, 293-294 oomycetes, 446-448 outcrossing, 45 primary ascomycetes, 41-45 MAT absence, 44-45 one MAT idiomorph in genome, 43-44 tvvo MAT idiomorphs in same genome, 41-43 in basidiomycetes, 47 pseudohomothallism, 39, 40 recognition and karyogamy in ascomycetes, 94 Saccharomyces cerevisiae, 37-38, 514 secondary, 529-530 in ascomycetes, 39 in basidiomycetes, 46-47 overview, 39 Sordaria macrospora, 171-184 in Zygomycetes, 434 Hook cell formation, 334 Hstlp, in Saccharomyces cerevisiae, 196 Hydrophobins, 334 I Inbreeding, in natural yeast populations, 508-509 Internuclear recognition model, 112-114 Introns, 511-512, 515 Irpex lacteus, 320, 322-323 Isogamy, 528-529 K KAR4 gene, in Saccharomyces cerevisiae, 164-165 Kimura, xVL, 491 Kluyveromyces lactis asg (a-speeifie gene) regulation, 85 MAT and genome comparison in hemiascomycetes, 250-257 mating-type switching, 38, 195 MAT locus strueture, 5, 6, 7, 8 silencing of mating-type loci, 194—195 Sir proteins in, 192, 193, 195 Kluyveromyces thermotolerans, 249-256, 258 Kluyveromyces ivaltü characteristics of, 250 genome duplication, 520 HO gene absence, 258 mating-type locus, 193, 250-256 phyiogeny of, 250 sequence identity boxes, 255 Kniep, Hans, 283-284 Leotiomycetes, MAT locus in, 14 Leptosphaeria biglobosa, 98 Leptosphaeria maculans, 98 Linkage, of mating-type loci in mushroom fungi, 317-328 Linkage disequilibria, 528 Lipid metabolism, in Emericella nidulans, 133 Lodderomyces elongispoms, 45 Loss-of funetion mutations in mating-type loci, 202 isdA, in aspergilli, 127 M Magnaporthe grisea, MAT locus in, 5, 14 Male sterility, 336-337 MAPK, see Mitogen-activated protein kinase (MAPK) Index 539 Mating Inhibition factors (MIFs), in Ustilago hordei, 393 Mating-type-like (MTL) locus, in Candida albicans, 62-64, 216-217, 222-228, 240-241 Mating-type locus (MAT) locus Alternaria alternata, 102-103 in aspergilli, 131-132, 136-139 basdiomycetes cloning MAT genes, 318-319, 323-324 organization and synteny, 317-318 in Candida species complex, 8-13, 235-242 cell identity control, 59-70 ascomycetes, 60-66 basidiomycetes, 66—70 in hemiascomycetous yeast genomes, 247-261 Kluyveromyces lactis, 5, 6, 7, 8, 194-195 Kluyveromyces waltii, 193, 250-256 in Saccharomyces cerevisiae, 37-38, 76-78 in sexual Aspergillns spp., 136-139 in Ustilago hordei, 392^101 Mating-type locus (MAT) locus, evolution of ascomycetes Candida species, 8-13 filamentous ascomycetes (Pezizomycotina), 13-15 HMG domain protein function, 10, 13 HO endonuclease gene, 7-8 Saccharomyces lineage, 5—8 basidiomycetes, 19-32 Coprinellus disseminatus, 16 Coprinopsis einerea, 24-25 Cryptococcus neoformans, 27-30 homeodomain locus, 22 Microbotryum violaceum, 27 multiallelic bipolar basidiomycetes, 26-27 pheromone/reeeptor locus, 21 Pholiata nameko, 26 recombination, 29-30, 31 Schizophyllum commune, 25-26 Sporisorium reilianum, 23-24, 25 tetrapolar mating System, 20, 22-23 transitions between heterothaiiic and homothallic cycles, 30—32 Ustilago hordei, 26-17 Ustilago maydis, 22-24 Mating-type regulation Candida albicans, 79-87 evolution of, 75-76 Saccharomyces cerevisiae, 75-78 Mating-type switching in ascomycetes, 39—46 in basidiomycetes, 46-50 in Candida albicans, 63—64 cell identity control and, 61, 63-64 in Cryptococcus neoformans, 36, 47-49 in Kluyveromyces lactis, 195 in Saccharomyces cerevisiae, 36. 37-38, 78, 159-168 donor preference, genetic control of, 163-167 donor preference, microscopic analysis of, 167-168 gene conversion, 161-162 microscopic analysis of, 162-163 overview, 159-161 RE (recombinarion enhancer), 163-J67 in Saccharomyces lineage, 6-7 in Schizosaccharomyces pombe, 61, 145, 147-151 secondary homothallism, 39, 46-47 in Schizosaccharomyces pombe, 38-39 Maynard Smith, John, 491 Mcml in Candida albicans, 85 in Saccharomyces cerevisiae, 77-78, 165 in Sordaria macrospora homologue, 182-183 MedA, in aspergilli, 130 Mei2, in Schizosaccharomyces pombe, 147, 153 Mei3, in Schizosaccharomyces pombe, 147 Meiosis meiotic silencing by unpaired DNA (MSUD), 118 Ustilago maydis, 358-359 mib (metalloendopeptidase) gene, 319-321, 323,325-327 Microbotryum violaceum, 27, 47, 390-391, 398, 400 Microsporidia, sex in, 413 MIFs (mating inhibition factors), in Ustilago hordei, 393 Mitochondria basdiomycetes mating-type loci and, 326-327326 cytoplasmic mixing, 335-336 epistasis, 509-510 male sterility and, 336-337 mosaics, 336 recombination, 335—336 rejuvenation of, 531 slow movement in matings, 336 Mitogen-activated protein kinase (MAPK) in aspergilli, 129 in Schizosaccharomyces pombe, 146-147 in Ustilago maydis, 371-372, 377, 381-383 MLMT (multilocus microsatellite typing), of Penicillium marneffei, 205 MLST (multilocus sequence typing) of Cryptococcus gattii, 481, 482 of Penicillium marneffei, 204-205 Mortierella species, 413, 435 Motor proteins, dynein, 334 Mucorales mating in, 411-413 mycoparasitism, 409 trisporoid, 434-439 zygospore dormancy, lack of, 408 Mucor amphibiorum, 409 Mucor circinelloides, 415, 440 Mucor hiemalis. 438 Mucor mucedo, 409, 413, 415, 431-432, 434-435,437-440 Mucor piriformis, 409, 438 Mucor pusillus, 440 Muller s ratchet, 491-492 Multilocus genotyping, of Penicillium marneffei,204-205 Multilocus microsatellite typing (MLMT), of Penicillium marneffei, 205 Multilocus sequence typing (MLST) of Cryptococcus gattii, 481, 482 of Penicillium marneffei, 204-205 Mushroom fungi; see also Basidiomycetes; Homobasidiomycetes; speeifie species mating-type loci, organization and synteny of, i 17-328 Mutation aecumulation, 464-466, 515-516 Mutations evolution of asexualiry and, 202 in Glomeromycota, 420, 426^27 masking and purging deleterious, 518-520 Muller s ratchet, 491-492 Mutualistic symbiosis, 419 Mycosphaerella graminicola, 98 Mycosphaerella zeae-maydis, 101 Mycotypha africana, 432 N Natural selection, role in evolution of asexu- ality, 202 NEJ1, in Saccharomyces cerevisiae, 76 Nematospora coryli, homothallism in, 44 Neocallimastix sp., 410 Neosartorya species morphology of sexual development, 124 N. fischeri .AI, A3 Neurospora africana, 40-41, 44 Neurospora crassa cell identity control, 65-66 immunity to MSUD (meiotic silencing by unpaired DNA), 118 mating, 39-41 nucleus-restricted expression, 113 postfertilization funcrions of mating-type genes, 116 Sordaria macrospora cornpared, 171-177, 179-184 Neurospora terricola, 44 Neurospora tetrasperma, 171 NosA, in aspergilli, 130-131 Nosema locustae, 415 noxA gene, in Emericella nidulans, 133-134 NsdD, in aspergilli, 130 Nuclear migration into ascogenous hyphae, 112 internuclear recognition model, 112-114 random segregation model, 114—115 Buller phenomenon, 337-338 male srerility and, 336—337 motive force for, 334 Schizophyllum commune, 268, 269. 302, 304^305 Nucleolar Organizer regions (NORs), 423 o Oomycetes, 445-455 cytology of mating, 446-448 gene expression during mating, 450 genetic basis of mating behavior, 449-450 importance of, 445-446 mating hormones, 450 oospores disease transmission, role in, 451 germination of, 448 as survival struetures, 450-451 S40 Index Oomycetes, (Continued) pathology downy mildew of grape, 453-454 late blight of potato, 451-452 Phytophthora capsici blights, 452-453 Phytophthora sojae root and stem rot, 453 sorghum downy mildew, 454 taxonomy, 446 Oospores disease transmission, role in, 451 germination of, 448 as survival structures, 450 Orclp, 195-196 Outcrossing, in natural yeast populations, 508-509 Oxidation State and hyphal differentiation, 133-134 Oxysterol binding protein, in Candida albi- cans, 62, 63 pab (para-aminobenzoic acid) gene, 319, 321, 324, 340 Papazian, Haig, 284 Parasexual cycle, 426 Parasitella parasitica, 409, 413, 432, 434, 437, 440 Parasitic DNA coevolution and domestication of, 513-515 sex and, 510-513 Patl protein, in Schizosaccharomyces pombe, 148, 153 PCR, cloning MAT using direct amplifica- tion, 323-324 Penicillium marneffei biology of, 204 effective population size, 206, 210 evolutionary trajectory, 209—210 multilocus genotyping, 204-205 reproduction, 207-209 spatial components of genetic diversity, 205-206 Peronosclerospora sorghi, 454 Peronospora destructor, 451 Peronospora farinosa, 448 Petromyces species, morphoiogy of sexual development in, 124 Pezizomycotina, mating-type locus in, 13-15 Phaeosphaeria nodorum, 98 Phanerochaete chrysosporium, 320, 321-324, 327 Pheromone/receptor Systems in aspergilli, 127-128 in basidiomycetes, 21 Candida albicans, 84, 220-223 Chytridiomycetes, 411 Coprinellus ctnerea, 290—292 