Identification of a novel helitron transposon in the genome of Antarctic fish

Rolling-circle (RC) eukaryotic transposons, known as helitrons, are found in a wide range of organisms, from protist to mammals. Autonomous helitrons have a distinctive open reading frame (ORF) encoding a polypeptide that contains typical domains for RC replication (RCR): the Rep (RCR initiator) and the DNA helicase domains. These elements are believed to have an important role in the host genome evolution, owing to their frequent capture of host genes, some of which can evolve into novel genes or become essential for helitron transposition. We conducted a molecular analysis of the suborder Notothenioidei, a group of Perciformes that currently dominate the Antarctic waters by virtue of their remarkable cold-adaptation ability. A novel helitron from the genome of the icefish species Chionodraco hamatus, belonging to the Channichthyidae, the most derived Notothenioids family, was isolated, characterized and designated as HeliNoto (8.9 kb). Its ORF was compared to homologous sequences from different species in a comprehensive phylogenetic analysis. For the first time the putative functional domains of a helitron were subjected to a well accurate structural analysis including chromosomal localization. Finally, the distribution of HeliNoto among Notothenioids was investigated.     

尖孢镰刀菌FoHeli转座元件的结构特征及功能验证

Helitron是一种广泛存在于真核生物中的可移动遗传元件。与其他转座子不同,自主Helitron元件可编码具有复制引发（Rep）和解旋酶（Hel）结构域的转座酶,并通过滚环复制的方式在基因组中进行扩张。本研究对9种尖孢镰刀菌中的自主Helitron元件进行系统分析,结果表明尖孢镰刀菌中存在两类自主Helitron元件FoHeli1与FoHeli2。其中FoHeli1成员间序列高度相似,并具有明晰的边界特征：3’端为保守的“TATTTT”序列,其上游可形成稳定的发夹结构,且发夹上游可与5’端形成12bp的反向互补结构。基于上述分析结果,从尖孢镰刀菌Fo4287菌株中克隆获得完整的FoHeli1元件,并通过构建双元转座系统及PEG介导的原生质体转化,证明尖孢镰刀菌中的FoHeli元件可在禾谷镰刀菌PH-1菌株的基因组中发生跳转。     

Landscape and evolutionary dynamics of Helitron transposons in plant genomes as well as construction of online database HelDB

Helitron transposons play an important role in host genome evolution due to their ability to capture genes and regulatory elements. In this study, we developed a pipeline to identify and annotate Helitrons systematically from 358 plant and 178 animal high-quality genomes. All these data were organized into HelDB, a database where Helitrons can be explored with a user-friendly Web interface and related software. Based on these data, further analysis showed that the number or the cumulative length of Helitrons is positively correlated with genome size. Helitrons had experienced two expansion periods in plants, with the first occurring 20–30 Ma and peaking at approximately 24 Ma. The second expansion occurred in the last 4 million years. The expansions might be due to stimulation of paleogeographic environment. Detailed investigation of gene capture by Helitrons in Brassicaceae and Solanaceae plants showed that the captured genes showed diverse functions. Interestingly, metal ion binding function was enriched in these captured genes in most species. This phenomenon might be due to the need for binding of divalent metal ions to the Rep domain required for Helitron transposition. This study improves our knowledge of the landscape and evolution of Helitron transposons in plants and paves a way for further functional studies of this kind of transposable element.