共生蓝菌重建的案例研究：相容的共生藻从何而来？

A case study on the re-establishment of the cyanolichen symbiosis: where do the compatible photobionts come from?

机构信息

Área de Biodiversidad y Conservación, ESCET, Universidad Rey Juan Carlos, Móstoles, Madrid, Spain.

Department of Biology and Geology, Physics and Inorganic Chemistry, Organismal and Evolutionary Biology Research Programme, Faculty of Biological and Environmental Sciences, University of Helsinki, Finland.

出版信息

Ann Bot. 2019 Oct 18;124(3):379-388. doi: 10.1093/aob/mcz052.

DOI:10.1093/aob/mcz052

PMID:31329832

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6798828/

Abstract

BACKGROUND AND AIMS

In order to re-establish lichen symbiosis, fungal spores must first germinate and then associate with a compatible photobiont. To detect possible establishment limitations in a sexually reproducing cyanolichen species, we studied ascospore germination, photobiont growth and photobiont association patterns in Pectenia plumbea.

METHODS

Germination tests were made with ascospores from 500 apothecia under different treatments, and photobiont growth was analysed in 192 isolates obtained from 24 thalli. We determined the genotype identity [tRNALeu (UAA) intron] of the Nostoc cyanobionts from 30 P. plumbea thalli from one population. We also sequenced cyanobionts of 41 specimens of other cyanolichen species and 58 Nostoc free-living colonies cultured from the bark substrate.

KEY RESULTS

Not a single fungal ascospore germinated and none of the photobiont isolates produced motile hormogonia. Genetic analyses revealed that P. plumbea shares Nostoc genotypes with two other cyanolichen species of the same habitat, but these photobionts were hardly present in the bark substrate.

CONCLUSIONS

Due to the inability of both symbionts to thrive independently, the establishment of P. plumbea seems to depend on Dendriscocaulon umhausense, the only cyanolichen species in the same habitat that reproduces asexually and acts as a source of appropriate cyanobionts. This provides support to the hypothesis about facilitation among lichens.

摘要

背景与目的

为了重新建立地衣共生关系，真菌孢子必须首先发芽，然后与相容的光养生物结合。为了检测有性繁殖蓝藻地衣物种中可能存在的建立限制，我们研究了 Pectenia plumbea 中担孢子的萌发、光养生物的生长和光养生物的结合模式。

方法

在不同处理条件下对来自 500 个子囊壳的担孢子进行萌发试验，并对从 24 个藻体中获得的 192 个分离物进行光养生物生长分析。我们确定了来自一个种群的 30 个 P. plumbea 藻体中 Nostoc 蓝藻共生体的基因型身份[trnL eu（UAA）内含子]。我们还对来自其他 41 个蓝藻地衣物种标本和从树皮基质中培养的 58 个 Nostoc 自由生活集落的蓝藻共生体进行了测序。

主要结果

没有一个真菌担孢子萌发，也没有一个光养生物分离物产生游动的藻殖段。遗传分析表明，P. plumbea 与同一生境中的另外两种蓝藻地衣物种共享 Nostoc 基因型，但这些光养生物在树皮基质中几乎不存在。

结论

由于两个共生体都无法独立生长，P. plumbea 的建立似乎依赖于同一生境中的唯一一种无性繁殖的地衣 Dendriscocaulon umhausense，它是合适的蓝藻共生体的来源。这为地衣之间的促进假说提供了支持。

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Oecologia. 2018 Jul;187(3):767-782. doi: 10.1007/s00442-018-4159-6. Epub 2018 May 14.

A species on a tightrope: Establishment limitations of an endangered lichen in a fragmented Mediterranean landscape.走在钢丝绳上的物种：在地中海破碎景观中一种濒危地衣的定殖限制

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Fungal Biol. 2017 Mar;121(3):222-233. doi: 10.1016/j.funbio.2016.12.001. Epub 2016 Dec 18.

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