Rachel Amir, Dan Levanon, Yitzhak Hadar, Ilan Chet
{"title":"Factors Affecting Translocation and Sclerotial Formation in Morchella esculenta","authors":"Rachel Amir, Dan Levanon, Yitzhak Hadar, Ilan Chet","doi":"10.1006/emyc.1995.1007","DOIUrl":null,"url":null,"abstract":"<div><p>Amir, R., Levanon, D., Hadar, Y., and Chet, I. 1995. Factors affecting translocation and sclerotial formation in <em>Morchella esculenta. Experimental Mycology</em> 19, 61-70. <em>Morchella esculenta</em> was grown on square split plates, forming sclerotia on one side and mycelium on the other. After the fungus ceased to colonize and before sclerotial initials appeared, [<sup>14</sup>C]3-<em>O</em>-methyl glucose was added to the edge of the plate on the mycelial side. The effect of various activities in the mycelium (source) and sclerotia (sink) on sclerotial formation and translocation were examined using inhibitors and water potential changes of the media. Sodium azide or cycloheximide applied separately to both sides inhibited both sclerotial formation and translocation, showing that processes in the source and sink depend on metabolic activities as well as protein synthesis. The use of nikkomycin inhibited sclerotial formation, without affecting translocation to the sclerotia. Since the hyphal tips swelled and burst, the translocated compounds were lost to the media. In a strain defective in sclerotial formation, used as a control, no translocation took place, showing that there is a connection between sclerotial formation and translocation. Reversal of the water potential gradient between the two media (lower on the mycelial side), reduced the formation of sclerotia and translocation to them. Translocation to <em>Morchella</em> sclerotia takes place via turgor driven mass flow, but is nevertheless affected by activities in both the source and the sink.</p></div>","PeriodicalId":12110,"journal":{"name":"Experimental Mycology","volume":"19 1","pages":"Pages 61-70"},"PeriodicalIF":0.0000,"publicationDate":"1995-03-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1006/emyc.1995.1007","citationCount":"17","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Experimental Mycology","FirstCategoryId":"1085","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0147597585710079","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 17
Abstract
Amir, R., Levanon, D., Hadar, Y., and Chet, I. 1995. Factors affecting translocation and sclerotial formation in Morchella esculenta. Experimental Mycology 19, 61-70. Morchella esculenta was grown on square split plates, forming sclerotia on one side and mycelium on the other. After the fungus ceased to colonize and before sclerotial initials appeared, [14C]3-O-methyl glucose was added to the edge of the plate on the mycelial side. The effect of various activities in the mycelium (source) and sclerotia (sink) on sclerotial formation and translocation were examined using inhibitors and water potential changes of the media. Sodium azide or cycloheximide applied separately to both sides inhibited both sclerotial formation and translocation, showing that processes in the source and sink depend on metabolic activities as well as protein synthesis. The use of nikkomycin inhibited sclerotial formation, without affecting translocation to the sclerotia. Since the hyphal tips swelled and burst, the translocated compounds were lost to the media. In a strain defective in sclerotial formation, used as a control, no translocation took place, showing that there is a connection between sclerotial formation and translocation. Reversal of the water potential gradient between the two media (lower on the mycelial side), reduced the formation of sclerotia and translocation to them. Translocation to Morchella sclerotia takes place via turgor driven mass flow, but is nevertheless affected by activities in both the source and the sink.
Amir, R., Levanon, D., Hadar, Y.和Chet, I. 1995。羊肚菌易位和硬化形成的影响因素。实验真菌学,19,61-70。羊肚菌生长在方形裂板上,一侧形成菌核,另一侧形成菌丝。在真菌停止定植后,在菌丝体一侧的平板边缘加入[14C]3- o -甲基葡萄糖。利用抑制剂和培养基水势变化考察了菌丝(源)和菌核(汇)中各种活性对菌核形成和易位的影响。叠氮化钠或环己亚胺分别应用于两侧,抑制了硬化的形成和转运,表明源和汇的过程取决于代谢活动和蛋白质合成。尼克霉素的使用抑制了巩膜的形成,但不影响向巩膜的易位。由于菌丝尖端膨胀和破裂,易位的化合物丢失到介质中。在一个菌核形成缺陷的菌株中,作为对照,没有发生易位,这表明在菌核形成和易位之间存在联系。两种介质之间水势梯度的逆转(菌丝侧水势较低),减少了菌核的形成和向菌核的转运。向硬化羊肚菌的转运是通过膨胀驱动的质量流进行的,但仍然受到源和汇活动的影响。