酿酒酵母科中端粒、端粒酶 RNA 及其模板区的非凡多样性。

Extraordinary diversity of telomeres, telomerase RNAs and their template regions in Saccharomycetaceae.

机构信息

Institute of Biophysics, Academy of Sciences of the Czech Republic, Brno, 61265, Czech Republic.

Mendel Centre for Plant Genomics and Proteomics, CEITEC, Masaryk University, Brno, 62500, Czech Republic.

出版信息

Sci Rep. 2021 Jun 17;11(1):12784. doi: 10.1038/s41598-021-92126-x.

DOI:10.1038/s41598-021-92126-x

PMID:34140564

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8211666/

Abstract

Telomerase RNA (TR) carries the template for synthesis of telomere DNA and provides a scaffold for telomerase assembly. Fungal TRs are long and have been compared to higher eukaryotes, where they show considerable diversity within phylogenetically close groups. TRs of several Saccharomycetaceae were recently identified, however, many of these remained uncharacterised in the template region. Here we show that this is mainly due to high variability in telomere sequence. We predicted the telomere sequences using Tandem Repeats Finder and then we identified corresponding putative template regions in TR candidates. Remarkably long telomere units and the corresponding putative TRs were found in Tetrapisispora species. Notably, variable lengths of the annealing sequence of the template region (1-10 nt) were found. Consequently, species with the same telomere sequence may not harbour identical TR templates. Thus, TR sequence alone can be used to predict a template region and telomere sequence, but not to determine these exactly. A conserved feature of telomere sequences, tracts of adjacent Gs, led us to test the propensity of individual telomere sequences to form G4. The results show highly diverse values of G4-propensity, indicating the lack of ubiquitous conservation of this feature across Saccharomycetaceae.

摘要

端粒酶 RNA（TR）携带端粒 DNA 合成的模板，并为端粒酶组装提供支架。真菌 TR 很长，与高等真核生物进行比较时，在系统发育密切相关的群体中显示出相当大的多样性。最近已经鉴定了几种酿酒酵母科的 TR，但这些在模板区域中仍未被表征。在这里，我们表明这主要是由于端粒序列的高度变异性。我们使用串联重复序列发现器预测了端粒序列，然后在 TR 候选物中识别了相应的假定模板区域。在 Tetrapisispora 物种中发现了非常长的端粒单元和相应的假定 TR。值得注意的是，模板区域的退火序列（1-10 nt）长度可变。因此，具有相同端粒序列的物种可能不具有相同的 TR 模板。因此，TR 序列本身可用于预测模板区域和端粒序列，但不能精确确定这些序列。端粒序列的一个保守特征是相邻 Gs 的序列，这使我们能够测试单个端粒序列形成 G4 的倾向。结果表明 G4 倾向具有高度多样化的值，表明 Saccharomycetaceae 中普遍缺乏这种特征的保守性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cc32/8211666/9bfa0b7a99f1/41598_2021_92126_Fig1_HTML.jpg

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酿酒酵母科中端粒、端粒酶 RNA 及其模板区的非凡多样性。

Extraordinary diversity of telomeres, telomerase RNAs and their template regions in Saccharomycetaceae.

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