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Heterothallism

April 24, 2023

Look up heterothallism in Wiktionary, the free dictionary.

Heterothallic species have sexes that reside in different individuals. The term is applied particularly to distinguish heterothallic fungi, which require two compatible partners to produce sexual spores, from homothallic ones, which are capable of sexual reproduction from a single organism.

In heterothallic fungi, two different individuals contribute nuclei to form a zygote. Examples of heterothallism are included for Saccharomyces cerevisiae, Aspergillus fumigatus, Aspergillus flavus, Penicillium marneffei and Neurospora crassa. The heterothallic life cycle of N. crassa is given in some detail, since similar life cycles are present in other heterothallic fungi.

Life cycle of Saccharomyces cerevisiae

 
Saccharomyces cerevisiae tetrad

The yeast Saccharomyces cerevisiae is heterothallic. This means that each yeast cell is of a certain mating type and can only mate with a cell of the other mating type. During vegetative growth that ordinarily occurs when nutrients are abundant, S. cerevisiae reproduces by mitosis as either haploid or diploid cells. However, when starved, diploid cells undergo meiosis to form haploid spores.[1] Mating occurs when haploid cells of opposite mating type, MATa and MATα, come into contact. Ruderfer et al.[2] pointed out that such contacts are frequent between closely related yeast cells for two reasons. The first is that cells of opposite mating type are present together in the same ascus, the sac that contains the tetrad of cells directly produced by a single meiosis, and these cells can mate with each other. The second reason is that haploid cells of one mating type, upon cell division, often produce cells of the opposite mating type with which they may mate.

Katz Ezov et al.[3] presented evidence that in natural S. cerevisiae populations clonal reproduction and a type of “self-fertilization” (in the form of intratetrad mating) predominate. Ruderfer et al.[2] analyzed the ancestry of natural S. cerevisiae strains and concluded that outcrossing occurs only about once every 50,000 cell divisions. Thus, although S. cerevisiae is heterothallic, it appears that, in nature, mating is most often between closely related yeast cells. The relative rarity in nature of meiotic events that result from outcrossing suggests that the possible long-term benefits of outcrossing (e.g. generation of genetic diversity) are unlikely to be sufficient for generally maintaining sex from one generation to the next.[citation needed] Rather, a short-term benefit, such as meiotic recombinational repair of DNA damages caused by stressful conditions such as starvation may be the key to the maintenance of sex in S. cerevisiae.[4][5]

Life cycle of Aspergillus fumigatus

Aspergillus fumigatus, is a heterothallic fungus.[6] It is one of the most common Aspergillus species to cause disease in humans with an immunodeficiency. A. fumigatus, is widespread in nature, and is typically found in soil and decaying organic matter, such as compost heaps, where it plays an essential role in carbon and nitrogen recycling. Colonies of the fungus produce from conidiophores thousands of minute grey-green conidia (2–3 μm) that readily become airborne. A. fumigatus possesses a fully functional sexual reproductive cycle that leads to the production of cleistothecia and ascospores.[7]

Although A. fumigatus occurs in areas with widely different climates and environments, it displays low genetic variation and lack of population genetic differentiation on a global scale.[8] Thus the capability for heterothallic sex is maintained even though little genetic diversity is produced. As in the case of S. cereviae, above, a short-term benefit of meiosis may be the key to the adaptive maintenance of sex in this species.

Life cycle of Aspergillus flavus

A. flavus is the major producer of carcinogenic aflatoxins in crops worldwide. It is also an opportunistic human and animal pathogen, causing aspergillosis in immunocompromised individuals. In 2009, a sexual state of this heterothallic fungus was found to arise when strains of opposite mating type were cultured together under appropriate conditions.[9]

Sexuality generates diversity in the aflatoxin gene cluster in A. flavus,[10] suggesting that production of genetic variation may contribute to the maintenance of heterothallism in this species.

Life cycle of Talaromyces marneffei

Henk et al.[11] showed that the genes required for meiosis are present in T. marneffei, and that mating and genetic recombination occur in this species.

Henk et al.[11] concluded that T. marneffei is sexually reproducing, but recombination in natural populations is most likely to occur across spatially and genetically limited distances resulting in a highly clonal population structure. Sex is maintained in this species even though very little genetic variability is produced. Sex may be maintained in T. marneffei by a short-term benefit of meiosis, as in S. cerevisiae and A. fumigatus, discussed above.

