Institute of Genomics and Bioinformatics, Agricultural Biotechnology Centre, National Chung Hsing University, Tauchung, Taiwan.
Plant Biol (Stuttg). 2013 Jan;15(1):27-36. doi: 10.1111/j.1438-8677.2012.00622.x. Epub 2012 Sep 28.
In this work, the population of small RNAs (sRNAs) was studied in the gymnosperm Sequoia sempervirens during phase changes, specifically in the juvenile, adult and rejuvenated plants obtained in vitro. The potential target genes of Sequoia sRNAs were predicted through bioinformatics. Rejuvenation is a pivotal process in woody plants that enables them to regain their growth potential, which results in the recovery of physiologic and molecular characteristics that were lost when the juveniles mature into adult plants. The results from the five repeated graftings of juvenile, adult and rejuvenated plants in vitro showed that sRNAs could be classified into structural RNAs (Group I), small interfering RNAs (Group II), annotated microRNAs (Group III, and unannotated sRNAs (Group IV). The results indicate that only 573 among 15,485,415 sRNAs (Groups III and IV) had significantly different expression patterns associated with rejuvenation and phase change. A total of 215 sRNAs exhibited up-regulated expression patterns in adult shoots, and 358 sRNAs were down-regulated. Expression profiling and prediction of possible target genes of these unique small RNAs indicate possible functions in the control of photosynthetic efficiency and rooting competence abundance during plant rejuvenation. Moreover, the increase in SsmiR156 and decrease in SsmiR172 during plant rejuvenation suggested that these two microRNAs extensively affect phase transition.
在这项工作中,研究了松柏类植物红杉在相变过程中的小 RNA(sRNA)群体,特别是在体外获得的幼体、成年和再生植物中。通过生物信息学预测了红杉 sRNA 的潜在靶基因。再生是木本植物的关键过程,使它们能够恢复生长潜力,从而恢复当幼体成熟为成年植物时失去的生理和分子特征。对体外重复五次幼体、成年和再生植物嫁接的结果表明,sRNA 可分为结构 RNA(第 I 组)、小干扰 RNA(第 II 组)、注释 microRNA(第 III 组)和未注释 sRNA(第 IV 组)。结果表明,只有 15485415 个 sRNA(第 III 和第 IV 组)中的 573 个与再生和相变有关,其表达模式有显著差异。共有 215 个 sRNA 在成年枝条中表现出上调表达模式,358 个 sRNA下调。这些独特 sRNA 的表达谱和可能靶基因的预测表明,它们在植物再生过程中对光合作用效率和生根能力的控制中可能具有功能。此外,在植物再生过程中 SsmiR156 的增加和 SsmiR172 的减少表明这两个 microRNA 广泛影响相变。
