The Neurospora crassa colonial temperature sensitive 2, 4 and 5 (cot-2, cot-4 and cot-5) genes encode regulatory and structural proteins required for hyphal elongation and branching

Zipi Resheat-Eini, A. Zelter, R. Gorovits, N. Read, O. Yarden
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This regular paper is available in Fungal Genetics Reports: http://newprairiepress.org/fgr/vol55/iss1/8 32 Fungal Genetics Reports The Neurospora crassa colonial temperature sensitive 2, 4 and 5 (cot-2, cot-4 and cot-5) genes encode regulatory and structural proteins required for hyphal elongation and branching Zipi Resheat-Eini, Alex Zelter, Rena Gorovits, Nick D. Read and Oded Yarden* Department of Plant Pathology and Microbiology, The Otto Warburg Minerva Center for Agricultural Biotechnology, Faculty of Agricultural, Food and Environmental Quality Sciences, The Hebrew University of Jerusalem, Rehovot, 76100, Israel and Fungal Cell Biology Group, Institute of Cell and Molecular Biology, University of Edinburgh, Rutherford Building, Edinburgh EH9 3JH, UK. *corresponding author, email: Oded.Yarden@huji.ac.il Fungal Genetics Reports 55:32-36 The morphology and the genetic defects of the Neurospora crassa colonial temperature-sensitive-2, -4 and -5 mutants were analyzed. cot-2 is allelic to gs-1 and encodes a component of the glucan synthesis process. cot-4 encodes the catalytic subunit of a type 2B phosphatase and is allelic to calcineurin (cna-1). cot-5 encodes a homologue of the S. cerevisiae ALG2 manosyltransferase-encoding gene, a component of the dolichol pathway. A group of five non-allelic Neurospora crassa colonial temperature sensitive (cot) mutants was described by Garnjobst and Tatum (1967). The cot-1 gene was found to encode a Ser/Thr protein kinase (Yarden et al. 1992) which is the founding member of the NDR kinase family. The nature of the cot-3 defect has also been analyzed and the cot-3 gene was found to encode protein elongation factor 2 (Propheta et al. 2001). In order to expand our understanding of the genetic defects that can confer abnormal hyphal elongation/branching patterns, we have performed morphological and genetic analyses of the three remaining cot mutants isolated by Garnjobst and Tatum. We found that even though they all exhibit compact temperaturesensitive macroscopic colonial features, their microscopic hyphal morphology and branching patterns differ. Furthermore, the genetic defects involved in conferring their phenotypes include both regulatory as well as structural factors, all of which are required for maintaining proper hyphal elongation and branching patterns. Confocal microscopic examination, using the membrane-selective dye FM4-64 (as described by Hickey et al. 2005) of Neurospora crassa wild-type (74-OR23-1A; FGSC987), cot-1 (FGSC 4065), cot-2 (FGSC 1512), cot-3 (FGSC 1517), cot4 (FGSC 3600) and cot-5 (FGSC 1362), revealed significant morphological differences between the different strains (Fig. 1). As the morphological features of cot-1 and cot-3 have been studied in depth (Collinge and Trinci, 1974; Collinge et al. 1978; Propheta et al. 2001), we focused on the quantification of the observed differences on cot-2, cot-4 and cot-5. Hyphal extension rates of cot-2 cot-4 and cot-5 were measured on a standard solid medium at permissive and restrictive conditions. All of the mutants exhibited a significant reduction (75 to 99%) in elongation rates (to 0.15±0.03 mm/h, 0.27±0.05 mm/h and negligible elongation for cot-2, cot-4 and cot-5, respectively) and an increase in branching rates when cultured at the restrictive temperature. Even though the mutant's phenotypes are clearly temperature sensitive, we found that their branching rates were significantly higher (60 to 160%) even at the permissive temperatures (Table 1). For the most part, the hyperbranching patterns observed are lateral, rather than apical (Watters et al. 