Coprinopsis cinerea, 66—68 Cryptococcus neofortnans, 69-70 Dikarya and basal fungi compared, 414 Mucorales, 413 Saccharomyces cerevisiae, 76, 301-302 Schizophyllum commune characterization of pheromones, 305-307 determinants of recognition by receptors, 307-309 discovery of, 304 gene nomenclature, 304 nuclear migration, role in, 304-305 number of, 286, 302 pheromone precursor sequences, 289, 290 role in B-regulated mating processes, 311-313 yeast studies, 309-310 Schizosaccharomyces pombe, 61-62, 146-148 signaling, in smut fungi, 381-383 Sordaria macrospora, 179-180 trisporic acid, 434-439 Ustilago maydis, 66, 67, 367-372 phoA, in aspergilli, 127 Pholiota natneko, 26, 324 Phosphatidyl inositol-3 kinase, in Candida albicans, 62, 63 Phycomyces blakesleeanus, 412-413, 415, 432-433, 435, 438-440 Phylogenetic tree of the fungal kingdom, 408 Phytophthora cactorum, 448 Phytophthora capsici, 452-453 Phytophthora infestans, 445, 447-452, 454 Phytophthora parasitica, 449 Phytophthora phaseoli, 450 Phytophthora sojae, 453 Phytophthora species, 445-447, 449-451 Pichia angusta, 250, 258, 260 Piromyces species, 415 PlasmidDNA, 510 Plasmopara, 446 Plasmopara viticola, 453 Pleurotus djamor, 320, 321-324 Ploidy, physiological effects of, 517-518 Pneumocystis carinii homothallism, 44 mating-type loci organization and synteny, 322 Podospora anserina cell identity control, 65 mating-type structure and function, 109-117 control of fertilization, 111 internuclear recognition model, 112-114 mating-type structure, 109 mutations, phenotype of, 110 nucleus migration into hyphae, 112 postfertilization developmental steps during fruiting-body formation, 109-111 postfertilization functions of mating- type genes, 116-117 random segregation model, 114-115 MAT locus Cochliobolus heterostrophus compared, 41 gene mutations, 109-111 structure/organization, 97, 109 pseudohomothallism, 171 senescence in, 531 Sordaria macrospora mating-type genes in, 176-178 Poly(A) polymerase, in Candida albicans, 62, 63 Polymorphism, intraindividual in Glomero- mycota, 420-421, 424 Polyphagus euglenae, 410 Population size, effective estimating in fungi, 202-204 Penicillium marneffei, 206, 210 in Wright-Fisher model of evolution, 202 Potato, late blight of, 451-452 ppgA, in aspergilli, 127-128 ppgB, in aspergilli, 128 ppgl/ppgZ, in Sordaria macrospora, 179-180,184 ppoA gene, 133 preß, in aspergilli, 128 prellprel, in Sordaria macrospora, 179-180, 184 Promoters, in Schizophyllum commune, 276 Pseudohomothallism, 39, 40, 171 Psi hormonal signaling, in Emericella nidu- lans, 133 Pyrenopeziza, 14 Pyrenopeziza brassicae, 98 Pyrenophora teres, 98 Pythium, 446^449 Pythium aphanidermatum, 448 R Radiomyces spectabilis, 410 Random drift, 493 Random segregation model, 114-115 Raper, Carlene (Cardy), 267, 272, 301, 310, 338 Raper, John, 267-268, 270-273, 276-278, 280,283,304,310,333,461 Raplp, in Saccharomyces cerevisiae, 189-190 Rasl, in Schizosaccharomyces pombe, 147 rDNA, concerted evolution of, 423-424 Receptors, see Pheromone/receptor Systems Recombination in basidiomycetes, 29-30, 31 evolution of MAT and, 29-30 mitochondrial DNA, 336 outcrossing, 508 Recombination enhancer (RE), in Saccha- romyces cerevisiae, 163-167 Red Queen hypothesis, 492-493 Regulation of mating-type Candida albicans, 79-87 evolution of, 75-76 Saccharomyces cerevisiae, 75-78 Retrotransposition, 512 Rhizopus oryzae, 415, 434, 440 Rhizopus sexualis, 438 Rhizopus stolonifer, 440 R1TS (RNA-induced transcriptional silenc- ing), 190 RME1, in Saccharomyces cerevisiae, 16 RosA, in aspergilti, 130-131 Ruml, in Schizosaccharomyces pombe, 146 Saccharomyces cerevisiae Candida albicans compared, 216, 217, 220-222 Candida glabrata compared, 230-231, 240 cell identity control, 60-61 ceil types, 76 centrornere structure, 193 chromosomal rearrangements, 509 genome duplication, 520-521 Index 541 Ho endonuclease, 514 life cycle, 497 maintenance of sex experiments, 497 mating-type regulation, 75-78 asg expression, 77-78 Candida albicans compared, 81-87 hsg expression, 78 mating-type switching, 78 regulatory circuit, 81, 82 asg expression, 78 transcriptional switching, 78 mating-type switching donor preference, genetic control of, 163-167 donor preference, microscopic analysis of, 167-168 gene conversion, 161-162 microscopic analysis of, 162-163 overview, 36, 37-38, 78, 159-161, 514 RE (recombination enhancer), 163-167 MAT oci evolution of, 514—515 MAT and genome comparison in hemiascomycetes, 250-257 mitochondria and, 326 pheromone-receptor System, 301-302 phylogeny, 191 regulation of mating type in, 247, 249 sexual cycle of an ho mutant of, 248 silencingin, 78, 189-190 spoll spol3 System, 500-503 whole genome duplication, 191 Saccharomyces kluyveri, 250, 258 Saccharomyces lineage, evolution of mating- type cassettes in, 5-8 Saccharomyces pastoriamts, 500 sakA, in Emericelia nidulans, 130 Schizophyllum commune A genes classical genetics studies, 302-304 doning oi Aa, 277-278 flanking genes and boundanes, 277 isolation of, 271-274 mutations, 271, 293 number of alleles, 270-271 overview, 270, 274 Promoter regions, 276 Y and Z gene products, 274-276 ß genes arrangement of, 305 classical genetics studies, 302-304 evolution of, 291 gene products, 304 isolation of, 278-280, 304 mutations, 271, 293, 294, 310-311, 324 number of alleles, 270-271, 286 overview, 270 pheromone signaling and, 311-313 recombination, 287-288 classical genetics studies, 302—304 flat phenotype, 284, 303 life cycle, 268-270, 284 mating process, 302 mating-type loci A genes, 270-278 B genes, 270-271, 278-280 doning of, 277-278, 318-319 discovery of, 283-284 historical perspective, 267-280 mutations, 271, 293, 294, 310-311, 324 organization and synteny of, 319, 321-322,324-325 Promoter regions, 276 origin of multiple mating types in, 283-296 overview, 25-26 pheromones/receptors characterization of pheromones, 305-307 determinants of recognition by receptors, 307-309 discovery of, 304 gene nomenclature, 304 nuclear migration, role in, 304-305 number of, 286, 302 pheromone precursor sequences, 289, 290 role in B-regulated mating processes, 311-313 yeast studies, 309-310 somatic recombination, 339-341 Schizosaccharomyces kambucha, 152 Schizosaccharomyces pombe cell identity control, 61-62 centromere structure, 193 evolution, 152-154 heterothallic strains, 145 homothallk switch, 147-148 life cycle, overview of, 143-144 mating-type switching, 145, 147-151 bias of donor cassette choice, 150-151 copy transposition from matlß to mall, 149-151 imprinting matl DNA, 148-149 overview, 38-39 silencing of storage cassettes mat2 and maxi, 151-152 mal region, organization of, 144-145 pheromone communication, 146-148 silencingin, 190-191 Sir proteins in, 192 transcriptional regulation, 145-146 Sclerotinia trifolium, 108 Scutellospora castanea, 423, 424-425 Scutellospora gregarta, 423 Scutellospora pellucida, 423, 424-425 SDSA (synthesis-dependent Strand anneal- mg), 161 Selection antagonism berween sexual and natural selection, 515-517 frequency-dependent, 492-493 natural selection role in evolution of asexuality, 202 Septoria passerinii, 98, 103 Sex Inducer genes, of Cryptococctis neofor- mans. 69-70 Sex (sexual reproduction) cost of, 201-202, 465-470, 528-530 epistasis and, 509-510 evolutionary implications of, 527-528, 5iZ ioss of, 464 maintenance of Crow and Kimura and, 491 experiments on, 494—505 Fisher and Muller, 490-491, 495 Maynard Smith and, 491 Mu ller s ratchet, 491^92 Red Queen hypothesis, 492^93 Weismann and, 490, 493 in natural populations in Cryptococcus gattii, 477-486 in natural yeast populations, 508-509 oomycetes, 445—455 parasitic DNA and, 510 quantitative nature of, 464 survival structure production, 531 Sexual fitness, 465 Sexual selection, antagonism with natural (vegetative) selection, 515-517 SfaD, in aspergilli, 128 Sikyospore, 434 Silencing of mating-type loci, 189-197 Candida glabrata, 194 comparative genomics of, 190-191, 192-194 evolution of silenced chromatin, 196-197 Kluyveromyces lactis, 194-195 overview, 189 Saccharomyces cerevisiae, 189-190 Schizosaccharomyces pombe, 190-191 Sir proteins, role of, 192-196 whole-genome duplication, impact of. 195-196 Silent mating cassettes defects in, 61 in Saccharomyces cerevisiae, 36. 37-38, 61, 78 in Saccharomyces lineage, 6-7 Sirenin, 411 Sir proteins functions of, 192-194, 195-196 hemiascomycetes phylogeny and, 191 in Saccharomyces cerevisiae, 37, 189-190 where they act, 193-194 Sistotrema brinkmannii, homothallism and, 47 SMIP gene, in Schizophyllum commune, 27 SMR1, in Podospora anserina, 109, 111, 113-114, 116-117 SMR2, in Podospora anserina. 