{"title":"锂离子对粗神经孢子孢子大小的影响","authors":"B. Aase, I. W. Jolma, P. Ruoff","doi":"10.4148/1941-4765.1113","DOIUrl":null,"url":null,"abstract":"Lithium (Li) ions are known to affect Neurospora crassa’s growth speed and circadian clock period, while elevated temperatures abolish these influences. We wondered whether Li has also an effect on conidia size. We used cryo-SEM to investigate this question and report here the results of 1720 measurements showing that at 20°C the long and short conidial axes are significantly reduced at high Li concentrations (10-15 mM), while the ratio between the long and short axes remains approximately constant. An increased temperature (30°C) appears to abolish the Li effect on conidia size. 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/vol53/iss1/10 34 Fungal Genetics Newsletter Influence of Lithium ions on conidiophore size in Neurospora crassa Bodil Aase, Ingunn W. Jolma and Peter Ruoff Department of Mathematics and Natural Science, University of Stavanger, N-4036 Stavanger, Norway corresponding author. email: peter.ruoff@uis.no. # Fungal Genetics Newsletter 53:34-36 Lithium (Li) ions are known to affect Neurospora crassa’s growth speed and circadian clock period, while elevated temperatures abolish these influences. We wondered whether Li has also an effect on conidia size. We used cryo-SEM to investigate this question and report here the results of 1720 measurements showing that at 20°C the long and short conidial axes are significantly reduced at high Li concentrations (10-15 mM), while the ratio between the long and short axes remains approximately constant. An increased temperature (30°C) appears to abolish the Li effect on conidia size. Lithium (Li) has a profound influence on Neurospora crassa’s growth rate and circadian period (Engelmann 1987; Davis 2000; Dunlap and Loros 2004). Typically, at extracellular concentrations of 10 mM LiCl, the growth rate is significantly reduced and the circadian clock begins to get disrupted (Engelmann 1987; Lakin-Thomas 1993; Jolma et al. 2006). Interestingly, increased temperature can abolish the Li effect, possibly by an increased dissociation between Li and its assumed targets (Jolma et al. 2006). Because of the macroscopically distinct differences in conidiation when Neurospora is grown in the presence or absence of Li, we wondered whether there might be also a difference in microscopic conidiation, for example conidia size. In order to answer this question, we performed a study using a Zeiss Supra VP35 scanning electron microscope (SEM) with a Polaron cryo stage. The bd a strain (FGSC #1859) was grown on Petri dishes in LD (12h:12h) at 20°C or 30°C using Vogel’s medium as previously described (Jolma et al. 2006). Li was added to the medium as LiCl. Samples were taken from Petri dishes that showed approximately the same amount of total growth (=growth speed X growth time). Because of the dependence of the speed of this organism’s growth on temperature and LiCl concentrations (Jolma et al. 2006) the growth time prior sampling varied as shown in Table 1. Table 1: Growth times prior analysis T, °C LiCl, mM GT, days 20 0 3 20 5 3 20 10 10 20 15 10 30 10 1 T: temperature; LiCl: concentration of LiCl; GT: growing time Figure 1. Measurement of conidia size as long and short axis, l and s, respectively. The picture shows conidia grown at 20°C with 15 mM Li. Samples were cut out using a cork-borer covering the growth zone and approximately 5 mm behind the growth zone. The cut-out samples were put on a Al-stub that had glue with colloidal graphite on its surface. The glued sample was rapidly frozen in nitrogen slush and then transferred to the pre-cooled SEM stage. Samples were then coated with a gold-palladium alloy for 80 seconds. In the SEM analysis the ‘In-Lens’ detector of the microscope was used. Conidia have an ellipsoidal-like shape and the long and short axes l and s (Fig. 1), which could be determined directly on the sample, were used as an approximate measure for conidia size. Published by New Prairie Press, 2017","PeriodicalId":12490,"journal":{"name":"Fungal Genetics Reports","volume":"29 1","pages":"34-36"},"PeriodicalIF":0.0000,"publicationDate":"2006-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Influence of Lithium ions on conidiophore size in Neurospora crassa\",\"authors\":\"B. Aase, I. W. Jolma, P. Ruoff\",\"doi\":\"10.4148/1941-4765.1113\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Lithium (Li) ions are known to affect Neurospora crassa’s growth speed and circadian clock period, while elevated temperatures abolish these influences. We wondered whether Li has also an effect on conidia size. We used cryo-SEM to investigate this question and report here the results of 1720 measurements showing that at 20°C the long and short conidial axes are significantly reduced at high Li concentrations (10-15 mM), while the ratio between the long and short axes remains approximately constant. An increased temperature (30°C) appears to abolish the Li effect on conidia size. 