Life cycle of Neurospora crassa

 
Neurospora crassa life cycle. The haploid mycelium reproduces asexually by two processes: (1) simple proliferation of existing mycelium, and (2) formation of conidia (macro- and micro-) which can be dispersed and then germinate to produce new mycelium. In the sexual cycle, mating can only occur between individual strains of different mating type, ‘A’ and ‘a’. Fertilization occurs by the passage of nuclei of conidia or mycelium of one mating type into the protoperithecia of the opposite mating type through the trichogyne. Fusion of the nuclei of opposite mating types occurs within the protoperithecium to form a zygote (2N) nucleus.

The sexual cycle of N. crassa is heterothallic. Sexual fruiting bodies (perithecia) can only be formed when two mycelia of different mating type come together. Like other ascomycetes, N. crassa has two mating types that, in this case, are symbolized by ‘A’ and ‘a’. There is no evident morphological difference between the ‘A’ and 'a' mating type strains. Both can form abundant protoperithecia, the female reproductive structure (see figure, top of §). Protoperithecia are formed most readily in the laboratory when growth occurs on solid (agar) synthetic medium with a relatively low source of nitrogen.[12] Nitrogen starvation appears to be necessary for expression of genes involved in sexual development.[13] The protoperithecium consists of an ascogonium, a coiled multicellular hypha that is enclosed in a knot-like aggregation of hyphae. A branched system of slender hyphae, called the trichogyne, extends from the tip of the ascogonium projecting beyond the sheathing hyphae into the air. The sexual cycle is initiated (i.e. fertilization occurs) when a cell (usually a conidium) of opposite mating type contacts a part of the trichogyne (see figure, top of §). Such contact can be followed by cell fusion leading to one or more nuclei from the fertilizing cell migrating down the trichogyne into the ascogonium. Since both ‘A’ and ‘a’ strains have the same sexual structures, neither strain can be regarded as exclusively male or female. However, as a recipient, the protoperithecium of both the ‘A’ and ‘a’ strains can be thought of as the female structure, and the fertilizing conidium can be thought of as the male participant.

The subsequent steps following fusion of ‘A’ and ‘a’ haploid cells, have been outlined by Fincham and Day,[14] and by Wagner and Mitchell.[15] After fusion of the cells, the further fusion of their nuclei is delayed. Instead, a nucleus from the fertilizing cell and a nucleus from the ascogonium become associated and begin to divide synchronously. The products of these nuclear divisions (still in pairs of unlike mating type, i.e. ‘A’ / ‘a’) migrate into numerous ascogenous hyphae, which then begin to grow out of the ascogonium. Each of these ascogenous hypha bends to form a hook (or crozier) at its tip and the ‘A’ and ‘a’ pair of haploid nuclei within the crozier divide synchronously. Next, septa form to divide the crozier into three cells. The central cell in the curve of the hook contains one ‘A’ and one ‘a’ nucleus (see figure, top of §). This binuclear cell initiates ascus formation and is called an “ascus-initial” cell. Next the two uninucleate cells on either side of the first ascus-forming cell fuse with each other to form a binucleate cell that can grow to form a further crozier that can then form its own ascus-initial cell. This process can then be repeated multiple times.

After formation of the ascus-initial cell, the ‘A’ and ‘a’ nucleus fuse with each other to form a diploid nucleus (see figure, top of §). This nucleus is the only diploid nucleus in the entire life cycle of N. crassa. The diploid nucleus has 14 chromosomes formed from the two fused haploid nuclei that had 7 chromosomes each. Formation of the diploid nucleus is immediately followed by meiosis. The two sequential divisions of meiosis lead to four haploid nuclei, two of the ‘A’ mating type and two of the ‘a’ mating type. One further mitotic division leads to four ‘A’ and four ‘a’ nuclei in each ascus. Meiosis is an essential part of the life cycle of all sexually reproducing organisms, and in its main features, meiosis in N. crassa seems typical of meiosis generally.

As the above events are occurring, the mycelial sheath that had enveloped the ascogonium develops as the wall of the perithecium, becomes impregnated with melanin, and blackens. The mature perithecium has a flask-shaped structure.

A mature perithecium may contain as many as 300 asci, each derived from identical fusion diploid nuclei. Ordinarily, in nature, when the perithecia mature the ascospores are ejected rather violently into the air. These ascospores are heat resistant and, in the lab, require heating at 60 °C for 30 minutes to induce germination. For normal strains, the entire sexual cycle takes 10 to 15 days. In a mature ascus containing 8 ascospores, pairs of adjacent spores are identical in genetic constitution, since the last division is mitotic, and since the ascospores are contained in the ascus sac that holds them in a definite order determined by the direction of nuclear segregations during meiosis. Since the four primary products are also arranged in sequence, the pattern of genetic markers from a first-division segregation can be distinguished from the markers from a second-division segregation pattern.

