纳格里亚双核糖核酸酶I组内含子的短期序列进化与垂直遗传

Short-term sequence evolution and vertical inheritance of the Naegleria twin-ribozyme group I intron.

作者信息

Wikmark Odd-Gunnar, Einvik Christer, De Jonckheere Johan F, Johansen Steinar D

机构信息

Department of Molecular Biotechnology, RNA Research Group, Institute of Medical Biology, University of Tromsø, N-9037 Tromsø, Norway.

出版信息

BMC Evol Biol. 2006 May 2;6:39. doi: 10.1186/1471-2148-6-39.

DOI:10.1186/1471-2148-6-39

PMID:16670006

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1464144/

Abstract

BACKGROUND

Ribosomal DNA of several species of the free-living Naegleria amoeba harbors an optional group I intron within the nuclear small subunit ribosomal RNA gene. The intron (Nae.S516) has a complex organization of two ribozyme domains (NaGIR1 and NaGIR2) and a homing endonuclease gene (NaHEG). NaGIR2 is responsible for intron excision, exon ligation, and full-length intron RNA circularization, reactions typical for nuclear group I intron ribozymes. NaGIR1, however, is essential for NaHEG expression by generating the 5' end of the homing endonuclease messenger RNA. Interestingly, this unusual class of ribozyme adds a lariat-cap at the mRNA.

RESULTS

To elucidate the evolutionary history of the Nae.S516 twin-ribozyme introns we have analyzed 13 natural variants present in distinct Naegleria isolates. Structural variabilities were noted within both the ribozyme domains and provide strong comparative support to the intron secondary structure. One of the introns, present in N. martinezi NG872, contains hallmarks of a degenerated NaHEG. Phylogenetic analyses performed on separate data sets representing NaGIR1, NaGIR2, NaHEG, and ITS1-5.8S-ITS2 ribosomal DNA are consistent with an overall vertical inheritance pattern of the intron within the Naegleria genus.

CONCLUSION

The Nae.S516 twin-ribozyme intron was gained early in the Naegleria evolution with subsequent vertical inheritance. The intron was lost in the majority of isolates (70%), leaving a widespread but scattered distribution pattern. Why the apparent asexual Naegleria amoebae harbors active intron homing endonucleases, dependent on sexual reproduction for its function, remains a puzzle.

摘要

背景

几种自由生活的耐格里属变形虫的核糖体DNA在核小亚基核糖体RNA基因内含有一个可选的I组内含子。该内含子（Nae.S516）具有两个核酶结构域（NaGIR1和NaGIR2）和一个归巢内切核酸酶基因（NaHEG）的复杂组织。NaGIR2负责内含子切除、外显子连接和全长内含子RNA环化，这些是核I组内含子核酶的典型反应。然而，NaGIR1通过产生归巢内切核酸酶信使RNA的5'末端对NaHEG表达至关重要。有趣的是，这种不寻常的核酶类别在mRNA上添加了一个套索帽。

结果

为了阐明Nae.S516双核酶内含子的进化历史，我们分析了存在于不同耐格里属分离株中的13个天然变体。在两个核酶结构域内都注意到了结构变异性，并为内含子二级结构提供了有力的比较支持。存在于马氏耐格里变形虫NG872中的一个内含子包含一个退化的NaHEG的特征。对代表NaGIR1、NaGIR2、NaHEG和ITS1-5.8S-ITS2核糖体DNA的单独数据集进行的系统发育分析与耐格里属内含子的整体垂直遗传模式一致。

结论

Nae.S516双核酶内含子在耐格里属进化早期获得，随后垂直遗传。该内含子在大多数分离株（70%）中丢失，留下广泛但分散的分布模式。为什么明显无性的耐格里属变形虫含有活跃的内含子归巢内切核酸酶，而其功能依赖有性生殖，仍然是一个谜。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0c63/1464144/9262d1311329/1471-2148-6-39-1.jpg

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纳格里亚双核糖核酸酶I组内含子的短期序列进化与垂直遗传

Short-term sequence evolution and vertical inheritance of the Naegleria twin-ribozyme group I intron.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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