Diurnal transcriptional variation is reduced in a nitrogen-fixing diatom endosymbiont

Heidi Abresch, Tisza Bell, Scott R Miller
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Abstract

Many organisms have formed symbiotic relationships with nitrogen (N)-fixing bacteria to overcome N limitation. Diatoms in the family Rhopalodiaceae host unicellular, N-fixing cyanobacterial endosymbionts called spheroid bodies (SBs). Although this relationship is relatively young, SBs share many key features with older endosymbionts, including coordinated cell division and genome reduction. Unlike free-living relatives that fix N exclusively at night, SBs fix N largely during the day; however, how SB metabolism is regulated and coordinated with the host is not yet understood. We compared four SB genomes, including those from two new host species (Rhopalodia gibba and Epithemia adnata), to build a genome-wide phylogeny which provides a better understanding of SB evolutionary origins. Contrary to models of endosymbiotic genome reduction, the SB chromosome is unusually stable for an endosymbiont genome, likely due to the early loss of all mobile elements. Transcriptomic data for the R. gibba SB and host organelles addressed whether and how the allocation of transcriptional resources depends on light and nitrogen availability. Whereas allocation to the SB was high under all conditions, relative expression of chloroplast photosynthesis genes increased in the absence of nitrate, but this pattern was suppressed by nitrate addition. SB expression of catabolism genes was generally greater during daytime rather than at night, although the magnitude of diurnal changes in expression was modest compared to free-living cyanobacteria. We conclude that SB daytime catabolism likely supports N-fixation by linking the process to host photosynthetic carbon fixation.
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固氮硅藻内共生体的昼夜转录变异减少
许多生物与固氮细菌形成共生关系,以克服氮限制。Rhopalodiaceae 科硅藻寄主单细胞固氮蓝藻内共生体,称为球状体(SB)。虽然这种关系相对年轻,但 SBs 与较老的内共生体有许多共同的关键特征,包括协调的细胞分裂和基因组减少。与只在夜间固定氮的自由生活的亲缘植物不同,SB 主要在白天固定氮;然而,SB 的新陈代谢是如何调节并与宿主协调的还不清楚。我们比较了四个 SB 基因组,包括两个新宿主物种(Rhopalodia gibba 和 Epithemia adnata)的基因组,建立了一个全基因组系统发生,从而更好地了解了 SB 的进化起源。与内共生基因组减少的模型相反,SB 染色体对于内共生基因组来说异常稳定,这可能是由于所有移动元素的早期丢失。关于 R. gibba SB 和宿主细胞器的转录组数据探讨了转录资源的分配是否以及如何取决于光和氮的可用性。虽然在所有条件下对 SB 的分配都很高,但叶绿体光合作用基因的相对表达量在无硝酸盐条件下有所增加,但硝酸盐的添加抑制了这种模式。尽管与自由生活的蓝藻相比,昼夜表达量的变化幅度不大,但分解代谢基因的 SB 表达量一般在白天比夜间高。我们的结论是,SB 白天的分解代谢可能通过将该过程与寄主光合作用碳固定联系起来来支持固氮作用。
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