2000). Nonetheless, some apical/dichotomous branching was evident in the cot-5 strain (regardless of temperature; Fig. 1j-k). Figure 1. Morphology of wild type and colonial temperature sensitive strains of N. crassa at permissive (24 C) and restrictive (37 C) temperatures. Fungi were stained with FM4-64 and imaged using a confocal microscope. (a) cot-1 grown at 24 C; (b) cot-1, 37 C; (c) wild type, 37 C; (d) cot-2, 24 C; (e) cot-2, 37 C; (f) cot-3, 24 C; (g) cot-3, 37 C; (h) cot4, 24 C; (i) cot-4, 37 C; (j) cot-5, 24 C; (k) cot-5, 37 C. Bars are 50 um. Published by New Prairie Press, 2017","PeriodicalId":12490,"journal":{"name":"Fungal Genetics Reports","volume":"1 1","pages":"32-36"},"PeriodicalIF":0.0000,"publicationDate":"2008-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"6","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Fungal Genetics Reports","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.4148/1941-4765.1088","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 6

Abstract

The morphology and the genetic defects of theNeurospora crassa colonial temperature-sensitive-2, -4 and -5 mutants were analyzed. cot-2 is allelic to gs-1 and encodes a component of the glucan synthesis process. cot-4 encodes the catalytic subunit of a type 2B phosphatase and is allelic to calcineurin (cna-1). cot-5 encodes a homologue of the S. cerevisiae ALG2 manosyltransferase-encoding gene, a component of the dolichol pathway. Creative Commons License This work is licensed under a Creative Commons Attribution-Share Alike 4.0 License. This regular paper is available in Fungal Genetics Reports: http://newprairiepress.org/fgr/vol55/iss1/8 32 Fungal Genetics Reports The Neurospora crassa colonial temperature sensitive 2, 4 and 5 (cot-2, cot-4 and cot-5) genes encode regulatory and structural proteins required for hyphal elongation and branching Zipi Resheat-Eini, Alex Zelter, Rena Gorovits, Nick D. Read and Oded Yarden* Department of Plant Pathology and Microbiology, The Otto Warburg Minerva Center for Agricultural Biotechnology, Faculty of Agricultural, Food and Environmental Quality Sciences, The Hebrew University of Jerusalem, Rehovot, 76100, Israel and Fungal Cell Biology Group, Institute of Cell and Molecular Biology, University of Edinburgh, Rutherford Building, Edinburgh EH9 3JH, UK. *corresponding author, email: Oded.Yarden@huji.ac.il Fungal Genetics Reports 55:32-36 The morphology and the genetic defects of the Neurospora crassa colonial temperature-sensitive-2, -4 and -5 mutants were analyzed. cot-2 is allelic to gs-1 and encodes a component of the glucan synthesis process. cot-4 encodes the catalytic subunit of a type 2B phosphatase and is allelic to calcineurin (cna-1). cot-5 encodes a homologue of the S. cerevisiae ALG2 manosyltransferase-encoding gene, a component of the dolichol pathway. A group of five non-allelic Neurospora crassa colonial temperature sensitive (cot) mutants was described by Garnjobst and Tatum (1967). The cot-1 gene was found to encode a Ser/Thr protein kinase (Yarden et al. 1992) which is the founding member of the NDR kinase family. The nature of the cot-3 defect has also been analyzed and the cot-3 gene was found to encode protein elongation factor 2 (Propheta et al. 2001). In order to expand our understanding of the genetic defects that can confer abnormal hyphal elongation/branching patterns, we have performed morphological and genetic analyses of the three remaining cot mutants isolated by Garnjobst and Tatum. We found that even though they all exhibit compact temperaturesensitive macroscopic colonial features, their microscopic hyphal morphology and branching patterns differ. Furthermore, the genetic defects involved in conferring their phenotypes include both regulatory as well as structural factors, all of which are required for maintaining proper hyphal elongation and branching patterns. Confocal microscopic