See also

References

  1. ^ Herskowitz I (December 1988). "Life cycle of the budding yeast Saccharomyces cerevisiae". Microbiol. Rev. 52 (4): 536–53. doi:10.1128/MMBR.52.4.536-553.1988. PMC 373162. PMID 3070323.
  2. ^ a b Ruderfer DM, Pratt SC, Seidel HS, Kruglyak L (September 2006). "Population genomic analysis of outcrossing and recombination in yeast". Nat. Genet. 38 (9): 1077–81. doi:10.1038/ng1859. PMID 16892060. S2CID 783720.
  3. ^ Katz Ezov T, Chang SL, Frenkel Z, Segrè AV, Bahalul M, Murray AW, Leu JY, Korol A, Kashi Y (January 2010). "Heterothallism in Saccharomyces cerevisiae isolates from nature: effect of HO locus on the mode of reproduction". Mol. Ecol. 19 (1): 121–31. doi:10.1111/j.1365-294X.2009.04436.x. PMC 3892377. PMID 20002587.
  4. ^ Birdsell JA, Wills C (2003). The evolutionary origin and maintenance of sexual recombination: A review of contemporary models. Evolutionary Biology Series >> Evolutionary Biology, Vol. 33 pp. 27-137. MacIntyre, Ross J.; Clegg, Michael, T (Eds.), Springer. ISBN 978-0306472619
  5. ^ Elvira Hörandl (2013). Meiosis and the Paradox of Sex in Nature, Meiosis, ISBN 978-953-51-1197-9, InTech, DOI: 10.5772/56542
  6. ^ Sugui JA, Losada L, Wang W, Varga J, Ngamskulrungroj P, Abu-Asab M, Chang YC, O'Gorman CM, Wickes BL, Nierman WC, Dyer PS, Kwon-Chung KJ (2011). "Identification and characterization of an Aspergillus fumigatus "supermater" pair". mBio. 2 (6): e00234–11. doi:10.1128/mBio.00234-11. PMC 3225970. PMID 22108383.
  7. ^ O'Gorman CM, Fuller H, Dyer PS (January 2009). "Discovery of a sexual cycle in the opportunistic fungal pathogen Aspergillus fumigatus". Nature. 457 (7228): 471–4. Bibcode:2009Natur.457..471O. doi:10.1038/nature07528. PMID 19043401. S2CID 4371721.
  8. ^ Rydholm C, Szakacs G, Lutzoni F (April 2006). "Low genetic variation and no detectable population structure in aspergillus fumigatus compared to closely related Neosartorya species". Eukaryotic Cell. 5 (4): 650–7. doi:10.1128/EC.5.4.650-657.2006. PMC 1459663. PMID 16607012.
  9. ^ Horn BW, Moore GG, Carbone I (2009). "Sexual reproduction in Aspergillus flavus". Mycologia. 101 (3): 423–9. doi:10.3852/09-011. PMID 19537215. S2CID 20648447.
  10. ^ Moore GG, Elliott JL, Singh R, Horn BW, Dorner JW, Stone EA, Chulze SN, Barros GG, Naik MK, Wright GC, Hell K, Carbone I (2013). "Sexuality generates diversity in the aflatoxin gene cluster: evidence on a global scale". PLOS Pathog. 9 (8): e1003574. doi:10.1371/journal.ppat.1003574. PMC 3757046. PMID 24009506.
  11. ^ a b Henk DA, Shahar-Golan R, Devi KR, Boyce KJ, Zhan N, Fedorova ND, Nierman WC, Hsueh PR, Yuen KY, Sieu TP, Kinh NV, Wertheim H, Baker SG, Day JN, Vanittanakom N, Bignell EM, Andrianopoulos A, Fisher MC (2012). "Clonality despite sex: the evolution of host-associated sexual neighborhoods in the pathogenic fungus Penicillium marneffei". PLOS Pathog. 8 (10): e1002851. doi:10.1371/journal.ppat.1002851. PMC 3464222. PMID 23055919.
  12. ^ Westergaard M, Mitchell HK (1947). "Neurospora. Part V. A synthetic medium favoring sexual reproduction". American Journal of Botany. 34: 573–577. doi:10.1002/j.1537-2197.1947.tb13032.x.
  13. ^ Nelson MA, Metzenberg RL (September 1992). "Sexual development genes of Neurospora crassa". Genetics. 132 (1): 149–162. doi:10.1093/genetics/132.1.149. PMC 1205113. PMID 1356883.
  14. ^ Fincham J RS, Day PR (1963). Fungal Genetics. Oxford, UK: Blackwell Scientific Publications. ASIN B000W851KO.
  15. ^ Wagner RP, Mitchell HK (1964). Genetics and Metabolism. New York, NY: John Wiley and Sons. ASIN B00BXTC5BO.

