{"title":"Neurospora tetrasperma bibliography - Additions","authors":"D. D. Perkins","doi":"10.4148/1941-4765.1160","DOIUrl":null,"url":null,"abstract":"During the evolutionary divergence of N. tetrasperma from the eight-spored Neurospora species, ascus development was reprogrammed with the result that each of the four large ascospores is heterokaryotic, containing nuclei of both mating types, and germlings are self-fertile. Unique features of genome oganization, cell biology, and population structure have attracted investigators to use this pseudohomothallic, four-spored species for a wide range of studies. A bibliography listing 164 publications was published in 1994 in Fungal Genetics Newsletter 41:72-78. Eighty-six additional publications are listed here. In addition to recent papers, these include some theses, abstracts, and papers that were omitted from the previous list. Creative Commons License This work is licensed under a Creative Commons Attribution-Share Alike 4.0 License. This special paper is available in Fungal Genetics Reports: http://newprairiepress.org/fgr/vol50/iss1/14 24 Fungal Genetics Newsletter Neurospora tetrasperm a bibliography – Additions David D. Perkins Department of Biological Sciences, Stanford University, Stanford, CA 94305-5020. Fungal Genet. Newsl. 50:24-26 During the evolutionary divergence of N. tetrasperma from the eight-spored Neurospora species, ascus development was reprogrammed with the result that each of the four large ascospores is heterokaryotic, containing nuclei of both mating types, and germlings are self-fertile. Unique features of genome oganization, cell biology, and population structure have attracted investigators to use this pseudohomothallic, four-spored species for a wide range of studies. A bibliography listing 164 publications was published in 1994 in Fungal Genetics.Newsletter 41:72-78. Eighty-six additional publications are listed here. In addition to recent papers, these include some theses, abstracts, and papers that were omitted from the previous list. Adhvaryu K.K., and R. Maheshwari. 2002. Heterogeneity in NTS of rDNA in localized populations of Neurospora. Curr. Sci. 82:1015-1020. Agarwal, C. P., and R. K. S. Chauhan. 1976. Neurospora tetrasperma: New record of its occurrence in Indian soil and its cellulolytic activity. Proc. Indian Nat. Sci. Acad., Part B: Biol. Sci. 42:122-124. Ardizzi, J. P., and A. M. Srb. 1981 . “E-like” ascospore excision mutants in Neurospora tetrasperma resistant to either p-DLfluorophenylalanine or methyl benzimidazol-2-yl carbamate. Neurospora Newslett. 28:6. Arganoza, M. T., J. Min, Z. Hu, and R. A. Akins. 1994. Distribution of seven homology groups of mitochondrial plasmids in Neurospora: Evidence for widespread mobility between species in nature. Curr. Genet. 26:62-73. Attoh, G. T . 1986. Ribosomal DN A systematics of homothallic species of Neurospora: A phylogenetic analysis. Ph.D. thesis, Howard University: Diss. Abstr. Intl. 47-10B:4060. Belmans, D. L., A. J. van Laere, and J. A. van Assche. 1983. Effect of n-alcohols and high pressure on the heat activation of Neurospora tetrasperma ascospores. Arch. Microbiol. 