examination, using the membrane-selective dye FM4-64 (as described by Hickey et al. 2005) of Neurospora crassa wild-type (74-OR23-1A; FGSC987), cot-1 (FGSC 4065), cot-2 (FGSC 1512), cot-3 (FGSC 1517), cot4 (FGSC 3600) and cot-5 (FGSC 1362), revealed significant morphological differences between the different strains (Fig. 1). As the morphological features of cot-1 and cot-3 have been studied in depth (Collinge and Trinci, 1974; Collinge et al. 1978; Propheta et al. 2001), we focused on the quantification of the observed differences on cot-2, cot-4 and cot-5. Hyphal extension rates of cot-2 cot-4 and cot-5 were measured on a standard solid medium at permissive and restrictive conditions. All of the mutants exhibited a significant reduction (75 to 99%) in elongation rates (to 0.15±0.03 mm/h, 0.27±0.05 mm/h and negligible elongation for cot-2, cot-4 and cot-5, respectively) and an increase in branching rates when cultured at the restrictive temperature. Even though the mutant's phenotypes are clearly temperature sensitive, we found that their branching rates were significantly higher (60 to 160%) even at the permissive temperatures (Table 1). For the most part, the hyperbranching patterns observed are lateral, rather than apical (Watters et al. 2000). Nonetheless, some apical/dichotomous branching was evident in the cot-5 strain (regardless of temperature; Fig. 1j-k). Figure 1. Morphology of wild type and colonial temperature sensitive strains of N. crassa at permissive (24 C) and restrictive (37 C) temperatures. Fungi were stained with FM4-64 and imaged using a confocal microscope. (a) cot-1 grown at 24 C; (b) cot-1, 37 C; (c) wild type, 37 C; (d) cot-2, 24 C; (e) cot-2, 37 C; (f) cot-3, 24 C; (g) cot-3, 37 C; (h) cot4, 24 C; (i) cot-4, 37 C; (j) cot-5, 24 C; (k) cot-5, 37 C. Bars are 50 um. Published by New Prairie Press, 2017
粗草神经孢子虫菌落温度敏感基因2、4和5 (cot-2、cot-4和cot-5)编码菌丝伸长和分支所需的调控蛋白和结构蛋白
分析了粗草eurospora colonia温度敏感突变体-2、-4和-5的形态和遗传缺陷。Cot-2是gs-1的等位基因,编码葡聚糖合成过程的一个组成部分。cot-4编码2B型磷酸酶的催化亚基,与钙调磷酸酶(na-1)等位。cot-5编码酿酒葡萄球菌ALG2锰基转移酶编码基因的同源物,该基因是乙醇途径的一个组成部分。本作品采用知识共享署名-相同方式共享4.0许可协议。这篇常规论文发表在《真菌遗传学报告》上:http://newprairiepress.org/fgr/vol55/iss1/8 32真菌遗传学报道:粗神经孢子虫菌落温敏2、4和5 (cot-2、cot-4和cot-5)基因编码菌丝伸长和分枝所需的调控和结构蛋白。Zipi Resheat-Eini, Alex Zelter, Rena Gorovits, Nick D. Read和Oded Yarden*, Otto Warburg Minerva农业生物技术中心,农业学院,植物病理学和微生物学食品和环境质量科学,耶路撒冷希伯来大学,Rehovot, 76100,以色列;真菌细胞生物学组,细胞和分子生物学研究所,爱丁堡大学,卢瑟福大楼,爱丁堡EH9 3JH,英国。*通讯作者,email: Oded.Yarden@huji.ac.il真菌遗传学报告55:32-36分析了粗神经孢子虫菌落温度敏感-2、-4和-5突变体的形态和遗传缺陷。Cot-2是gs-1的等位基因,编码葡聚糖合成过程的一个组成部分。cot-4编码2B型磷酸酶的催化亚基,与钙调磷酸酶(na-1)等位。cot-5编码酿酒葡萄球菌ALG2锰基转移酶编码基因的同源物,该基因是乙醇途径的一个组成部分。Garnjobst和Tatum(1967)描述了一组5个非等位基因的草神经孢子虫(Neurospora crassa)群体温度敏感突变体。cot-1基因被发现编码丝氨酸/苏氨酸蛋白激酶(Yarden et al. 1992),该蛋白激酶是NDR激酶家族的创始成员。对cot-3缺陷的性质也进行了分析,发现cot-3基因编码蛋白延伸因子2 (Propheta et al. 2001)。为了扩大我们对导致菌丝异常伸长/分枝模式的遗传缺陷的理解,我们对Garnjobst和Tatum分离的三个剩余的cot突变体进行了形态学和遗传学分析。我们发现,尽管它们都表现出致密的温度敏感的宏观群体特征,但它们的微观菌丝形态和分支模式不同。此外,遗传缺陷涉及赋予其表型包括调控和结构因素,所有这些都需要维持适当的菌丝伸长和分支模式。共聚焦显微镜检查,使用膜选择性染料FM4-64(如Hickey et al. 2005所述)的粗神经孢子虫野生型(74-OR23-1A;FGSC987), cot-1 (FGSC 4065), cot-2 (FGSC 1512), cot-3 (FGSC 1517), cot4 (FGSC 3600)和cot-5 (FGSC 1362)显示不同菌株之间存在显著的形态学差异(图1)。由于对cot-1和cot-3的形态学特征进行了深入研究(Collinge和Trinci, 1974;Collinge et al. 1978;Propheta et al. 2001),我们专注于对cot-2、cot-4和cot-5观察到的差异进行量化。在允许和限制条件下,在标准固体培养基上测量了cot-2、cot-4和cot-5的菌丝延伸率。在限制温度下培养时,所有突变体的伸长率均显著降低(75%至99%)(分别为0.15±0.03 mm/h、0.27±0.05 mm/h, cot-2、cot-4和cot-5的伸长率可忽略不计),分枝率增加。尽管突变体的表型明显对温度敏感,但我们发现即使在允许的温度下,它们的分支率也明显更高(60%至160%)(表1)。在大多数情况下,观察到的超分支模式是侧向的,而不是顶端的(Watters et al. 2000)。尽管如此,在cot-5菌株中,一些根尖/二分分支是明显的(与温度无关;图1 j - k)。图1所示。允许温度(24℃)和限制温度(37℃)下野生型和群体温度敏感菌株的形态。真菌用FM4-64染色,并用共聚焦显微镜成像。(a) 24℃下生长的cot-1;(b) cot- 1,37 C;(c)野生型,37℃;(d) cot- 2,24 C;(e) cot- 2,37℃;(f) cot- 3,24℃;(g) cot- 3,37℃;(h) cot4, 24℃;(i) cot- 4,37 C;(j) cot- 5,24 C;(k) cot-5, 37℃,bar为50 um。新草原出版社2017年出版
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