109-115 Smut fungi bipolar and tetrapolar mating Systems, 389^01 mating-type loci evolutionary history, 400-401 functional analysis of, 393—394 future studies and quesrions, 400-401 genomic analysis, 396—398 Identification of, 392-393 organization of, 394-396 mating-type loci organization. 378-381 overview, 377-378. 390-391 pheromone-controlled signaling cascade, 381-385 phytopathogenesis, 389-390, 391, 398-400 Somatic recombination in dikaryons. 341—342 Di-Mon matings, 338-341 Sordaria brevtcollis, 45—46, 175 Sordarta fimicola, outcrossing of, 45 542 Index Sordaria macrospora, 171-184 lifecycle, 171-172, 173 mating-type genes into Podospora anserina, 41 mating-type locus fruiting-body development and, 176-179 interaction network of mating-type proteins, 181-184 mating-type-dependent gene expression, 179-181 pheromone/pheromone receptor System, 179-180 phylogenetic analysis, 174-175 SMTa-1, 177, 180-184 structure of, 172—174 transcriptional expression, 175 transgenic studies in Podospora anserina, 176-178 Mcml homologue, 182-183 Neurospora crassa compared, 171-177, 179-184 outcrossing, 45 phylogeny, 171 primary homothallism, 42 STE12 homologue, 183-184 Sordariomycetes, MAT locus in, 4, 12-15 Sorghum downy mildew, 454 SPB1 gene, in Saccharomyces cerevisiae, 164-165 Spore trapping, 335 Sporisorium reilianum, 23-24, 25, 370, 378-380 spoll spol3 system, 500-503 STE2, in Saccharomyces cerevisiae, 76 STE3 in Candida albicans, 83 homologs in basidiomycetes, 322—324 in Saccharomyces cerevisiae, 76 Stel 1, in Schizosaccharomyces pombe, 145-147 STE12 in Candida albicans, 84 in Cryptococcus and Pneumocystis, 322 in Saccharomyces cerevisiae, 77, 84 Sordaria macrospora homologue, 183-184 Stemphylium MAT locus phylogenetic and structural analyses, 104-105 structure, 101, 102, 103 primary homothallism, 42 Sordaria compared, 174 Stml, in Schizosaccharomyces pombe, 147 StuA, in aspergilli, 130 Suml, in Saccharomyces cerevisiae, 196 Swi4/6, in Saccharomyces cerevisiae. 165-166,167 Swi6, in Schizosaccharomyces pombe, 190-191 Swi5-Swi2, in Schizosaccharomyces pombe, 151 Symbiosis, mutualistic, 419 Synteny, of mating-type loci in mushroom fungi, 317-328 Synthesis-dependent Strand annealing (SDSA), 161 Syzigites megalocarpus, 438 TALE (three-amino-acid loop extension) homeobox, in Schizophyllum com- mune, 276, 277 Telomeric silencing, 38, 190, 193 Tetrapolar mating Systems, 20, 22-23, 317-318 Thamnidium elegans, 438 TOS9, in Candida albicans, 218-220 Transcriptional regulatory circuit Candida albicans, 79-87 evolution of, 75-76 Saccharomyces cerevisiae, 75-78 Transposable elements MAT loci and, 400 as parasitic DNA, 512-514 Trisporic acid biosynthesis pathway, 436 diversity in signaling by, 435 overview, 413, 434—435 physiological aspects of signaling, 437-439 tspl gene, 437, 440 tspl gene, 440 Tvvofold cost of sex, 528 Ty elements, 512-514 u Ustilaginales, bipolar and tetrapolar mating Systems in, 389^01 Ustilago hordei evolution, 26—27 mating-type loci, 378-381 functional analysis of, 393-394 genomic analysis, 396—398 identification of, 392-393 organization of, 394-396 sex chromosomes, 399, 400 transposable elements, 400 overview, 390 pathogenesis of, 391 Ustilago maydis compared, 399-401 Ustilago maydis, 351-372 a locus, 367-372 cloning and molecular genetic analysis, 367-372 organization and functional/ evolutionary implications, 378-381 overview, 355-357 b locus, 358-367 bmut alleles, 358-359, 365 cloning and molecular genetic analysis, 359-367 meiosis, role in, 358—359 organization and functional/evolutionary implications, 378-381 overview, 355-356 cell identity control, 66, 67 evolutionary distance from Ustilago hordei , 399-400 general features, 351-352 genomic analysis of mating System, 396-398 heterothallism, 354 homeodomain locus, 22-23 life cycle, 352 mating incompatibility, genetic basis of, 355-357 MAT loci mitochondria and, 326 nomenclature, 21, 22 pheromone-controlled signaling cascade bE/bW heterodimer, targets of, 383-385 components, 22—23, 381 genes and processes controlled by, 381-383 sexual/pathogenic development, 383-385 repetitive DNA, 399, 400 segregation analysis, 353-354 sex factors, 354-355 Sporisorium reilianum compared, 23-24 sterility factor, 355 V VDE, 515 VeA, in aspergilli, 126-127 Vegetative chimerism, 426 Vegetative fitness, 470-473 Vegetative (natural) selection, antagonism with sexual selection, 515-517 Virus, transmission via spores, 531-532 w Weismann, August, 489, 490, 493 White-opaque switching in Candida albicans, 80-81, 82-83, 84-85 Williams, G. C, 493 WOR1, in Candida albicans, 82-83, 85, 218-220 Wright-Fisher model of evolution, 202 Yarrowia lipolytica, 61, 193, 250, 258, 260 Zygomycetes, 431-441 diseases caused by, 431, 434 genetics of sexual differentiation, 439—441 mating-type System, 434 sexual mechanisms in, 411—413 sexual morphogenesis, 431^433 trisporic acid biosynthesis pathway, 436 diversity in signaling by, 435 overview, 434-435 physiological aspects of signaling, 437-439 Zygorhizidium planktonicum, 410, 411 Zygorhynchus heterogamus, 435, 437 Zygorhynchus macrocarpus, 438 Zygorhynchus moelleri, 435, 438 Zygorhynchus species, 434 Zygosaccharomyces rouxii, 249—256, 257 Zygotropism, 432
adam_txt	Contents Contributors ix Preface xv Dedication: ha Herskowitz xix Appreciation: John and Cardy Raper xxiii I. GENERAL PRINCIPLES 1 The Evolution of MAT: the Ascomycetes 3 Geraldine Butler 2 Evolution of the Mating-Type Locus: the Basidiomycetes 19 James A. Fräser, Yen-Ping Hsueh, Keisha M. Findlev, and Joseph Heitman 3 Mechanisms of Homothallism in Fungi and Transitions between Heterothallism and Homothallism 55 XlAORONG LlN AND JOSEPH HEITMAN 4 Mating-Type Locus Control of Cell Identity 59 Brynne C. Stanton and Christina M. Hui l 5 Rewiring Transcriptional Circuitry: Mating-Type Regulation in Saccharotnyces cerevisiae and Candida albicans as a Model for Evolution 75 Annie E. Tsong, Brian B. Tuch, and Alexander D. Johnson Contents II. ASCOMYCETES: FROM MODEL YEASTS TO PLANT AND HUMAN PATHOGENS 6 Cochliobolus and Podospora: Mechanisms of Sex Determination and the Evolution of Reproductive Lifestyle 93 B. GlLLIAN TURGEON AND ROBERT ÖEBUCHY 7 Sexual Reproduction and Significance of MAT in the Aspergilli 123 Paul S. Dyer 8 The mat Genes of Schizosaccharomyces pombe: Expression, Homothallic Switch, and Silencing 143 Olaf Nielsen and Richard Egel 9 Decisions, Decisions: Donor Preference during Budding Yeast Mating-Type Switching 159 James E. Haber 10 MAT and Its Role in the Homothallic Ascomycete Sordaria macrospora 171 Stefanie Pöggeler 11 Evolution of Silencing at the Mating-Type Loci in Hemiascomycetes 189 Laura N. Rusche and Meleah A. Hickman 12 The Evolutionary Implications of an Asexual Lifestyle Manifested by Penicillium marneffei 201 Matthew C. Fisher ffl. ASCOMYCETES: THE CANDIDA MAT LOCUS AND RELATED TOPICS 13 MAT, Mating, Switching, and Pathogenesis in Candida albicans, Candida dubliniensis, and Candida glabrata 215 David R. Soll and Karla J. Daniels 14 Evolution of MAT in the Candida Species Complex: Sex, Ploidy, and Complete Sexual Cycles in C. lusitaniae, C. guilliermondii, and C. krusei 235 Jennifer L. Reedy and Joseph Heitman 15 Ascomycetes: the Candida MAT Locus: Comparing MAT in the Genomes of Hemiascomycetous Yeasts 247 Heloise Muller, Christophe Hennequin, Bernard Dujon, AND CECILE FäIRHEAD IV. BASEDIOMYCETES: THE MUSHROOMS 16 Cloning the Mating-Type Genes of Schizophyllum commune: a Historical Perspective 267 Mary M. Stankis and Charles A. Specht 17 The Origin of Multiple Mating Types in the Model Mushrooms Coprinopsis cinerea and Schizophyllum commune 283 Lorna A. Casselton and Ursula Kües Contents vü 18 Pheromones and Pheromone Receptors in Schizophyllum commune Mate Recognition: Retrospective of a Half-Century of Progress and a Look Ahead 301 Thomas J. Fowler and Lisa J. Vaillancourt 19 Analysis of Mating-Type Locus Organization and Synteny in Mushroom Fungi: Beyond Model Species 317 Timothy Y. James 20 Dikaryons, Diploids, and Evolution 333 James B. Anderson and Linda M. Kohn V. BASIDIOMYCETES: PLANT AND ANIMAL PATHOGENIC YEASTS 21 History of the Mating Types in Ustilago maydis 351 Flora Banuett 22 Mating in the Smut Fungi: from a to b to the Downstream Cascades 377 Regine Kahmann and Jan Schirawski 23 Bipolar and Tetrapolar Mating Systems in the Ustilaginales 389 Guus Bakkeren and James W. Kronstad VI. ZYGOMYCETES, CHYTRIDIOMYCETES, AND OOMYCETES: THE FRONTIERS OF KNOWLEDGE 24 Sex in the Rest: Mysterious Mating in the Chytridiomycota and Zygomycota 407 Alexander Idnurm, Timothy Y. James, and Rytas Vilgalys 25 How the Genome Is Organized in the Glomeromycota 419 Teresa E. Pawlowska 26 Trisporic Acid and Mating in Zygomycetes 431 Johannes Wöstemeyer and Christine Schimek 27 Sexual Reproduction in Plant Pathogenic Oomycetes: Biology and Impact on Disease 445 Howard S. Judelson VII. THE IMPLICATIONS OF SEX 28 Origin, Evolution, and Extinction of Asexual Fungi: Experimental Tests Using Cryptococcus neoformans 461 JlANPING XU 29 Sex in Natural Populations of Cryptococcus gattii All Dee Carter, Nathan Saul, Leona Campbell, Tien Bui, and Mark Krockenberger 30 Why Bother with Sex? Answers from Experiments with Yeast and Other Organisms 489 Matthew R. Goddard viii Contents 31 Ploidy and the Sexual Yeast Genome in Theory, Nature, and Experiment 507 Clifford Zeyl 32 Why Sex Is Good: on Fungi and Beyond 527 Duur K. Aanen and Rolf F. Hoekstra Index 535 Index A Absidia glauca, 413. 