April 24, 2023
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Look up heterothallism in Wiktionary the free dictionary Heterothallic species have sexes that reside in different individuals The term is applied particularly to distinguish heterothallic fungi which require two compatible partners to produce sexual spores from homothallic ones which are capable of sexual reproduction from a single organism In heterothallic fungi two different individuals contribute nuclei to form a zygote Examples of heterothallism are included for Saccharomyces cerevisiae Aspergillus fumigatus Aspergillus flavus Penicillium marneffei and Neurospora crassa The heterothallic life cycle of N crassa is given in some detail since similar life cycles are present in other heterothallic fungi Contents 1 Life cycle of Saccharomyces cerevisiae 2 Life cycle of Aspergillus fumigatus 3 Life cycle of Aspergillus flavus 4 Life cycle of Talaromyces marneffei 5 Life cycle of Neurospora crassa 6 See also 7 ReferencesLife cycle of Saccharomyces cerevisiae Edit Saccharomyces cerevisiae tetrad The yeast Saccharomyces cerevisiae is heterothallic This means that each yeast cell is of a certain mating type and can only mate with a cell of the other mating type During vegetative growth that ordinarily occurs when nutrients are abundant S cerevisiae reproduces by mitosis as either haploid or diploid cells However when starved diploid cells undergo meiosis to form haploid spores 1 Mating occurs when haploid cells of opposite mating type MATa and MATa come into contact Ruderfer et al 2 pointed out that such contacts are frequent between closely related yeast cells for two reasons The first is that cells of opposite mating type are present together in the same ascus the sac that contains the tetrad of cells directly produced by a single meiosis and these cells can mate with each other The second reason is that haploid cells of one mating type upon cell division often produce cells of the opposite mating type with which they may mate Katz Ezov et al 3 presented evidence that in natural S cerevisiae populations clonal reproduction and a type of self fertilization in the form of intratetrad mating predominate Ruderfer et al 2 analyzed the ancestry of natural S cerevisiae strains and concluded that outcrossing occurs only about once every 50 000 cell divisions Thus although S cerevisiae is heterothallic it appears that in nature mating is most often between closely related yeast cells The relative rarity in nature of meiotic events that result from outcrossing suggests that the possible long term benefits of outcrossing e g generation of genetic diversity are unlikely to be sufficient for generally maintaining sex from one generation to the next citation needed Rather a short term benefit such as meiotic recombinational repair of DNA damages caused by stressful conditions such as starvation may be the key to the maintenance of sex in S cerevisiae 4 5 Life cycle of Aspergillus fumigatus EditAspergillus fumigatus is a heterothallic fungus 6 It is one of the most common Aspergillus species to cause disease in humans with an immunodeficiency A fumigatus is widespread in nature and is typically found in soil and decaying organic matter such as compost heaps where it plays an essential role in carbon and nitrogen recycling Colonies of the fungus produce from conidiophores thousands of minute grey green conidia 2 3 mm that readily become airborne A fumigatus possesses a fully functional sexual reproductive cycle that leads to the production of cleistothecia and ascospores 7 Although A fumigatus occurs in areas with widely different climates and environments it displays low genetic variation and lack of population genetic differentiation on a global scale 8 Thus the capability for heterothallic sex is maintained even though little genetic diversity is produced As in the case of S cereviae above a short term benefit of meiosis may be the key to the adaptive maintenance of sex in this species Life cycle of Aspergillus flavus EditA flavus is the major producer of carcinogenic aflatoxins in crops worldwide It is also an opportunistic human and animal pathogen causing aspergillosis in immunocompromised individuals In 2009 a sexual state of this heterothallic fungus was found to arise when strains of opposite mating type were cultured together under appropriate conditions 9 Sexuality generates diversity in the aflatoxin gene cluster in A flavus 10 suggesting that production of genetic variation may contribute to the maintenance of heterothallism in this species Life cycle of Talaromyces marneffei