134:49-51. Bennett, S. M., and H. B. Howe, Jr. 1977. Development of the sexual cycle in Neurospora tetrasperma. Assoc. Southeast Biol. Bull. 24:36-37. (Abstr.) Bhat, A., and D. P. Kasbekar. 2001. Escape from repeat-induced point mutation of a gene-sized duplication in Neurospora crassa crosses that are heterozygous for a larger chromosome segment duplication. Genetics 157:1581-1590. Bistis, G . N. 1996. T richogynes and fertilization in uniand bimating type colonies of Neurospora tetrasperma. Fungal Genet. Biol. 20:93-98. Bok, J.-W., and A. J. F. Griffiths. 2000. Possible benefits of kalilo plasmids to their Neurospora hosts. Plasmid 43:176-180. Bok, J.-W., C. He, and A. J. F. Griffiths. 1999. T ransfer of Neurospora kalilo plasmids among species and strains by introgression. Curr. Genet. 36:275-281. Buller, A. H. R. 1943. Sex and inheritance of lethal factors in Neurospora tetrasperma. Unpublished manuscrip t deposited in the Library of the Royal Botanic Gardens, Kew. [See G. R. Bisby. 1950. Editor’s note in A. H. R. Buller. Researches on Fungi, vol.7, p. xv. Univ.Toronto Press. Burk, A. G., and S. M. Srb. 1977. Effect of biotin deficiency on formation of ascospores in Neurospora tetrasperma. Genetics 86:s8-s9. (Abstr.) Calhoun, W. F. 1971. Inhibition of perithecial development in Neurospora tetrasperma. Ph.D. Thesis, Univ. Georgia. Diss. Abstr. 32:5342-B. Calhoun, F ., and H . B. Howe, Jr. 1972. Alpha-glucose and beta-glucose utilization by Neurospora tetrasperma. Microbiologica 5:53-56. Cutter , V. M ., Jr. 1946. T he chromosomes of Neurospora tetrasperma. Mycologia 38:693-698. Debets, A., A. van Mourik, A. J. F. Griffiths, and R. F. Hoekstra. 2001 . Stable polymorphism for the kalilo senescence plasmid in Hawaiian populations of Neurospora. Fungal Genet. Newslett. 48 (Suppl.):62. (Abstr.) Dettman, J. R., F. M. Harbinski, and J. W. Taylor. 2001. Ascospore morphology is a poor predictor of the phylogenetic relationships of Neurospora and Gelasinospora. Fungal Genet. Biol. 34:44-61. Dettman, J . R., D. J. Jacobson, and J. W. Taylor. 2002. Phylogenetic species recognition in Neurospora. Fungal Genet. Newslett. 49 (Suppl.):19 . (Abstr.) Dettman, J . R., and J. W. Taylor. 2003. M icrosatellite evolution in Neurospora. Fungal Genet. Newslett. 50 (Suppl.):144. (Abstr.) Dettman, J. R., D. J. Jacobson and J. W. Taylor. 2003. A multilocus geneological approach to phylogenetic species recognition in the model eukaryote Neurospora. Evolution (accepted subject to revision) Dodge, B. O. 1932. The non-sexual and the sexual functions of microconidia of Neurospora. Bull. Torrey Bot. Club 59:347360. Dodge, B. O. 1939. A new dominant lethal, E, in Neurospora tetrasperma. Science 89:401. (Abstr.) Dodge, B. O., J. R. Singleton, and A. Rolnick. 1948. Studies re lative to a temporary reversion of Neurospora tetrasperma to an 8-spored type. Science 108:680. (Abstr.) Duran, R., and P. M. Gray. 1989. Nuclear DNA, an adjunct to morphology in fungal taxonomy. Mycotaxon 36:205-219. Freitag, M., R. L. Williams, G. O. Kothe, and E. U. Selker. 