434. 437, 438, 440 Adaptation, rates of. 520 Agancns bisporus var. bisporus, 46-47 Agaricus bisporus var. eurotetrasporus, 4" Agrucybe aegenta, 46 Atlomyces macrogynm, 409, 411,415 Allomyces sp. 41(5-411 Alternaria jlternata, MAT locus of. 102-103 AMBM \| Amut Bmut) strains, of Coprtnellus anerea, 294-296 Amphimixis, 490 Arbuscular mycorrhizal (AM) fungi. see Giomeromycota Armillana A. gallua, 335-336 diploidy in. 343-344 Ascocbyta lentis, 98 Ascomycetes, see also specific species cell identity control, 60-66 dikaryon in. 333-335 evolution of MAT Candida species, 8-13 filamemous ascomycetes (Pezizomycotina), 13-15 HMG domain protein function, 10, 13 HO endonuclease gene, 7-8 Saccharotnyces lineage. ?-8 male and female functions, 334—335 MAT and genome compansons in hemiascomycetous yeasts, 247-261 MAT locus location, J-5 phylogenetic relationships, 4 sexual cycles, 39-46 heterothjllism diagram of, 36 heterothallic fungi with homothallic life cycles, 45-46 homorballism homothallic fungi with heterothallic life cycles, 45 primary, 41-45 pseudohomothallism, 39, 40 primary homothallism. 41—45 MAT absence, 44-45 one MAT idiomorph in genome, 43-44 two MAT idiomorphs in same genome, 41—43 Ascospore formation in Emericella niduhns, genetics of. 134 Asexual reproduction in Aspergillus spp., 135-138 in Candida albuans, 216 in Cryptococcus gattü, 4~9 in Dothidomycetes, 101-103 evolution of, 201-210 in Glomeromycota. 419—420 hypotheses about. 463 long-term costs of. 202 in Pemcühum marneffet. 20T-209 speed of. 529 Variation in, 462—463 vegetative firne« decrease in Cryptococcus neoformans. 470—4T3 Ashbya gossypü genome duplication. 520 homothallism, 44 MAT locus, 5. 6. 7, 8. 193 Sir proteins in, 192 Ashbya waltu. 250-256, 258 Aspergilliis asexualiry in. 135-138 evolution of homothallism and heterorhallism in. 138-139 HMG-domain genes. 15 MAT genes expression, 132 presence and distribution, 136-13" structure, 15, 131-132 sexual development, genetics of, 126-132 COP9 Signal. 131 cpcA. 12" cpcB, 12" DopA protein, 130 environmentai signal perception. 126-12" FpkA. 126 G-protein subumts, 128-129 isdA, 12" MAP kmase cascade. 129 MAT1 and MAT2, 131-132 MedA protein. 130 NosA prorein, 130-131 NsdD protein. 130 overview, 134-135 pheromone precursors \PpgA/Pp%B , 127-128 pheromone receprors iPreA'GprB and PreB/GprA). 128 phoA, 127 RosA protein, 1 ^0-131 Signal transducrion pathways, 12~-130 StuA protein. 130 transcriptton factors/regulatorv proteins, 130-132 YeA. 126-12" 535 156 Index Aspergdhts {(.ontimwil) sexual development, morphology of, 124-125 sexual development, physiology of, 133-154 asfosporc production, 134 carbohydrate metabolism, 133 lipid metabolism, 133 overview, 1.34-135 oxidation state, 133-134 psi hormonal signaling, 133 taxonomy, 123-124 teleomorphs, 124 Aspergillus flai-its, I ^ -137 Aspergillus fumigatus asexuality and, 135-136 genome sequence data, 136 MAT genes, 135-139 transgenic /VLATstrain, 41 Aspergillus nidulans GprD receptor, 40 homothallism, 42, 43 outcrossing, 45 sexual cycle as a selection arena, 531 Aspergillus niger, 135-138 Aspergillus oryzae, 135-139 ,4X7./, in Saccharomyces cerevisiae, 76 B Basalfungi, 407-415 Chytridiomycota, 409-411 Dikarya compared, 414 importance of, 407-409 Microsporidia, 413 Zygomycota, 411-413, 431-141 Basidiomycetes, See also specific species cell identity control, 66-70 cost of sex, 529-530 dikaryon in, 333-335 life cycle, 20 male and female functions, 334-335 mating-type loci cloning, 318-319, 323-324 organization and synteny, 317-318 MAT (mating-type locus), evolution of, 19-32 Coprinellus disseminatus, 26 Coprinopsis cinerea, 24—25 Cryptococcus neoformans, 27-30 homeodomain locus, 22 Microbotryum violaceum, 27 multiallelic bipolar basidiomycetes, 26-27 pheromone/receptor locus, 21 Pholiata nameko, 26 recombination, 29-30, 31 Schizopbyllum cammune, 25—26 Sporisorium reiliamtm, 23-24, 25 tetrapolar maring System, 20, 22—23 transitions between heterothallic and homothallic cycles, 30—32 Ustilago hordei, 26—27 Vstilago maydis, 22—24 phylogeny, 318-319, 323-324 regularion of mating in, 20—21 sexual cycles heterothailic fungi with homothallic life cycles, 47-50 heterothallism, diagram of, 36 primary homothallism, 47 secondary homothallism, 46-47 Batrachachytrium dendrobatidis, 409, 410 Bensaude, Mathilde, 283 BGl.l ß-glucosidase gene, 96 Biotilm formation, by Candida albicans, 223-224,225 Bipolaris sacchari, MAT locus of, 101-103 Birth-and-death model, 423 Blakeslea trispora, 413, 434^(39 Blastocladiella variabilis, 411 Botryotinia fuckeliana, 108 Botrytis, MAT locus, 14 Bottlenecks, in Glomeromycota, 420—421 Bremia, 446, 449, 450 Buller phenomenon, 337-338, 345, 529 Camptothecin, 409 Candida CUG codon reassignment, 237 evolution of MAT locus, 8-13, 235-242 MTL locus structure in, 240-242 phylogeny, 235-237 teleomorphs, 237 Candida albicans Candida dubliniensis, in vitro mating with, 229 cell identity control, 62-64 centromere structure, 193-194 mating-type regulation, 79-87 asg regulon evolution, 85-87 regulatory circuit, 81-85 Saccbaromyces cerevisiae compared, 81-87 white-opaque switching and, 80-81, 82-83, 84-85 MAT locus, 79-80 MTL locus discovery of, 62, 216 evolution and structure of, 240-241 heterozygosity and virulence, 224-228 white-opaque switching and, 216-217, 222, 223 overview of mating in, 79-80 recombination, 215, 216 Saccharomyces cerevisiae compared, 216, 217,220-222 Sir proteins in, 192 white-opaque switching, 63-64, 80-81, 82-83,84-85,217-224 biofilm formation, 223-224, 225 featuresof, 218-219 reasons for, 222-223 temperarure and, 219-220 Candida dubliniensis Candida albicans, in vitro mating with, 229 switching and mating in, 228-229 Candida glabrata MAT and genome comparison in hemiascomycetes, 250-257 mating in, 230-231 AMT locus, 5, 6, 7, 8 Saccharomyces cerevisiae compared, 230-231,240 siiencing of mating-type loci, 194 Sir proteins in, 192, 194 Candida guilliermondii (teleomorph Pichia guilliermondü), 239-240, 241, 242 Candida knisei (teleomorph Issatchenkia orientalisIPichia kudriavzevii), 240 Candida lusitaniae (teleomorph Clavispora lusitaniae), 237-239, 241, 242 Candida parapsilosis, 215, 229-230, 241, 242, 258 Carbohydrate metabolism, in Emericella nidulans, 133 ß-Carotene, 434-436, 439 Cell identity, MAT locus and, 59-70 ascomycetes, 60-66 Candida albicans, 62—64 Cochliobolus heterostrophus, 64-65 Neurospora crassa, 65-66 Podospora anseria, 65 Saccharomyces cerevisiae, 60-61 Schizosaccharomyces pombe, 61-62 asidiomycetes Coprino cinerea, 66-68 Cryptococcus neoformans, 69-70 Ustilago maydis, 66, 67 basidiomycetes, 66-70 overview, 59-60 cenH, in Schizosaccharomyces pombe, 190 Ceratocystis coerulescens, 108 Chaetocladium brefeldi, 409 Chaetocladium jonesii, 434 Chimerism, in Glomeromycota formation, general principles of, 425 overview, 424—425 in parasexual cycle, 426 resource partitioning mechanisms, 425-426 vegetative, 426 Chlamydomonas reinhardtii, 496, 516 Choanephora cucurbitarum, 433,437—438 Chromocrea spinulosa, 107-108 Chromosomal rearrangements, 509 Chytridiomycetes diseases caused by, 409 sexual mechanisms, 409—411 Chytriomyces hyalinus, 410 cla4 gene, 320, 322-323, 325, 327 Clr4, in Schizosaccharomyces pombe, 190-191 Coccidioides, MAT locus, 14 Cochliobolus mating-type structure and function, 95-107 conserved motifs in