EditHenk et al 11 showed that the genes required for meiosis are present in T marneffei and that mating and genetic recombination occur in this species Henk et al 11 concluded that T marneffei is sexually reproducing but recombination in natural populations is most likely to occur across spatially and genetically limited distances resulting in a highly clonal population structure Sex is maintained in this species even though very little genetic variability is produced Sex may be maintained in T marneffei by a short term benefit of meiosis as in S cerevisiae and A fumigatus discussed above Life cycle of Neurospora crassa Edit Neurospora crassa life cycle The haploid mycelium reproduces asexually by two processes 1 simple proliferation of existing mycelium and 2 formation of conidia macro and micro which can be dispersed and then germinate to produce new mycelium In the sexual cycle mating can only occur between individual strains of different mating type A and a Fertilization occurs by the passage of nuclei of conidia or mycelium of one mating type into the protoperithecia of the opposite mating type through the trichogyne Fusion of the nuclei of opposite mating types occurs within the protoperithecium to form a zygote 2N nucleus The sexual cycle of N crassa is heterothallic Sexual fruiting bodies perithecia can only be formed when two mycelia of different mating type come together Like other ascomycetes N crassa has two mating types that in this case are symbolized by A and a There is no evident morphological difference between the A and a mating type strains Both can form abundant protoperithecia the female reproductive structure see figure top of Protoperithecia are formed most readily in the laboratory when growth occurs on solid agar synthetic medium with a relatively low source of nitrogen 12 Nitrogen starvation appears to be necessary for expression of genes involved in sexual development 13 The protoperithecium consists of an ascogonium a coiled multicellular hypha that is enclosed in a knot like aggregation of hyphae A branched system of slender hyphae called the trichogyne extends from the tip of the ascogonium projecting beyond the sheathing hyphae into the air The sexual cycle is initiated i e fertilization occurs when a cell usually a conidium of opposite mating type contacts a part of the trichogyne see figure top of Such contact can be followed by cell fusion leading to one or more nuclei from the fertilizing cell migrating down the trichogyne into the ascogonium Since both A and a strains have the same sexual structures neither strain can be regarded as exclusively male or female However as a recipient the protoperithecium of both the A and a strains can be thought of as the female structure and the fertilizing conidium can be thought of as the male participant The subsequent steps following fusion of A and a haploid cells have been outlined by Fincham and Day 14 and by Wagner and Mitchell 15 After fusion of the cells the further fusion of their nuclei is delayed Instead a nucleus from the fertilizing cell and a nucleus from the ascogonium become associated and begin to divide synchronously The products of these nuclear divisions still in pairs of unlike mating type i e A a migrate into numerous ascogenous hyphae which then begin to grow out of the ascogonium Each of these ascogenous hypha bends to form a hook or crozier at its tip and the A and a pair of haploid nuclei within the crozier divide synchronously Next septa form to divide the crozier into three cells The central cell in the curve of the hook contains one A and one a nucleus see figure top of This binuclear cell initiates ascus formation and is called an ascus initial cell Next the two uninucleate cells on either side of the first ascus forming cell fuse with each other to form a binucleate cell that can grow to form a further crozier that can then form its own ascus initial cell This process can then be repeated multiple times After formation of the ascus initial cell the A and a nucleus fuse with each other to form a diploid nucleus see figure top of This nucleus is the only diploid nucleus in the entire life cycle of N crassa The diploid nucleus has 14 chromosomes formed from the two fused haploid nuclei that had 7 chromosomes each Formation of the diploid nucleus is immediately followed by meiosis The two sequential divisions of meiosis lead to four haploid nuclei two of the A mating type and two of the a mating type One further mitotic division leads to four A and four a nuclei in each ascus Meiosis is an essential part of the life cycle of all sexually