基因组变异导致了蒺藜苜蓿生态型Jemalong A17和R108对三种矿质元素的不同反应。
Genome variations account for different response to three mineral elements between Medicago truncatula ecotypes Jemalong A17 and R108.
作者信息
Wang Tian-Zuo, Tian Qiu-Ying, Wang Bao-Lan, Zhao Min-Gui, Zhang Wen-Hao
机构信息
State Key Laboratory of Vegetation and Environmental Change, Institute of Botany, the Chinese Academy of Sciences, Beijing, P, R, China.
出版信息
BMC Plant Biol. 2014 May 6;14:122. doi: 10.1186/1471-2229-14-122.
BACKGROUND
Resequencing can be used to identify genome variations underpinning many morphological and physiological phenotypes. Legume model plant Medicago truncatula ecotypes Jemalong A17 (J. A17) and R108 differ in their responses to mineral toxicity of aluminum and sodium, and mineral deficiency of iron in growth medium. The difference may result from their genome variations, but no experimental evidence supports this hypothesis.
RESULTS
A total of 12,750 structure variations, 135,045 short insertions/deletions and 764,154 single nucleotide polymorphisms were identified by resequencing the genome of R108. The suppressed expression of MtAACT that encodes a putative aluminum-induced citrate efflux transporter by deletion of partial sequence of the second intron may account for the less aluminum-induced citrate exudation and greater accumulation of aluminum in roots of R108 than in roots of J. A17, thus rendering R108 more sensitive to aluminum toxicity. The higher expression-level of MtZpt2-1 encoding a TFIIIA-related transcription factor in J. A17 than R108 under conditions of salt stress can be explained by the greater number of stress-responsive elements in its promoter sequence, thus conferring J. A17 more tolerant to salt stress than R108 plants by activating the expression of downstream stress-responsive genes. YSLs (Yellow Stripe-Likes) are involved in long-distance transport of iron in plants. We found that an YSL gene was deleted in the genome of R108 plants, thus rendering R108 less tolerance to iron deficiency than J. A17 plants.
CONCLUSIONS
The deletion or change in several genes may account for the different responses of M. truncatula ecotypes J. A17 and R108 to mineral toxicity of aluminum and sodium as well as iron deficiency. Uncovering genome variations by resequencing is an effective method to identify different traits between species/ecotypes that are genetically related. These findings demonstrate that analyses of genome variations by resequencing can shed important light on differences in responses of M. truncatula ecotypes to abiotic stress in general and mineral stress in particular.
背景
重测序可用于识别构成许多形态和生理表型基础的基因组变异。豆科模式植物蒺藜苜蓿生态型Jemalong A17(J. A17)和R108在对生长培养基中铝和钠的矿质毒性以及铁缺乏的反应上存在差异。这种差异可能源于它们的基因组变异,但尚无实验证据支持这一假设。
结果
通过对R108基因组进行重测序,共鉴定出12,750个结构变异、135,045个短插入/缺失和764,154个单核苷酸多态性。R108中由于第二个内含子部分序列缺失导致编码假定的铝诱导柠檬酸外流转运蛋白的MtAACT表达受抑制,这可能解释了与J. A17相比,R108根系中铝诱导的柠檬酸分泌较少且铝积累较多,从而使R108对铝毒性更敏感。在盐胁迫条件下,J. A17中编码TFIIIA相关转录因子的MtZpt2-1的表达水平高于R108,这可以通过其启动子序列中更多的胁迫响应元件来解释,从而通过激活下游胁迫响应基因的表达使J. A17比R108植物更耐盐胁迫。YSLs(类黄条纹蛋白)参与植物中铁的长距离运输。我们发现R108植物基因组中一个YSL基因缺失,从而使R108对缺铁的耐受性低于J. A17植物。
结论
几个基因的缺失或变化可能解释了蒺藜苜蓿生态型J. A17和R108对铝和钠的矿质毒性以及缺铁的不同反应。通过重测序揭示基因组变异是识别遗传相关物种/生态型之间不同性状的有效方法。这些发现表明,通过重测序分析基因组变异可以为蒺藜苜蓿生态型对非生物胁迫尤其是矿质胁迫的反应差异提供重要线索。
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