2002. A cytosine methyltransferase homologue is essential for repeat-induced point mutation in Neurospora crassa . Proc. Nat. Acad. Sci. U.S.A. 99:8802-8807. Gallegos, A., D. J. Jacobson, M. P. Skupski, G. Saenz, and D. O. Natvig. 1998. Recombination on the mating-type chromosome in Neurospora tetrasperma. Neurospora 1998 (Asilomar Conference), p.20 . (Abstr.) Gallegos, A., D. J. Jacobson, N. B. Raju, M. P. Skupski, and D. O. Natvig. 2000. Suppressed recombination and a pairing anomaly on the mating-type chromosome of Neurospora tetrasperma. Genetics 154:623-633. 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引用次数: 2
Abstract
During the evolutionary divergence of N. tetrasperma from the eight-spored Neurospora species, ascus development was reprogrammed with the result that each of the four large ascospores is heterokaryotic, containing nuclei of both mating types, and germlings are self-fertile. Unique features of genome oganization, cell biology, and population structure have attracted investigators to use this pseudohomothallic, four-spored species for a wide range of studies. A bibliography listing 164 publications was published in 1994 in Fungal Genetics Newsletter 41:72-78. Eighty-six additional publications are listed here. In addition to recent papers, these include some theses, abstracts, and papers that were omitted from the previous list. Creative Commons License This work is licensed under a Creative Commons Attribution-Share Alike 4.0 License. This special paper is available in Fungal Genetics Reports: http://newprairiepress.org/fgr/vol50/iss1/14 24 Fungal Genetics Newsletter Neurospora tetrasperm a bibliography – Additions David D. Perkins Department of Biological Sciences, Stanford University, Stanford, CA 94305-5020. Fungal Genet. Newsl. 50:24-26 During the evolutionary divergence of N. tetrasperma from the eight-spored Neurospora species, ascus development was reprogrammed with the result that each of the four large ascospores is heterokaryotic, containing nuclei of both mating types, and germlings are self-fertile. Unique features of genome oganization, cell biology, and population structure have attracted investigators to use this pseudohomothallic, four-spored species for a wide range of studies. A bibliography listing 164 publications was published in 1994 in Fungal Genetics.Newsletter 41:72-78. Eighty-six additional publications are listed here. In addition to recent papers, these include some theses, abstracts, and papers that were omitted from the previous list. Adhvaryu K.K., and R. Maheshwari. 2002. Heterogeneity in NTS of rDNA in localized populations of Neurospora. Curr. Sci. 82:1015-1020. Agarwal, C. P., and R. K. S. Chauhan. 1976. Neurospora tetrasperma: New record of its occurrence in Indian soil and its cellulolytic activity. Proc. Indian Nat. Sci. Acad., Part B: Biol. Sci. 42:122-124. Ardizzi, J. P., and A. M. Srb. 1981 . “E-like” ascospore excision mutants in Neurospora tetrasperma resistant to either p-DLfluorophenylalanine or methyl benzimidazol-2-yl carbamate. Neurospora Newslett. 28:6. Arganoza, M. T., J. Min, Z. Hu, and R. A. Akins. 