新的分离物扩大了原绿球藻的生理多样性,并揭示了其宏观进化过程。

IF 5.1 1区 生物学 Q1 MICROBIOLOGY mBio Pub Date : 2024-11-13 Epub Date: 2024-10-18 DOI:10.1128/mbio.03497-23
Jamie W Becker, Shaul Pollak, Jessie W Berta-Thompson, Kevin W Becker, Rogier Braakman, Keven D Dooley, Thomas Hackl, Allison Coe, Aldo Arellano, Kristen N LeGault, Paul M Berube, Steven J Biller, Andrés Cubillos-Ruiz, Benjamin A S Van Mooy, Sallie W Chisholm
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引用次数: 0

摘要

原绿球藻是一种多样化的微囊藻属,也是地球上最丰富的光营养体。其光合作用的多样性将其划分为适应高光(HL)或低光(LL)的群体,代表了广泛的系统发育等级--每个群体都由多个单系支系组成。在此,我们对从北太平洋深层叶绿素最高点以下分离出来的四株新的原绿球藻进行了生理特征描述。我们将这些生理特性与基因组分析相结合,探索光合触角的进化过程,并讨论其潜在的宏观进化意义。这些分离物属于低光适应性深分支支系,没有其他栽培代表,并显示出一些不寻常的特征。例如,尽管菌株 MIT1223 具有适应弱光的生理特征,但其 chl b2 含量较低,与适应强光的菌株相似。分离基因组显示,每个菌株都含有独特的色素生物合成和结合等位基因,这些等位基因是横向获得的,导致了观察到的生理多样性。对所有微囊藻进行的基因组比较分析表明,Pcb 是原绿球藻中主要的色素携带蛋白,其每个基因组的拷贝数和多样性都大大增加,而这一分支恰好与丧失面性颗粒附着相吻合。总体而言,这些观察结果支持了最近提出的宏观进化模型,即生态位构建辐射使微囊藻的祖先品系从颗粒附着型生活方式过渡到浮游型生活方式,并在极光带广泛定殖。尽管野外研究有助于揭示其多样性的范围,但培养分离物使我们能够将基因组潜力与生理过程联系起来,阐明生态进化反馈,并检验野生细胞比较基因组学所产生的理论。在这里,我们报告了新的适应低光照(LL)的原氯球藻菌株的分离和特征描述,这些菌株填补了多个进化空白。这些新菌株是 LLVII 和 LLVIII 副系原绿球藻的首批栽培代表,它们广泛分布于海洋极光带的较低区域。这些等级是原绿球藻树中独特的、高度多样化的部分,将不同的生态群组分开:LLVII 等级在单系支系之间分支,这些单系支系具有与颗粒相关的面生生活方式和浮游生活方式,而 LLVIII 等级则位于通向所有高光(HL)适应支系的分支上。对这些等级的菌株和基因组进行鉴定,可以深入了解原绿球藻的大规模进化过程。新的 LLVII 和 LLVIII 菌株适应在极低的辐照度水平下生长,具有独特的采光基因特征和色素沉着。LLVII 菌株代表了最基本的原绿球菌类群,其光合触角基因有重大扩展。此外,来自 LLVIII 级的一株菌株挑战了所有适应 LL 的原绿球藻都表现出高 chl b:a2 比率的模式。这些发现有助于深入了解原绿球藻的光生理学进化,并重新定义了低光适应与高光适应原绿球藻细胞的含义。
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Novel isolates expand the physiological diversity of Prochlorococcus and illuminate its macroevolution.

Prochlorococcus is a diverse picocyanobacterial genus and the most abundant phototroph on Earth. Its photosynthetic diversity divides it into high-light (HL)- or low-light (LL)-adapted groups representing broad phylogenetic grades-each composed of several monophyletic clades. Here, we physiologically characterize four new Prochlorococcus strains isolated from below the deep chlorophyll maximum in the North Pacific Ocean. We combine these physiological properties with genomic analyses to explore the evolution of photosynthetic antennae and discuss potential macroevolutionary implications. The isolates belong to deeply branching low-light-adapted clades that have no other cultivated representatives and display some unusual characteristics. For example, despite its otherwise low-light-adapted physiological characteristics, strain MIT1223 has low chl b2 content similar to high-light-adapted strains. Isolate genomes revealed that each strain contains a unique arsenal of pigment biosynthesis and binding alleles that have been horizontally acquired, contributing to the observed physiological diversity. Comparative genomic analysis of all picocyanobacteria reveals that Pcb, the major pigment carrying protein in Prochlorococcus, greatly increased in copy number and diversity per genome along a branch that coincides with the loss of facultative particle attachment. Collectively, these observations support a recently developed macroevolutionary model, in which niche-constructing radiations allowed ancestral lineages of picocyanobacteria to transition from a particle-attached to planktonic lifestyle and broadly colonize the euphotic zone.IMPORTANCEThe marine cyanobacterium, Prochlorococcus, is among the Earth's most abundant organisms, and much of its genetic and physiological diversity remains uncharacterized. Although field studies help reveal the scope of diversity, cultured isolates allow us to link genomic potential to physiological processes, illuminate eco-evolutionary feedbacks, and test theories arising from comparative genomics of wild cells. Here, we report the isolation and characterization of novel low-light (LL)-adapted Prochlorococcus strains that fill in multiple evolutionary gaps. These new strains are the first cultivated representatives of the LLVII and LLVIII paraphyletic grades of Prochlorococcus, which are broadly distributed in the lower regions of the ocean euphotic zone. Each of these grades is a unique, highly diverse section of the Prochlorococcus tree that separates distinct ecological groups: the LLVII grade branches between monophyletic clades that have facultatively particle-associated and constitutively planktonic lifestyles, whereas the LLVIII grade lies along the branch that leads to all high-light (HL)-adapted clades. Characterizing strains and genomes from these grades yields insights into the large-scale evolution of Prochlorococcus. The new LLVII and LLVIII strains are adapted to growth at very low irradiance levels and possess unique light-harvesting gene signatures and pigmentation. The LLVII strains represent the most basal Prochlorococcus group with a major expansion in photosynthetic antenna genes. Furthermore, a strain from the LLVIII grade challenges the paradigm that all LL-adapted Prochlorococcus exhibit high ratios of chl b:a2. These findings provide insights into the photophysiological evolution of Prochlorococcus and redefine what it means to be a low- vs high-light-adapted Prochlorococcus cell.

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来源期刊
mBio
mBio MICROBIOLOGY-
CiteScore
10.50
自引率
3.10%
发文量
762
审稿时长
1 months
期刊介绍: mBio® is ASM''s first broad-scope, online-only, open access journal. mBio offers streamlined review and publication of the best research in microbiology and allied fields.
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