MATl-1-1 and MAT1-2-1, 107 conversion self-compatible to self- incompatible, 105-107 conversion self-incompatible to self- compatible, 105 phylogenetic and structurai analyses, 104 self-compatible species, 99-101 self-incompatible species, 95-98 MAT locus evolution, 15 structure, 14, 15 primary homothallism, 42 reproductive biology of, 96 Sordaria compared, 174 transgenic MAT strains, 41 Cochliobolus carbonum, 97-98 Cochliobolus cymbopogonis, 99-101, 102 Index 537 Cochliobolus ellisii, 99-101 Cochliobolus heterostrophus cell identity control, 64-65 MAT locus, structure/organization of, 95-97, 99-101 transgenic studies with Cochliobolus luttrellii, 105-107 Cochliobolus homomorphus, 99-101, 102, 104 Cochliobolus kusanoi, 99-100, 102 Cochliobolus luttrellii, 99-101, 102, 104, 105-107 Cochliobolus victoriae, 97-98 Coelotnotnyces psorophorae, 411 Concerted evolution of rDNA, 423-424 Coniochaeta tetraspora, 107-108 Conjugation tube formation, Ustilago may- dis, 371-372 con mutation, in Schizophyllum conimune, 271 Coprinellus disseminatus, 26, 320, 321, 323-324 Coprinopsis cinerea cell identity control, 66-68 homeodomain locus, 22, 24—25 life cycle, 284-285 mating-type genes, 285—296 AMBM (Amut Bmut) strains, 294-296 cloningof, 318-319 comparison of sequenced, 288 evolution of, 291-293 mutations, 293-296, 324 organization of, 286, 287, 319, 321-324 overview, 285-288 pheromones-receptors, 290-292 origin of multiple mating types in, 283-296 pheromone/receptor Jocus, 21 segmental duplication and evolution of mating types in, 24-25 Coprinopsis scobicola, 319, 320 Coprinus cinereus homothallism in, 49-50 somatic recombination, 339 COP9 signalosome, in aspergilli, 131 Corn smut disease, 351 Cost of sex, 528-530 cpcA, in aspergilli, 127 cpcB, in aspergilli, 127 Crivellia C. papaveracea, 98 MAT locus phylogenetic and structural analyses, 105 structure, 101, 102 Crow, J. F., 491 Croziers, 95, 172, 173 Crypkonectria parasitica heterokaryons, 340-341 self-fertility, 108 Cryptococcus gattii, 477-486 cryptococcosis, 477-478, 484, 486 MLST (multilocus sequence typing), 481, 482, 484 phylogeny, 482-484 recombination, rnethods for detecting, 478 sexual reproducrion basidiospore formation, 478 clinical and veterinary populations, 482-483 environmental population with both mating types, 480 natural populations, 480, 486 Cryptococcus neoformans cell identity control, 69-70 fitness in asexual clones, 470-473 mating interaction, 466^70 mating-type loci organization and synteny, 322, 325 overview, 27-30 mating-type switching, 36, 47-49 mitochondrial inheritance, 326 as model System, 464 mtDNA transmission, 335 mutation accumulation, 464-466, 515-516 recombination hot spots, 341 sexual cycle of, 48 CsnD, in aspergilli, 131 CsnE, in aspergilli, 131 CUG codon reassignment, in Candida, 237 D Debaryomyces hansenü characteristics of, 250 MAT locus evolution, 9 structure, 10, 11, 193, 258, 260 phylogeny of, 8, 250 Sir proteins in, 192 Dicranophora fulva, 438 Didymella rabiei, 98 Didymella zeae-maydis, 101 4-Dihydromethyltrisporate dehydrogenase, 437, 440 4-Dihydrotrisporin dehydrogenase, 440 Dikarya basal fungi compared to, 407, 414 Glomeromycota compared, 426 Dikaryon in Ascomycota, 333-335 in Basidiomycota, 333—335 Buller phenomenon, 337-338 in Coprinellus cinerea, 284 Di-Mon (dikaryon-monokaryon) matings analysis of somatic recombinants, 338-339, 340 nuclear selection in, 338 patterns of somatic recombination, 339-341 evolution and, 343—345 iife cycle Variation, 343-344 long-term changes in, 342-343 male potential, 529 mitochondrial DNA and, 335-337 nuclear escape from, 337 nuclear reassociation, 337 overview of, 333-334 in Schizophyllum commune, 268-270, 284,302-303,312 somatic recombination in, 341—342 in Ustilago maydis, 359 Diploids adaptarion rate, 520 dikaryosis and, 343-344 evolution and, 343-345, 517 masking of deleterious mutations, 518-520 of oomycetes, 446 physiological effects of ploidy, 517-518 Ustilago maydis, 357, 370-372 Dispira americana, 409 DopA, in aspergilli, 130 Dothideomycetes, see also Cochliobolus het- erostrophus evolution of MAT, 12, 103-105 mating-type (MAT) locus structure, 12, 14 asexual species, 101-103 self-compatible species, 99-101 self-incomparible species, 98-99 Double-stranded break repair, in Saccha- romyces cerevisiae MAT switching, 161-163 Downy mildew of grape, 453^154 of sorghum, 454 Dynein moror proteins, 334 Effective population size estimating in fungi, 202-204 Penicillium marneffei, 206, 210 in Wright-Fisher model of evolution, 202 Emericella nidulans, see also Aspergillus nidnlans MAT locus, 131-132 sexual development genetics of, 126-132 morphology of, 124—125 overview of, 133-134 physiology of, 133-134 Emericella species, morphology of sexual development, 124 Encephalitozoon cuniculi, 415 Epistasis, 509-510 Eremothecium coryli, homothallism in, 44 Euascomycetes, postfertilization functions of mating-type genes in, 116 Eurotiomycetes, MAT locus in, 4, 12, 14 Eurotium species, morphology of sexual development, 124 Evolution asexual reproduction, 201-210 asg regulon, 85-87 concerted, 423-424 Glomeromycota, 419-424, 426^27 homothallism, mutations in A and B genes and, 293-294 homothallism and heterothallism in aspergilli, 138-139 horizontal transmission, role of, 515 maintenance of sex, 489-505 mating type in the Dothideomycetes, 103-105 mating-type locus (MAT) ascomycetes, 3—15 basidiomycetes, 19-32 Candida species complex, 235-242 complex, 291-293 silencing in Hemiascomycetes, 189-197 mating-type switching, 36, 38-39 merits of diploidy and dikaryosis, 344-345 of ploidy, 517 Scbiiosaccharoniyces pombe, 152-154 SIS Index Kvolutinn (C.ontinited) of scx, hmgal modeis and, 532 ot silencing at rhc m.uing-rype loci in Hcmiascomycetes, IK9-I97 l'voiutionarv diit.iucc, between Ustilago hordei and Ustibiio maydis, 399-400 FadA, in aspergilli, I2X Filamentous ascomycetes, cell identity con- trol, 64-66 Hlnbasidiella dcpauperata, 49 Fishcr, R. A., 490-491 Fisher-Muller theory, 491, 492, 495 Fission yeast, see Schizosaccharomyces pombe Fkhl, in Saccharomyces cerevisiae, 165-166, 167 FMR I, in Podospora anserina, 109-1 15 FphA, in aspergilli, 126 FPRl, in Podospora anserina, 109-115 Frequency-dependent selection, 492-493 Fungal Trec of Life (AFTOL) projecr, 415 Generic" drift, role in evolution of asexuality, 202 Getieftes o/ Sexuality in Higher tungi (Raper), 26",' 268, M3, 461 Genome duplication, 520-521 Gihberella species homothallism, 42 MAT locus, 15 Gilbertella persicaria, 438 Git3, in Scbizosaccharomyces pombe, 147 Glomerella species, MAT locus in, 14 Glomeromycota. 419-427 chimensm formation, general principles of, 425 overview, 424-425 in parasexual cycle, 426 resource partitioning mechanisins, 425-426 vegetative, 426 evolution and, 419-424, 426-427 multigenomic strueture, 424—426 muldnucleate spore srrueture, 426—427 phyiogeny of PLSI variants, 422 polymorphism, intraindividual, 420-421, ' 424 ribosomal DNA (rDNA), 420, 423-425 spores as Surrogate individuals in studies of, 419-420 Glomus caledonium, 423, 424 Clomus claroideum, 424 Glomus etunicatum, 421—422, 424 Glomus geosporwn, 422, 424 Glomus intraradices, 415, 421-422 Glomus mosseae, 424, 426 ß-Glucosidase gene, 99 Gpal, in Schizosaccharomyces pomhe, 147 GpgA, in aspergilli, 128 gprA, in aspergiili, 128 gprB, in aspergilii, 128 gprC, D, E. G, K genes, in aspergilli, 40, 129-130 Grape, downy müdew of, 453—454 H Hjploids, adaptation rate and, 520 Hi'beloma crustuliniforme, 337 HF.Gs (homing endunuclease genes), 8 Hemiascomycetes evolution of silencing at macing-type loci, 189-197 MAT and genome comparisons, 247-261 conservation of synteny, 256 gene identification, 249-251 HO endonudease, 257-258 M/^Tand silenced cassettes, 251-257 multiple sequence alignments, 252-253 overvievv, 258-261 species with multiple MAT loci, 249-258 species with Single MAT locus, 258 phyiogeny of, 191 Heterobasidion annosum, 337 Heterochromatin, silencing of storage cas- settes in Schizosaccharomyces pombe, 151-152 Heterokaryosis chimerism and, 425 in Glomeromycota, 420—421 in parasexual cycle, 426 Heterothallic-homothallic transitions, see Mating-type switching Heterothallism defined, 35, 462 homothallism transition, 30—32, 35-53 in Mucorales, 411—412 oomycetes, 446, 447 recognition and karyogamy in ascomycetes, 94 in Schizosaccharomyces pombe, 145 Ustilago maydis, discovery in, 354 Heterozygosity, of MAT alleles, 518 HMG-domain proteins, 10, 13, 15 Ho endonuclease acquisition