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/vol53/iss1/10 34 Fungal Genetics Newsletter Influence of Lithium ions on conidiophore size in Neurospora crassa Bodil Aase, Ingunn W. Jolma and Peter Ruoff Department of Mathematics and Natural Science, University of Stavanger, N-4036 Stavanger, Norway corresponding author. email: peter.ruoff@uis.no. # Fungal Genetics Newsletter 53:34-36 Lithium (Li) ions are known to affect Neurospora crassa’s growth speed and circadian clock period, while elevated temperatures abolish these influences. We wondered whether Li has also an effect on conidia size. We used cryo-SEM to investigate this question and report here the results of 1720 measurements showing that at 20°C the long and short conidial axes are significantly reduced at high Li concentrations (10-15 mM), while the ratio between the long and short axes remains approximately constant. An increased temperature (30°C) appears to abolish the Li effect on conidia size. Lithium (Li) has a profound influence on Neurospora crassa’s growth rate and circadian period (Engelmann 1987; Davis 2000; Dunlap and Loros 2004). Typically, at extracellular concentrations of 10 mM LiCl, the growth rate is significantly reduced and the circadian clock begins to get disrupted (Engelmann 1987; Lakin-Thomas 1993; Jolma et al. 2006). Interestingly, increased temperature can abolish the Li effect, possibly by an increased dissociation between Li and its assumed targets (Jolma et al. 2006). Because of the macroscopically distinct differences in conidiation when Neurospora is grown in the presence or absence of Li, we wondered whether there might be also a difference in microscopic conidiation, for example conidia size. In order to answer this question, we performed a study using a Zeiss Supra VP35 scanning electron microscope (SEM) with a Polaron cryo stage. The bd a strain (FGSC #1859) was grown on Petri dishes in LD (12h:12h) at 20°C or 30°C using Vogel’s medium as previously described (Jolma et al. 2006). Li was added to the medium as LiCl. Samples were taken from Petri dishes that showed approximately the same amount of total growth (=growth speed X growth time). Because of the dependence of the speed of this organism’s growth on temperature and LiCl concentrations (Jolma et al. 2006) the growth time prior sampling varied as shown in Table 1. Table 1: Growth times prior analysis T, °C LiCl, mM GT, days 20 0 3 20 5 3 20 10 10 20 15 10 30 10 1 T: temperature; LiCl: concentration of LiCl; GT: growing time Figure 1. Measurement of conidia size as long and short axis, l and s, respectively. The picture shows conidia grown at 20°C with 15 mM Li. Samples were cut out using a cork-borer covering the growth zone and approximately 5 mm behind the growth zone. The cut-out samples were put on a Al-stub that had glue with colloidal graphite on its surface. The glued sample was rapidly frozen in nitrogen slush and then transferred to the pre-cooled SEM stage. Samples were then coated with a gold-palladium alloy for 80 seconds. In the SEM analysis the ‘In-Lens’ detector of the microscope was used. Conidia have an ellipsoidal-like shape and the long and short axes l and s (Fig. 1), which could be determined directly on the sample, were used as an approximate measure for conidia size. 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引用次数: 1
摘要
众所周知,锂离子会影响粗神经孢子虫的生长速度和生物钟周期,而升高的温度会消除这些影响。我们想知道Li是否也对分生孢子的大小有影响。我们使用冷冻扫描电镜(cro - sem)研究了这个问题,并在这里报告了1720年的测量结果,结果表明,在20°C时,在高Li浓度(10-15 mM)下,分生孢子的长轴和短轴显著减少,而长轴和短轴之间的比例保持大致不变。温度升高(30℃)似乎消除了Li对分生孢子大小的影响。本作品采用知识共享署名-相同方式共享4.0许可协议。这篇论文发表在《真菌遗传学报告:http://newprairiepress.org/fgr/vol53/iss1/10 34真菌遗传学通讯》上,锂离子对粗神经孢子虫Bodil Aase分生孢子大小的影响,Ingunn W. Jolma和Peter Ruoff,斯塔万格大学数学与自然科学系,N-4036斯塔万格,挪威。电子邮件:peter.ruoff@uis.no。#真菌遗传学通讯53:34-36已知锂离子会影响粗神经孢子虫的生长速度和生物钟周期,而升高的温度会消除这些影响。我们想知道Li是否也对分生孢子的大小有影响。我们使用冷冻扫描电镜(cro - sem)研究了这个问题,并在这里报告了1720年的测量结果,结果表明,在20°C时,在高Li浓度(10-15 mM)下,分生孢子的长轴和短轴显著减少,而长轴和短轴之间的比例保持大致不变。温度升高(30℃)似乎消除了Li对分生孢子大小的影响。锂(Li)对粗神经孢子虫(Neurospora crassa)的生长速度和昼夜节律有深远的影响(Engelmann 1987;戴维斯2000;Dunlap and Loros 2004)。通常,在细胞外浓度为10 mM LiCl时,生长速度显著降低,生物钟开始被打乱(Engelmann 1987;Lakin-Thomas 1993;Jolma et al. 2006)。有趣的是,升高的温度可以消除锂效应,可能是由于锂与其假设目标之间的解离增加(Jolma et al. 2006)。由于神经孢子在Li存在或不存在的情况下生长时,在宏观上存在明显的分生差异,我们想知道在微观上是否也存在分生差异,例如分生孢子的大小。为了回答这个问题,我们使用带有极化子冷冻级的蔡司Supra VP35扫描电子显微镜(SEM)进行了研究。bd a菌株(fgsc# 1859)在20°C或30°C的培养皿中培养(12h:12h),使用Vogel培养基,如前所述(Jolma et al. 2006)。Li以LiCl的形式加入到培养基中。样品取自培养皿,培养皿显示出大致相同的总生长量(=生长速度X生长时间)。由于该生物的生长速度依赖于温度和LiCl浓度(Jolma et al. 2006),因此采样前的生长时间变化如表1所示。表1:生长时间前期分析T,°C LiCl, mM GT,天20 0 3 20 5 3 20 10 10 10 10 15 10 30 10 1 T:温度;LiCl: LiCl浓度;GT:生长时间分生孢子大小分别为长轴和短轴l和s。图为分生孢子在20°C、15 mM Li条件下生长。用软木钻覆盖生长区域并在生长区域后面约5毫米处切割样品。切下的样品被放在Al-stub上,其表面有胶状石墨。将胶合后的样品快速冷冻在氮泥中,然后转移到预冷SEM阶段。然后用金钯合金涂覆样品80秒。在SEM分析中,使用了显微镜的“In- lens”检测器。分生孢子呈椭球状,分生孢子的长轴l和短轴s(图1)可直接在样品上测定,作为分生孢子大小的近似度量。新草原出版社2017年出版