reproducing organisms and in its main features meiosis in N crassa seems typical of meiosis generally As the above events are occurring the mycelial sheath that had enveloped the ascogonium develops as the wall of the perithecium becomes impregnated with melanin and blackens The mature perithecium has a flask shaped structure A mature perithecium may contain as many as 300 asci each derived from identical fusion diploid nuclei Ordinarily in nature when the perithecia mature the ascospores are ejected rather violently into the air These ascospores are heat resistant and in the lab require heating at 60 C for 30 minutes to induce germination For normal strains the entire sexual cycle takes 10 to 15 days In a mature ascus containing 8 ascospores pairs of adjacent spores are identical in genetic constitution since the last division is mitotic and since the ascospores are contained in the ascus sac that holds them in a definite order determined by the direction of nuclear segregations during meiosis Since the four primary products are also arranged in sequence the pattern of genetic markers from a first division segregation can be distinguished from the markers from a second division segregation pattern See also EditMating of yeastReferences Edit Herskowitz I December 1988 Life cycle of the budding yeast Saccharomyces cerevisiae Microbiol Rev 52 4 536 53 doi 10 1128 MMBR 52 4 536 553 1988 PMC 373162 PMID 3070323 a b Ruderfer DM Pratt SC Seidel HS Kruglyak L September 2006 Population genomic analysis of outcrossing and recombination in yeast Nat Genet 38 9 1077 81 doi 10 1038 ng1859 PMID 16892060 S2CID 783720 Katz Ezov T Chang SL Frenkel Z Segre AV Bahalul M Murray AW Leu JY Korol A Kashi Y January 2010 Heterothallism in Saccharomyces cerevisiae isolates from nature effect of HO locus on the mode of reproduction Mol Ecol 19 1 121 31 doi 10 1111 j 1365 294X 2009 04436 x PMC 3892377 PMID 20002587 Birdsell JA Wills C 2003 The evolutionary origin and maintenance of sexual recombination A review of contemporary models Evolutionary Biology Series gt gt Evolutionary Biology Vol 33 pp 27 137 MacIntyre Ross J Clegg Michael T Eds Springer ISBN 978 0306472619 Elvira Horandl 2013 Meiosis and the Paradox of Sex in Nature Meiosis ISBN 978 953 51 1197 9 InTech DOI 10 5772 56542 Sugui JA Losada L Wang W Varga J Ngamskulrungroj P Abu Asab M Chang YC O Gorman CM Wickes BL Nierman WC Dyer PS Kwon Chung KJ 2011 Identification and characterization of an Aspergillus fumigatus supermater pair mBio 2 6 e00234 11 doi 10 1128 mBio 00234 11 PMC 3225970 PMID 22108383 O Gorman CM Fuller H Dyer PS January 2009 Discovery of a sexual cycle in the opportunistic fungal pathogen Aspergillus fumigatus Nature 457 7228 471 4 Bibcode 2009Natur 457 471O doi 10 1038 nature07528 PMID 19043401 S2CID 4371721 Rydholm C Szakacs G Lutzoni F April 2006 Low genetic variation and no detectable population structure in aspergillus fumigatus compared to closely related Neosartorya species Eukaryotic Cell 5 4 650 7 doi 10 1128 EC 5 4 650 657 2006 PMC 1459663 PMID 16607012 Horn BW Moore GG Carbone I 2009 Sexual reproduction in Aspergillus flavus Mycologia 101 3 423 9 doi 10 3852 09 011 PMID 19537215 S2CID 20648447 Moore GG Elliott JL Singh R Horn BW Dorner JW Stone EA Chulze SN Barros GG Naik MK Wright GC Hell K Carbone I 2013 Sexuality generates diversity in the aflatoxin gene cluster evidence on a global scale PLOS Pathog 9 8 e1003574 doi 10 1371 journal ppat 1003574 PMC 3757046 PMID 24009506 a b Henk DA Shahar Golan R Devi KR Boyce KJ Zhan N Fedorova ND Nierman WC Hsueh PR Yuen KY Sieu TP Kinh NV Wertheim H Baker SG Day JN Vanittanakom N Bignell EM Andrianopoulos A Fisher MC 2012 Clonality despite sex the evolution of host associated sexual neighborhoods in the pathogenic fungus Penicillium marneffei PLOS Pathog 8 10 e1002851 doi 10 1371 journal ppat 1002851 PMC 3464222 PMID 23055919 Westergaard M Mitchell HK 1947 Neurospora Part V A synthetic medium favoring sexual reproduction American Journal of Botany 34 573 577 doi 10 1002 j 1537 2197 1947 tb13032 x Nelson MA Metzenberg RL September 1992 Sexual development genes of Neurospora crassa Genetics 132 1 149 162 doi 10 1093 genetics 132 1 149 PMC 1205113 PMID 1356883 Fincham J RS Day PR 1963 Fungal Genetics Oxford UK Blackwell Scientific Publications ASIN B000W851KO Wagner RP Mitchell HK 1964 Genetics and Metabolism New York NY John Wiley and Sons ASIN B00BXTC5BO Retrieved from https en wikipedia org w index php title Heterothallism amp oldid 1142629966, wikipedia, wiki, book, books, library,

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