of gene, 7-8, 38 in hemiascomycetous yeasts, 257-258 in Saccharomyces cerevisiae, 37-38, 161-163,231,514 silencing of HML and HMR cassettes and, 37-38 Homeodomain locus, in basidiomycetes, 22 Homing endonuclease genes (HEGs), 8 Homobasidiomycetes cost of sex, 529-530 internuclear recognition in, 114 MAT loci organization, 324—325 Homokaryosis, in Glomeromycota, 420-421 Homothallism defined, 35, 462 heterothallism transition, 30-32, 35-51 mechanisms of, 35 in Mucorales, 411-412 mutations in A and ß genes and evolution of, 293-294 oomycetes, 446-448 outcrossing, 45 primary ascomycetes, 41-45 MAT absence, 44-45 one MAT idiomorph in genome, 43-44 tvvo MAT idiomorphs in same genome, 41-43 in basidiomycetes, 47 pseudohomothallism, 39, 40 recognition and karyogamy in ascomycetes, 94 Saccharomyces cerevisiae, 37-38, 514 secondary, 529-530 in ascomycetes, 39 in basidiomycetes, 46-47 overview, 39 Sordaria macrospora, 171-184 in Zygomycetes, 434 Hook cell formation, 334 Hstlp, in Saccharomyces cerevisiae, 196 Hydrophobins, 334 I Inbreeding, in natural yeast populations, 508-509 Internuclear recognition model, 112-114 Introns, 511-512, 515 Irpex lacteus, 320, 322-323 Isogamy, 528-529 K KAR4 gene, in Saccharomyces cerevisiae, 164-165 Kimura, xVL, 491 Kluyveromyces lactis asg (a-speeifie gene) regulation, 85 MAT and genome comparison in hemiascomycetes, 250-257 mating-type switching, 38, 195 MAT locus strueture, 5, 6, 7, 8 silencing of mating-type loci, 194—195 Sir proteins in, 192, 193, 195 Kluyveromyces thermotolerans, 249-256, 258' Kluyveromyces ivaltü characteristics of, 250 genome duplication, 520 HO gene absence, 258 mating-type locus, 193, 250-256 phyiogeny of, 250 sequence identity boxes, 255 Kniep, Hans, 283-284 Leotiomycetes, MAT locus in, 14 Leptosphaeria biglobosa, 98 Leptosphaeria maculans, 98 Linkage, of mating-type loci in mushroom fungi, 317-328 Linkage disequilibria, 528 Lipid metabolism, in Emericella nidulans, 133 Lodderomyces elongispoms, 45 Loss-of funetion mutations in mating-type loci, 202 isdA, in aspergilli, 127 M Magnaporthe grisea, MAT locus in, 5, 14 Male sterility, 336-337 MAPK, see Mitogen-activated protein kinase (MAPK) Index 539 Mating Inhibition factors (MIFs), in Ustilago hordei, 393 Mating-type-like (MTL) locus, in Candida albicans, 62-64, 216-217, 222-228, 240-241 Mating-type locus (MAT) locus Alternaria alternata, 102-103 in aspergilli, 131-132, 136-139 basdiomycetes cloning MAT genes, 318-319, 323-324 organization and synteny, 317-318 in Candida species complex, 8-13, 235-242 cell identity control, 59-70 ascomycetes, 60-66 basidiomycetes, 66—70 in hemiascomycetous yeast genomes, 247-261 Kluyveromyces lactis, 5, 6, 7, 8, 194-195 Kluyveromyces waltii, 193, 250-256 in Saccharomyces cerevisiae, 37-38, 76-78 in sexual Aspergillns spp., 136-139 in Ustilago hordei, 392^101 Mating-type locus (MAT) locus, evolution of ascomycetes Candida species, 8-13 filamentous ascomycetes (Pezizomycotina), 13-15 HMG domain protein function, 10, 13 HO endonuclease gene, 7-8 Saccharomyces lineage, 5—8 basidiomycetes, 19-32 Coprinellus disseminatus, 16 Coprinopsis einerea, 24-25 Cryptococcus neoformans, 27-30 homeodomain locus, 22 Microbotryum violaceum, 27 multiallelic bipolar basidiomycetes, 26-27 pheromone/reeeptor locus, 21 Pholiata nameko, 26 recombination, 29-30, 31 Schizophyllum commune, 25-26 Sporisorium reilianum, 23-24, 25 tetrapolar mating System, 20, 22-23 transitions between heterothaiiic and homothallic cycles, 30—32 Ustilago hordei, 26-17 Ustilago maydis, 22-24 Mating-type regulation Candida albicans, 79-87 evolution of, 75-76 Saccharomyces cerevisiae, 75-78 Mating-type switching in ascomycetes, 39—46 in basidiomycetes, 46-50 in Candida albicans, 63—64 cell identity control and, 61, 63-64 in Cryptococcus neoformans, 36, 47-49 in Kluyveromyces lactis, 195 in Saccharomyces cerevisiae, 36. 37-38, 78, 159-168 donor preference, genetic control of, 163-167 donor preference, microscopic analysis of, 167-168 gene conversion, 161-162 microscopic analysis of, 162-163 overview, 159-161 RE (recombinarion enhancer), 163-J67 in Saccharomyces lineage, 6-7 in Schizosaccharomyces pombe, 61, 145, 147-151 secondary homothallism, 39, 46-47 in Schizosaccharomyces pombe, 38-39 Maynard Smith, John, 491 Mcml in Candida albicans, 85 in Saccharomyces cerevisiae, 77-78, 165 in Sordaria macrospora homologue, 182-183 MedA, in aspergilli, 130 Mei2, in Schizosaccharomyces pombe, 147, 153 Mei3, in Schizosaccharomyces pombe, 147 Meiosis meiotic silencing by unpaired DNA (MSUD), 118' Ustilago maydis, 358-359 mib (metalloendopeptidase) gene, 319-321, 323,325-327 Microbotryum violaceum, 27, 47, 390-391, 398, 400 Microsporidia, sex in, 413 MIFs (mating inhibition factors), in Ustilago hordei, 393 Mitochondria basdiomycetes mating-type loci and, 326-327326 cytoplasmic mixing, 335-336 epistasis, 509-510 male sterility and, 336-337 mosaics, 336 recombination, 335—336 rejuvenation of, 531 slow movement in matings, 336 Mitogen-activated protein kinase (MAPK) in aspergilli, 129 in Schizosaccharomyces pombe, 146-147 in Ustilago maydis, 371-372, 377, 381-383 MLMT (multilocus microsatellite typing), of Penicillium marneffei, 205 MLST (multilocus sequence typing) of Cryptococcus gattii, 481, 482 of Penicillium marneffei, 204-205 Mortierella species, 413, 435 Motor proteins, dynein, 334 Mucorales mating in, 411-413 mycoparasitism, 409 trisporoid, 434-439 zygospore dormancy, lack of, 408 Mucor amphibiorum, 409 Mucor circinelloides, 415, 440 Mucor hiemalis. 438 Mucor mucedo, 409, 413, 415, 431-432, 434-435,437-440 Mucor piriformis, 409, 438 Mucor pusillus, 440 Muller's ratchet, 491-492 Multilocus genotyping, of Penicillium marneffei,204-205 Multilocus microsatellite typing (MLMT), of Penicillium marneffei, 205 Multilocus sequence typing (MLST) of Cryptococcus gattii, 481, 482 of Penicillium marneffei, 204-205 Mushroom fungi; see also Basidiomycetes; Homobasidiomycetes; speeifie species mating-type loci, organization and synteny of, i 17-328 Mutation aecumulation, 464-466, 515-516 Mutations evolution of asexualiry and, 202 in Glomeromycota, 420, 426^27 masking and purging deleterious, 518-520 Muller's ratchet, 491-492 Mutualistic symbiosis, 419 Mycosphaerella graminicola, 98 Mycosphaerella zeae-maydis, 101 Mycotypha africana, 432 N Natural selection, role in evolution of asexu- ality, 202 NEJ1, in Saccharomyces cerevisiae, 76 Nematospora coryli, homothallism in, 44 Neocallimastix sp., 410 Neosartorya species morphology of sexual development, 124 N. fischeri'.AI, A3 Neurospora africana, 40-41, 44 Neurospora crassa cell identity control, 65-66 immunity to MSUD (meiotic silencing by unpaired DNA), 118 mating, 39-41 nucleus-restricted expression, 113 postfertilization funcrions of mating-type genes, 116 Sordaria macrospora cornpared, 171-177, 179-184 Neurospora terricola, 44 Neurospora tetrasperma, 171 NosA, in aspergilli, 130-131 Nosema locustae, 415 noxA gene, in Emericella nidulans, 133-134 NsdD, in aspergilli, 130 Nuclear migration into ascogenous hyphae, 112 internuclear recognition model, 112-114 random segregation model, 114—115 Buller phenomenon, 337-338 male srerility and, 336—337 motive force for, 334 Schizophyllum commune, 268, 269. 