1994. Distribution of seven homology groups of mitochondrial plasmids in Neurospora: Evidence for widespread mobility between species in nature. Curr. Genet. 26:62-73. Attoh, G. T . 1986. Ribosomal DN A systematics of homothallic species of Neurospora: A phylogenetic analysis. Ph.D. thesis, Howard University: Diss. Abstr. Intl. 47-10B:4060. Belmans, D. L., A. J. van Laere, and J. A. van Assche. 1983. Effect of n-alcohols and high pressure on the heat activation of Neurospora tetrasperma ascospores. Arch. Microbiol. 134:49-51. Bennett, S. M., and H. B. Howe, Jr. 1977. Development of the sexual cycle in Neurospora tetrasperma. Assoc. Southeast Biol. Bull. 24:36-37. (Abstr.) Bhat, A., and D. P. Kasbekar. 2001. Escape from repeat-induced point mutation of a gene-sized duplication in Neurospora crassa crosses that are heterozygous for a larger chromosome segment duplication. Genetics 157:1581-1590. Bistis, G . N. 1996. T richogynes and fertilization in uniand bimating type colonies of Neurospora tetrasperma. Fungal Genet. Biol. 20:93-98. Bok, J.-W., and A. J. F. Griffiths. 2000. Possible benefits of kalilo plasmids to their Neurospora hosts. Plasmid 43:176-180. Bok, J.-W., C. He, and A. J. F. Griffiths. 1999. T ransfer of Neurospora kalilo plasmids among species and strains by introgression. Curr. Genet. 36:275-281. Buller, A. H. R. 1943. Sex and inheritance of lethal factors in Neurospora tetrasperma. Unpublished manuscrip t deposited in the Library of the Royal Botanic Gardens, Kew. [See G. R. Bisby. 1950. Editor’s note in A. H. R. Buller. Researches on Fungi, vol.7, p. xv. Univ.Toronto Press. Burk, A. G., and S. M. Srb. 1977. Effect of biotin deficiency on formation of ascospores in Neurospora tetrasperma. Genetics 86:s8-s9. (Abstr.) Calhoun, W. F. 1971. Inhibition of perithecial development in Neurospora tetrasperma. Ph.D. Thesis, Univ. Georgia. Diss. Abstr. 32:5342-B. Calhoun, F ., and H . B. Howe, Jr. 1972. Alpha-glucose and beta-glucose utilization by Neurospora tetrasperma. Microbiologica 5:53-56. Cutter , V. M ., Jr. 1946. T he chromosomes of Neurospora tetrasperma. Mycologia 38:693-698. Debets, A., A. van Mourik, A. J. F. Griffiths, and R. F. Hoekstra. 2001 . Stable polymorphism for the kalilo senescence plasmid in Hawaiian populations of Neurospora. Fungal Genet. Newslett. 48 (Suppl.):62. (Abstr.) Dettman, J. R., F. M. Harbinski, and J. W. Taylor. 2001. Ascospore morphology is a poor predictor of the phylogenetic relationships of Neurospora and Gelasinospora. Fungal Genet. Biol. 34:44-61. Dettman, J . R., D. J. Jacobson, and J. W. Taylor. 2002. Phylogenetic species recognition in Neurospora. Fungal Genet. Newslett. 49 (Suppl.):19 . (Abstr.) Dettman, J . R., and J. W. Taylor. 2003. M icrosatellite evolution in Neurospora. Fungal Genet. Newslett. 50 (Suppl.):144. (Abstr.) Dettman, J. R., D. J. Jacobson and J. W. Taylor. 2003. A multilocus geneological approach to phylogenetic species recognition in the model eukaryote Neurospora. Evolution (accepted subject to revision) Dodge, B. O. 1932. The non-sexual and the sexual functions of microconidia of Neurospora. Bull. Torrey Bot. Club 59:347360. Dodge, B. O. 1939. A new dominant lethal, E, in Neurospora tetrasperma. Science 89:401. (Abstr.) Dodge, B. O., J. R. Singleton, and A. Rolnick. 