Influence of Lithium ions on conidiophore size in Neurospora crassa
Lithium (Li) ions are known to affect Neurospora crassa’s growth speed and circadian clock period, while elevated temperatures abolish these influences. We wondered whether Li has also an effect on conidia size. We used cryo-SEM to investigate this question and report here the results of 1720 measurements showing that at 20°C the long and short conidial axes are significantly reduced at high Li concentrations (10-15 mM), while the ratio between the long and short axes remains approximately constant. An increased temperature (30°C) appears to abolish the Li effect on conidia size. 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/vol53/iss1/10 34 Fungal Genetics Newsletter Influence of Lithium ions on conidiophore size in Neurospora crassa Bodil Aase, Ingunn W. Jolma and Peter Ruoff Department of Mathematics and Natural Science, University of Stavanger, N-4036 Stavanger, Norway corresponding author. email: peter.ruoff@uis.no. # Fungal Genetics Newsletter 53:34-36 Lithium (Li) ions are known to affect Neurospora crassa’s growth speed and circadian clock period, while elevated temperatures abolish these influences. We wondered whether Li has also an effect on conidia size. We used cryo-SEM to investigate this question and report here the results of 1720 measurements showing that at 20°C the long and short conidial axes are significantly reduced at high Li concentrations (10-15 mM), while the ratio between the long and short axes remains approximately constant. An increased temperature (30°C) appears to abolish the Li effect on conidia size. Lithium (Li) has a profound influence on Neurospora crassa’s growth rate and circadian period (Engelmann 1987; Davis 2000; Dunlap and Loros 2004). Typically, at extracellular concentrations of 10 mM LiCl, the growth rate is significantly reduced and the circadian clock begins to get disrupted (Engelmann 1987; Lakin-Thomas 1993; Jolma et al. 2006). Interestingly, increased temperature can abolish the Li effect, possibly by an increased dissociation between Li and its assumed targets (Jolma et al. 2006). Because of the macroscopically distinct differences in conidiation when Neurospora is grown in the presence or absence of Li, we wondered whether there might be also a difference in microscopic conidiation, for example conidia size. In order to answer this question, we performed a study using a Zeiss Supra VP35 scanning electron microscope (SEM) with a Polaron cryo stage. The bd a strain (FGSC #1859) was grown on Petri dishes in LD (12h:12h) at 20°C or 30°C using Vogel’s medium as previously described (Jolma et al. 2006). Li was added to the medium as LiCl. Samples were taken from Petri dishes that showed approximately the same amount of total growth (=growth speed X growth time). Because of the dependence of the speed of this organism’s growth on temperature and LiCl concentrations (Jolma et al. 2006) the growth time prior sampling varied as shown in Table 1. Table 1: Growth times prior analysis T, °C LiCl, mM GT, days 20 0 3 20 5 3 20 10 10 20 15 10 30 10 1 T: temperature; LiCl: concentration of LiCl; GT: growing time Figure 1. Measurement of conidia size as long and short axis, l and s, respectively. The picture shows conidia grown at 20°C with 15 mM Li. Samples were cut out using a cork-borer covering the growth zone and approximately 5 mm behind the growth zone. The cut-out samples were put on a Al-stub that had glue with colloidal graphite on its surface. The glued sample was rapidly frozen in nitrogen slush and then transferred to the pre-cooled SEM stage. Samples were then coated with a gold-palladium alloy for 80 seconds. In the SEM analysis the ‘In-Lens’ detector of the microscope was used. Conidia have an ellipsoidal-like shape and the long and short axes l and s (Fig. 1), which could be determined directly on the sample, were used as an approximate measure for conidia size. Published by New Prairie Press, 2017