302, 304^305 Nucleolar Organizer regions (NORs), 423 o Oomycetes, 445-455 cytology of mating, 446-448 gene expression during mating, 450 genetic basis of mating behavior, 449-450 importance of, 445-446 mating hormones, 450 oospores disease transmission, role in, 451 germination of, 448 as survival struetures, 450-451 S40 Index Oomycetes, (Continued) pathology downy mildew of grape, 453-454 late blight of potato, 451-452 Phytophthora capsici blights, 452-453 Phytophthora sojae root and stem rot, 453 sorghum downy mildew, 454 taxonomy, 446 Oospores disease transmission, role in, 451 germination of, 448 as survival structures, 450 Orclp, 195-196 Outcrossing, in natural yeast populations, 508-509 Oxidation State and hyphal differentiation, 133-134 Oxysterol binding protein, in Candida albi- cans, 62, 63 pab (para-aminobenzoic acid) gene, 319, 321, 324, 340 Papazian, Haig, 284 Parasexual cycle, 426 Parasitella parasitica, 409, 413, 432, 434, 437, 440 Parasitic DNA coevolution and domestication of, 513-515 sex and, 510-513 Patl protein, in Schizosaccharomyces pombe, 148, 153 PCR, cloning MAT using direct amplifica- tion, 323-324 Penicillium marneffei biology of, 204 effective population size, 206, 210 evolutionary trajectory, 209—210 multilocus genotyping, 204-205 reproduction, 207-209 spatial components of genetic diversity, 205-206 Peronosclerospora sorghi, 454 Peronospora destructor, 451 Peronospora farinosa, 448 Petromyces species, morphoiogy of sexual development in, 124 Pezizomycotina, mating-type locus in, 13-15 Phaeosphaeria nodorum, 98 Phanerochaete chrysosporium, 320, 321-324, 327 Pheromone/receptor Systems in aspergilli, 127-128 in basidiomycetes, 21 Candida albicans, 84, 220-223 Chytridiomycetes, 411 Coprinellus ctnerea, 290—292 Coprinopsis cinerea, 66—68 Cryptococcus neofortnans, 69-70 Dikarya and basal fungi compared, 414 Mucorales, 413 Saccharomyces cerevisiae, 76, 301-302 Schizophyllum commune characterization of pheromones, 305-307 determinants of recognition by receptors, 307-309 discovery of, 304 gene nomenclature, 304 nuclear migration, role in, 304-305 number of, 286, 302 pheromone precursor sequences, 289, 290 role in B-regulated mating processes, 311-313 yeast studies, 309-310 Schizosaccharomyces pombe, 61-62, 146-148 signaling, in smut fungi, 381-383 Sordaria macrospora, 179-180 trisporic acid, 434-439 Ustilago maydis, 66, 67, 367-372 phoA, in aspergilli, 127 Pholiota natneko, 26, 324 Phosphatidyl inositol-3 kinase, in Candida albicans, 62, 63 Phycomyces blakesleeanus, 412-413, 415, 432-433, 435, 438-440 Phylogenetic tree of the fungal kingdom, 408 Phytophthora cactorum, 448 Phytophthora capsici, 452-453 Phytophthora infestans, 445, 447-452, 454 Phytophthora parasitica, 449 Phytophthora phaseoli, 450 Phytophthora sojae, 453 Phytophthora species, 445-447, 449-451 Pichia angusta, 250, 258, 260 Piromyces species, 415 PlasmidDNA, 510 Plasmopara, 446 Plasmopara viticola, 453 Pleurotus djamor, 320, 321-324 Ploidy, physiological effects of, 517-518 Pneumocystis carinii homothallism, 44 mating-type loci organization and synteny, 322 Podospora anserina cell identity control, 65 mating-type structure and function, 109-117 control of fertilization, 111 internuclear recognition model, 112-114 mating-type structure, 109 mutations, phenotype of, 110 nucleus migration into hyphae, 112 postfertilization developmental steps during fruiting-body formation, 109-111 postfertilization functions of mating- type genes, 116-117 random segregation model, 114-115 MAT locus Cochliobolus heterostrophus compared, 41 gene mutations, 109-111 structure/organization, 97, 109 pseudohomothallism, 171 senescence in, 531 Sordaria macrospora mating-type genes in, 176-178 Poly(A) polymerase, in Candida albicans, 62, 63 Polymorphism, intraindividual in Glomero- mycota, 420-421, 424 Polyphagus euglenae, 410 Population size, effective estimating in fungi, 202-204 Penicillium marneffei, 206, 210 in Wright-Fisher model of evolution, 202 Potato, late blight of, 451-452 ppgA, in aspergilli, 127-128 ppgB, in aspergilli, 128 ppgl/ppgZ, in Sordaria macrospora, 179-180,184 ppoA gene, 133 preß, in aspergilli, 128 prellprel, in Sordaria macrospora, 179-180, 184 Promoters, in Schizophyllum commune, 276 Pseudohomothallism, 39, 40, 171 Psi hormonal signaling, in Emericella nidu- lans, 133 Pyrenopeziza, 14 Pyrenopeziza brassicae, 98 Pyrenophora teres, 98 Pythium, 446^449 Pythium aphanidermatum, 448 R Radiomyces spectabilis, 410 Random drift, 493 Random segregation model, 114-115 Raper, Carlene (Cardy), 267, 272, 301, 310, 338 Raper, John, 267-268, 270-273, 276-278, 280,283,304,310,333,461 Raplp, in Saccharomyces cerevisiae, 189-190 Rasl, in Schizosaccharomyces pombe, 147 rDNA, concerted evolution of, 423-424 Receptors, see Pheromone/receptor Systems Recombination in basidiomycetes, 29-30, 31 evolution of MAT and, 29-30 mitochondrial DNA, 336 outcrossing, 508 Recombination enhancer (RE), in Saccha- romyces cerevisiae, 163-167 Red Queen hypothesis, 492-493 Regulation of mating-type Candida albicans, 79-87 evolution of, 75-76 Saccharomyces cerevisiae, 75-78 Retrotransposition, 512 Rhizopus oryzae, 415, 434, 440 Rhizopus sexualis, 438 Rhizopus stolonifer, 440 R1TS (RNA-induced transcriptional silenc- ing), 190 RME1, in Saccharomyces cerevisiae, 16 RosA, in aspergilti, 130-131 Ruml, in Schizosaccharomyces pombe, 146 Saccharomyces cerevisiae Candida albicans compared, 216, 217, 220-222 Candida glabrata compared, 230-231, 240 cell identity control, 60-61 ceil types, 76 centrornere structure, 193 chromosomal rearrangements, 509 genome duplication, 520-521 Index 541 Ho endonuclease, 514 life cycle, 497 maintenance of sex experiments, 497 mating-type regulation, 75-78 asg expression, 77-78 Candida albicans compared, 81-87 hsg expression, 78 mating-type switching, 78 regulatory circuit, 81, 82 asg expression, 78 transcriptional switching, 78 mating-type switching donor preference, genetic control of, 163-167 donor preference, microscopic analysis of, 167-168 gene conversion, 161-162 microscopic analysis of, 162-163 overview, 36, 37-38, 78, 159-161, 514 RE (recombination enhancer), 163-167 MAT \oci evolution of, 514—515 MAT and genome comparison in hemiascomycetes, 250-257 mitochondria and, 326 pheromone-receptor System, 301-302 phylogeny, 191 regulation of mating type in, 247, 249 sexual cycle of an ho mutant of, 248 silencingin, 78, 189-190 spoll spol3 System, 500-503 whole genome duplication, 191 Saccharomyces kluyveri, 250, 258 Saccharomyces lineage, evolution of mating- type cassettes in, 5-8 Saccharomyces pastoriamts, 500 sakA, in Emericelia nidulans, 130 Schizophyllum commune A genes classical genetics studies, 302-304 doning oi Aa, 277-278 flanking genes and boundanes, 277 isolation of, 271-274 mutations, 271, 293 number of alleles, 270-271 overview, 270, 274 Promoter regions, 276 Y and Z gene products, 274-276 ß genes arrangement of, 305 classical genetics studies, 302-304 evolution of, 291 gene products, 304 isolation of, 278-280, 304 mutations, 271, 293, 294, 310-311, 324 number of alleles, 270-271, 286 overview, 270 pheromone signaling and, 311-313 recombination, 287-288 classical genetics studies, 302—304 flat phenotype, 284, 303 life cycle, 268-270, 284 mating process, 302 mating-type loci A genes, 270-278 B genes, 270-271, 278-280 doning of, 277-278, 318-319 discovery of, 283-284 historical perspective, 267-280 mutations, 271, 293, 294, 310-311, 324 organization and synteny of, 319, 321-322,324-325 Promoter regions, 276 origin of multiple mating types in, 283-296 overview, 25-26 pheromones/receptors characterization of pheromones, 305-307 determinants of recognition by receptors, 307-309 discovery of, 304 gene nomenclature, 304 nuclear migration, role in, 304-305 number of, 286, 302 pheromone precursor sequences, 289, 290 role in B-regulated mating processes, 311-313 yeast studies, 309-310 somatic recombination, 339-341 Schizosaccharomyces kambucha, 152 Schizosaccharomyces pombe cell identity control, 61-62 centromere structure, 193 evolution, 152-154 heterothallic strains, 145 homothallk switch, 147-148 life cycle, overview of, 143-144 mating-type switching, 145, 147-151 bias of donor cassette choice, 150-151 copy transposition from matlß to mall, 149-151 imprinting matl DNA, 148-149 overview, 38-39 silencing of storage cassettes mat2 and maxi, 151-152 mal region, organization of, 144-145 pheromone communication, 146-148 silencingin, 190-191 Sir proteins in, 192 transcriptional regulation, 145-146 Sclerotinia trifolium, 108 Scutellospora castanea, 423, 424-425 Scutellospora gregarta, 423 Scutellospora pellucida, 423, 424-425 SDSA (synthesis-dependent Strand anneal- mg), 161 Selection antagonism berween sexual and natural selection, 515-517 frequency-dependent, 492-493 natural selection role in evolution of asexuality, 202 Septoria passerinii, 98, 103 Sex Inducer genes, of Cryptococctis neofor- mans. 69-70 Sex (sexual reproduction) cost of, 201-202, 465-470, 528-530 epistasis and, 509-510 evolutionary implications of, 527-528, 5iZ ioss of, 464 maintenance of Crow and Kimura and, 491 experiments on, 494—505 Fisher and Muller, 490-491, 495 Maynard Smith and, 491 Mu'ller's ratchet, 491^92 Red Queen hypothesis, 492^93 Weismann and, 490, 493 in natural populations in Cryptococcus gattii, 477-486 in natural yeast populations, 508-509 oomycetes, 445—455 parasitic DNA and, 510 quantitative nature of, 464 survival structure production, 531 Sexual fitness, 465 Sexual selection, antagonism with natural (vegetative) selection, 515-517 SfaD, in aspergilli, 128 Sikyospore, 434 Silencing of mating-type loci, 189-197 Candida glabrata, 194 comparative genomics of, 190-191, 192-194" evolution of silenced chromatin, 196-197 Kluyveromyces lactis, 194-195 overview, 189 Saccharomyces cerevisiae, 189-190 Schizosaccharomyces pombe, 190-191 Sir proteins, role of, 192-196 whole-genome duplication, impact of. 195-196 Silent mating cassettes defects in, 61 in Saccharomyces cerevisiae, 36. 