Nasr Esfahani Maryam, Inoue Komaki, Chu Ha Duc, Nguyen Kien Huu, Van Ha Chien, Watanabe Yasuko, Burritt David J, Herrera-Estrella Luis, Mochida Keiichi, Tran Lam-Son Phan
Department of Biology, Lorestan University, Khorramabad, 68137-17133, Iran.
Cellulose Production Research Team, Biomass Engineering Research Division, RIKEN Center for Sustainable Resource Science, 1-7-22, Suehiro-cho, Tsurumi, Yokohama, 230-0045, Japan.
Plant J. 2017 Sep;91(5):911-926. doi: 10.1111/tpj.13616. Epub 2017 Aug 4.
Phosphate (Pi) deficiency is known to be a major limitation for symbiotic nitrogen fixation (SNF), and hence legume crop productivity globally. However, very little information is available on the adaptive mechanisms, particularly in the important legume crop chickpea (Cicer arietinum L.), which enable nodules to respond to low-Pi availability. Thus, to elucidate these mechanisms in chickpea nodules at molecular level, we used an RNA sequencing approach to investigate transcriptomes of the nodules in Mesorhizobium mediterraneum SWRI9-(MmSWRI9)-chickpea and M. ciceri CP-31-(McCP-31)-chickpea associations under Pi-sufficient and Pi-deficient conditions, of which the McCP-31-chickpea association has a better SNF capacity than the MmSWRI9-chickpea association during Pi starvation. Our investigation revealed that more genes showed altered expression patterns in MmSWRI9-induced nodules than in McCP-31-induced nodules (540 vs. 225) under Pi deficiency, suggesting that the Pi-starvation-more-sensitive MmSWRI9-induced nodules required expression change in a larger number of genes to cope with low-Pi stress than the Pi-starvation-less-sensitive McCP-31-induced nodules. The functional classification of differentially expressed genes (DEGs) was examined to gain an understanding of how chickpea nodules respond to Pi starvation, caused by soil Pi deficiency. As a result, more DEGs involved in nodulation, detoxification, nutrient/ion transport, transcriptional factors, key metabolic pathways, Pi remobilization and signalling were found in Pi-starved MmSWRI9-induced nodules than in Pi-starved McCP-31-induced nodules. Our findings have enabled the identification of molecular processes that play important roles in the acclimation of nodules to Pi deficiency, ultimately leading to the development of Pi-efficient chickpea symbiotic associations suitable for Pi-deficient soils.
已知磷(Pi)缺乏是共生固氮(SNF)的主要限制因素,因此也是全球豆类作物生产力的主要限制因素。然而,关于适应性机制的信息非常少,特别是在重要的豆类作物鹰嘴豆(Cicer arietinum L.)中,这些机制使根瘤能够应对低磷可用性。因此,为了在分子水平上阐明鹰嘴豆根瘤中的这些机制,我们采用RNA测序方法研究了在磷充足和磷缺乏条件下,地中海中生根瘤菌SWRI9-(MmSWRI9)-鹰嘴豆和鹰嘴豆根瘤菌CP-31-(McCP-31)-鹰嘴豆共生体中根瘤的转录组,其中在缺磷期间,McCP-31-鹰嘴豆共生体比MmSWRI9-鹰嘴豆共生体具有更好的SNF能力。我们的研究表明,在缺磷条件下,MmSWRI9诱导的根瘤中比McCP-31诱导的根瘤中有更多基因显示出表达模式的改变(540个对225个),这表明对缺磷更敏感的MmSWRI9诱导的根瘤比缺磷不太敏感的McCP-31诱导的根瘤需要更多基因的表达变化来应对低磷胁迫。对差异表达基因(DEG)进行功能分类,以了解鹰嘴豆根瘤如何应对土壤磷缺乏引起的缺磷情况。结果发现,与缺磷的McCP-31诱导的根瘤相比,缺磷的MmSWRI9诱导的根瘤中更多的DEG参与结瘤、解毒、营养/离子运输、转录因子、关键代谢途径、磷再转运和信号传导。我们的研究结果有助于确定在根瘤适应缺磷过程中起重要作用的分子过程,最终导致开发出适合缺磷土壤的高效磷鹰嘴豆共生体。
