荨麻青霉中的分生孢子形成及次生代谢

Conidiogenesis and secondary metabolism in Penicillium urticae.

作者信息

Sekiguchi J, Gaucher G M

出版信息

Appl Environ Microbiol. 1977 Jan;33(1):147-58. doi: 10.1128/aem.33.1.147-158.1977.

DOI:10.1128/aem.33.1.147-158.1977

PMID:836020

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC170614/

Abstract

Submerged cultures of Penicillium urticae (NRRL 2159A) produced the antibiotics patulin and griseofulvin when grown in a glucose-nitrate medium. A high concentration of calcium (i.e., 68 mM) inhibited the production of both antibiotics while stimulating conidiogenesis. Conidial mutants that were defective in an early stage of conidiogenesis produced markedly less patulin, even under growth conditions that favored secondary metabolism. A mutant which lacked the ability to produce the patulin pathway metabolites m-cresol, toluquinol, m-hydroxybenzyl-alcohol, m-hydroxybenzaldehyde, gentisaldehyde, gentisyl alcohol, gentisic acid and patulin, as well as the pathway enzyme m-hydroxybenzyl-alcohol dehydrogenase, still produced yields of conidia that were equivalent to or greater than those of the parent strain. Other mutants which were blocked at later steps of the patulin pathway also produced conidia. These results indicate that patulin and the other related secondary metabolites noted above are not a prerequisite to conidiogenesis in P. urticae. Environmental and developmental factors such as calcium levels and conidiogenesis do, however, indirectly affect the production of patulin pathway metabolites.

摘要

荨麻青霉（NRRL 2159A）的深层培养物在葡萄糖-硝酸盐培养基中生长时会产生抗生素棒曲霉素和灰黄霉素。高浓度的钙（即68 mM）会抑制这两种抗生素的产生，同时刺激分生孢子形成。在分生孢子形成早期存在缺陷的分生孢子突变体产生的棒曲霉素明显较少，即使在有利于次生代谢的生长条件下也是如此。一个缺乏产生棒曲霉素途径代谢产物间甲酚、甲苯醌、间羟基苄醇、间羟基苯甲醛、龙胆醛、龙胆醇、龙胆酸和棒曲霉素能力的突变体，以及缺乏途径酶间羟基苄醇脱氢酶的突变体，其分生孢子产量仍与亲本菌株相当或更高。在棒曲霉素途径后期步骤受阻的其他突变体也能产生分生孢子。这些结果表明，棒曲霉素和上述其他相关次生代谢产物并非荨麻青霉分生孢子形成的先决条件。然而，环境和发育因素，如钙水平和分生孢子形成，确实会间接影响棒曲霉素途径代谢产物的产生。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a056/170614/7d0d6ccd30bc/aem00012-0170-a.jpg

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荨麻青霉中的分生孢子形成及次生代谢

Conidiogenesis and secondary metabolism in Penicillium urticae.

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