1948. Studies re lative to a temporary reversion of Neurospora tetrasperma to an 8-spored type. Science 108:680. (Abstr.) Duran, R., and P. M. Gray. 1989. Nuclear DNA, an adjunct to morphology in fungal taxonomy. Mycotaxon 36:205-219. Freitag, M., R. L. Williams, G. O. Kothe, and E. U. Selker. 2002. A cytosine methyltransferase homologue is essential for repeat-induced point mutation in Neurospora crassa . Proc. Nat. Acad. Sci. U.S.A. 99:8802-8807. Gallegos, A., D. J. Jacobson, M. P. Skupski, G. Saenz, and D. O. Natvig. 1998. Recombination on the mating-type chromosome in Neurospora tetrasperma. Neurospora 1998 (Asilomar Conference), p.20 . (Abstr.) Gallegos, A., D. J. Jacobson, N. B. Raju, M. P. Skupski, and D. O. Natvig. 2000. Suppressed recombination and a pairing anomaly on the mating-type chromosome of Neurospora tetrasperma. Genetics 154:623-633. Published by New Prairie Press, 2017
在四曲霉与八孢子神经孢子的进化分化过程中,子囊孢子的发育被重新编程,结果是四个大子囊孢子中的每一个都是异核的,包含两种交配类型的细胞核,并且胚芽是自育的。基因组组织、细胞生物学和种群结构的独特特征吸引了研究人员使用这种假同型四孢子物种进行广泛的研究。1994年发表于《真菌遗传学通讯》41:72-78。这里列出了86种其他出版物。除了最近的论文外,还包括一些论文、摘要和之前列表中遗漏的论文。本作品采用知识共享署名-相同方式共享4.0许可协议。这篇特别的论文可在真菌遗传学报告:http://newprairiepress.org/fgr/vol50/iss1/14 24真菌遗传学通讯神经孢子四虫参考书目-添加David D. Perkins生物科学系,斯坦福大学,斯坦福,CA 94305-5020。真菌麝猫。在四曲霉从八孢子神经孢子的进化分化过程中,子囊孢子的发育被重新编程,结果是四个大子囊孢子中的每一个都是异核的,包含两种交配类型的细胞核,并且胚芽是自育的。基因组组织、细胞生物学和种群结构的独特特征吸引了研究人员使用这种假同型四孢子物种进行广泛的研究。1994年在《真菌遗传学》上发表了164篇文献的参考书目。通讯41:72 - 78。这里列出了86种其他出版物。除了最近的论文外,还包括一些论文、摘要和之前列表中遗漏的论文。Adhvaryu k.k.和R. Maheshwari, 2002。神经孢子虫局部种群rDNA NTS的异质性。咕咕叫。Sci 82:1015 - 1020。阿加瓦尔,C. P.和R. K. S. Chauhan. 1976。四asperma神经孢子虫:其在印度土壤中的出现及其纤维素分解活性的新记录。印度自然科学进展。第二部分:生物学。Sci 42:122 - 124。Ardizzi, J. P.和A. M. Srb. 1981。四asperma神经孢子虫的“样”子囊孢子切除突变体对p- dl氟苯丙氨酸或甲基苯并咪唑-2-酰基氨基甲酸酯具有抗性。神经孢子病通讯,28:6。胡振中,闵志明,胡振中,阿金斯,1994。神经孢子虫线粒体质粒7个同源群的分布:自然界物种间广泛流动的证据。咕咕叫。麝猫。26:62 - 73。阿托斯,g.t.。1986. 神经孢子虫同属种核糖体dna系统:系统发育分析。博士论文,霍华德大学:Diss。Abstr。Intl。47-10B: 4060。Belmans, d.l., A. J. van Laere, and J. A. van Assche. 1983。正醇和高压对四曲霉神经孢子热活化的影响。拱门。Microbiol 134:49-51。班尼特,s.m.和h.b. Howe, Jr. 1977。四asperma神经孢子虫性周期的发育。Assoc。东南杂志。牛,24:36-37。(Abstr)。Bhat, A.和D. P. Kasbekar. 2001。从重复诱导的一个基因大小的重复点突变中逃脱的神经孢子虫杂交是杂合的一个更大的染色体片段重复。遗传学157:1581 - 1590。比蒂斯,G。n 1996。四asperma神经孢子虫单翅和双翅型菌落的繁殖和受精。真菌麝猫。生物20:93 - 98。博克,J.-W。A. J. F. Griffiths, 2000。辣椒质粒对其神经孢子虫宿主的可能益处。质粒43:176 - 180。博克,J.-W。, C. He, A. J. F. Griffiths. 1999。神经孢子虫质粒在种与株间的渗透转移。咕咕叫。麝猫。36:275 - 281。a·h·r·布勒,1943。四asperma神经孢子虫致死因素的性别和遗传。未发表的手稿存放在邱园皇家植物园图书馆。[见比斯比,1950。a·h·r·布勒的编者按。真菌研究,第7卷,第15页。Univ.Toronto出版社。博克,a.g.和s.m. Srb. 1977。生物素缺乏对四asperma神经孢子形成子囊孢子的影响。遗传学86:s8-s9。(Abstr)。卡尔霍恩,1971。四asperma神经孢子虫鞘周发育的抑制作用。博士论文,美国佐治亚大学。迪斯。Abstr 32:5342-B。卡尔霍恩,F .和H .。B. Howe, Jr. 1972。四asperma神经孢子菌对α -葡萄糖和β -葡萄糖的利用。Microbiologica 5:53-56。卡特,小v·M·1946四asperma神经孢子虫的染色体。Mycologia 38:693 - 698。Debets, A. van Mourik, A. J. F. Griffiths和R. F. Hoekstra. 2001。夏威夷神经孢子虫种群中卡利洛衰老质粒的稳定多态性。真菌麝猫。通讯,48(增刊):62。(Abstr)。德特曼,J. R., F. M. Harbinski, J. W. Taylor. 2001。
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