37-38, 61, 78 in Saccharomyces lineage, 6-7 Sirenin, 411 Sir proteins functions of, 192-194, 195-196 hemiascomycetes phylogeny and, 191 in Saccharomyces cerevisiae, 37, 189-190 where they act, 193-194 Sistotrema brinkmannii, homothallism and, 47 SMIP gene, in Schizophyllum commune, 27" SMR1, in Podospora anserina, 109, 111, 113-114, 116-117 SMR2, in Podospora anserina. 109-115 Smut fungi bipolar and tetrapolar mating Systems, 389^01 mating-type loci evolutionary history, 400-401 functional analysis of, 393—394 future studies and quesrions, 400-401 genomic analysis, 396—398 Identification of, 392-393 organization of, 394-396 mating-type loci organization. 378-381 overview, 377-378. 390-391 pheromone-controlled signaling cascade, 381-385 phytopathogenesis, 389-390, 391, 398-400 Somatic recombination in dikaryons. 341—342 Di-Mon matings, 338-341 Sordaria brevtcollis, 45—46, 175 Sordarta fimicola, outcrossing of, 45 542 Index Sordaria macrospora, 171-184 lifecycle, 171-172, 173 mating-type genes into Podospora anserina, 41 mating-type locus fruiting-body development and, 176-179 ' interaction network of mating-type proteins, 181-184 mating-type-dependent gene expression, 179-181 pheromone/pheromone receptor System, 179-180 phylogenetic analysis, 174-175 SMTa-1, 177, 180-184 structure of, 172—174 transcriptional expression, 175 transgenic studies in Podospora anserina, 176-178 Mcml homologue, 182-183 Neurospora crassa compared, 171-177, 179-184 outcrossing, 45 phylogeny, 171 primary homothallism, 42 STE12 homologue, 183-184 Sordariomycetes, MAT locus in, 4, 12-15 Sorghum downy mildew, 454 SPB1 gene, in Saccharomyces cerevisiae, 164-165 Spore trapping, 335 Sporisorium reilianum, 23-24, 25, 370, 378-380 spoll spol3 system, 500-503 STE2, in Saccharomyces cerevisiae, 76 STE3 in Candida albicans, 83 homologs in basidiomycetes, 322—324 in Saccharomyces cerevisiae, 76 Stel 1, in Schizosaccharomyces pombe, 145-147 STE12 in Candida albicans, 84 in Cryptococcus and Pneumocystis, 322 in Saccharomyces cerevisiae, 77, 84 Sordaria macrospora homologue, 183-184 Stemphylium MAT locus phylogenetic and structural analyses, 104-105 structure, 101, 102, 103 primary homothallism, 42 Sordaria compared, 174 Stml, in Schizosaccharomyces pombe, 147 StuA, in aspergilli, 130 Suml, in Saccharomyces cerevisiae, 196 Swi4/6, in Saccharomyces cerevisiae. 165-166,167' Swi6, in Schizosaccharomyces pombe, 190-191 Swi5-Swi2, in Schizosaccharomyces pombe, 151 Symbiosis, mutualistic, 419 Synteny, of mating-type loci in mushroom fungi, 317-328 Synthesis-dependent Strand annealing (SDSA), 161 Syzigites megalocarpus, 438 TALE (three-amino-acid loop extension) homeobox, in Schizophyllum com- mune, 276, 277 Telomeric silencing, 38, 190, 193 Tetrapolar mating Systems, 20, 22-23, 317-318 Thamnidium elegans, 438 TOS9, in Candida albicans, 218-220 Transcriptional regulatory circuit Candida albicans, 79-87 evolution of, 75-76 Saccharomyces cerevisiae, 75-78 Transposable elements MAT loci and, 400 as parasitic DNA, 512-514 Trisporic acid biosynthesis pathway, 436 diversity in signaling by, 435 overview, 413, 434—435 physiological aspects of signaling, 437-439 tspl gene, 437, 440 tspl gene, 440 Tvvofold cost of sex, 528 Ty elements, 512-514 u Ustilaginales, bipolar and tetrapolar mating Systems in, 389^01 Ustilago hordei evolution, 26—27 mating-type loci, 378-381 functional analysis of, 393-394 genomic analysis, 396—398 identification of, 392-393 organization of, 394-396 sex chromosomes, 399, 400 transposable elements, 400 overview, 390 pathogenesis of, 391 Ustilago maydis compared, 399-401 Ustilago maydis, 351-372 a locus, 367-372 cloning and molecular genetic analysis, 367-372 organization and functional/ evolutionary implications, 378-381 overview, 355-357 b locus, 358-367 bmut alleles, 358-359, 365 cloning and molecular genetic analysis, 359-367 meiosis, role in, 358—359 organization and functional/evolutionary implications, 378-381 overview, 355-356 cell identity control, 66, 67 evolutionary distance from Ustilago hordei', 399-400 general features, 351-352 genomic analysis of mating System, 396-398 heterothallism, 354 homeodomain locus, 22-23 life cycle, 352 mating incompatibility, genetic basis of, 355-357 MAT loci mitochondria and, 326 nomenclature, 21, 22 pheromone-controlled signaling cascade bE/bW heterodimer, targets of, 383-385 components, 22—23, 381 genes and processes controlled by, 381-383 sexual/pathogenic development, 383-385 repetitive DNA, 399, 400 segregation analysis, 353-354 sex factors, 354-355 Sporisorium reilianum compared, 23-24 sterility factor, 355 V VDE, 515 VeA, in aspergilli, 126-127 Vegetative chimerism, 426 Vegetative fitness, 470-473 Vegetative (natural) selection, antagonism with sexual selection, 515-517 Virus, transmission via spores, 531-532 w Weismann, August, 489, 490, 493 White-opaque switching in Candida albicans, 80-81, 82-83, 84-85 Williams, G. C, 493 WOR1, in Candida albicans, 82-83, 85, 218-220 Wright-Fisher model of evolution, 202 Yarrowia lipolytica, 61, 193, 250, 258, 260 Zygomycetes, 431-441 diseases caused by, 431, 434 genetics of sexual differentiation, 439—441 mating-type System, 434 sexual mechanisms in, 411—413 sexual morphogenesis, 431^433 trisporic acid biosynthesis pathway, 436 diversity in signaling by, 435 overview, 434-435 physiological aspects of signaling, 437-439 Zygorhizidium planktonicum, 410, 411 Zygorhynchus heterogamus, 435, 437 Zygorhynchus macrocarpus, 438 Zygorhynchus moelleri, 435, 438 Zygorhynchus species, 434 Zygosaccharomyces rouxii, 249—256, 257 Zygotropism, 432
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spelling	Sex in fungi molecular determination and evolutionary implications edited by Joseph Heitman ... [et al.] Washington, D.C. ASM Press c2007 XXV, 542 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Includes index. Evolution Fungi Reproduction Fungi genetics Fungi physiology Genes, Mating Type, Fungal Reproduction, Asexual Sexualität (DE-588)4054684-6 gnd rswk-swf Pilze (DE-588)4046076-9 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Pilze (DE-588)4046076-9 s Sexualität (DE-588)4054684-6 s DE-604 Heitman, Joseph Sonstige oth http://www.loc.gov/catdir/toc/ecip0716/2007017650.html Table of contents only HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016173299&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Sex in fungi molecular determination and evolutionary implications Evolution Fungi Reproduction Fungi genetics Fungi physiology Genes, Mating Type, Fungal Reproduction, Asexual Sexualität (DE-588)4054684-6 gnd Pilze (DE-588)4046076-9 gnd
subject_GND	(DE-588)4054684-6 (DE-588)4046076-9 (DE-588)4143413-4
title	Sex in fungi molecular determination and evolutionary implications
title_auth	Sex in fungi molecular determination and evolutionary implications
title_exact_search	Sex in fungi molecular determination and evolutionary implications
title_exact_search_txtP	Sex in fungi molecular determination and evolutionary implications
title_full	Sex in fungi molecular determination and evolutionary implications edited by Joseph Heitman ... [et al.]
title_fullStr	Sex in fungi molecular determination and evolutionary implications edited by Joseph Heitman ... [et al.]
title_full_unstemmed	Sex in fungi molecular determination and evolutionary implications edited by Joseph Heitman ... [et al.]
title_short	Sex in fungi
title_sort	sex in fungi molecular determination and evolutionary implications
title_sub	molecular determination and evolutionary implications
topic	Evolution Fungi Reproduction Fungi genetics Fungi physiology Genes, Mating Type, Fungal Reproduction, Asexual Sexualität (DE-588)4054684-6 gnd Pilze (DE-588)4046076-9 gnd
topic_facet	Evolution Fungi Reproduction Fungi genetics Fungi physiology Genes, Mating Type, Fungal Reproduction, Asexual Sexualität Pilze Aufsatzsammlung
url	http://www.loc.gov/catdir/toc/ecip0716/2007017650.html http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016173299&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT heitmanjoseph sexinfungimoleculardeterminationandevolutionaryimplications

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