通过深度 RNA 扩增子测序鉴定到的杜伦小麦品种中乳糜泻表位的定量和定性差异。

Quantitative and qualitative differences in celiac disease epitopes among durum wheat varieties identified through deep RNA-amplicon sequencing.

机构信息

Plant Research International, Wageningen UR, P,O, Box 16, Wageningen, AA NL-6700, The Netherlands.

出版信息

BMC Genomics. 2013 Dec 19;14:905. doi: 10.1186/1471-2164-14-905.

DOI:10.1186/1471-2164-14-905

PMID:24354426

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3890609/

Abstract

BACKGROUND

Wheat gluten is important for the industrial quality of bread wheat (Triticum aestivum L.) and durum wheat (T. turgidum L.). Gluten proteins are also the source of immunogenic peptides that can trigger a T cell reaction in celiac disease (CD) patients, leading to inflammatory responses in the small intestine. Various peptides with three major T cell epitopes involved in CD are derived from alpha-gliadin fraction of gluten. Alpha-gliadins are encoded by a large multigene family and amino acid variation in the CD epitopes is known to influence the immunogenicity of individual gene family members. Current commercial methods of gluten detection are unable to distinguish between immunogenic and non-immunogenic CD epitope variants and thus to accurately quantify the overall CD epitope load of a given wheat variety. Such quantification is indispensable for correct selection of wheat varieties with low potential to cause CD.

RESULTS

A 454 RNA-amplicon sequencing method was developed for alpha-gliadin transcripts encompassing the three major CD epitopes and their variants. The method was used to screen developing grains on plants of 61 different durum wheat cultivars and accessions. A dedicated sequence analysis pipeline returned a total of 304 unique alpha-gliadin transcripts, corresponding to a total of 171 'unique deduced protein fragments' of alpha-gliadins. The numbers of these fragments obtained in each plant were used to calculate quantitative and quantitative differences between the CD epitopes expressed in the endosperm of these wheat plants. A few plants showed a lower fraction of CD epitope-encoding alpha-gliadin transcripts, but none were free of CD epitopes.

CONCLUSIONS

The dedicated 454 RNA-amplicon sequencing method enables 1) the grouping of wheat plants according to the genetic variation in alpha-gliadin transcripts, and 2) the screening for plants which are potentially less CD-immunogenic. The resulting alpha-gliadin sequence database will be useful as a reference in proteomics analysis regarding the immunogenic potential of mature wheat grains.

摘要

背景

小麦面筋对于面包小麦（Triticum aestivum L.）和硬质小麦（T. turgidum L.）的工业质量很重要。面筋蛋白也是免疫原性肽的来源，这些肽在乳糜泻（CD）患者中可引发 T 细胞反应，导致小肠炎症反应。源自面筋中α-醇溶蛋白的各种含有三个主要 CD 表位的肽是 CD 的来源。α-醇溶蛋白由一个大的多基因家族编码，已知 CD 表位中的氨基酸变异会影响个别基因家族成员的免疫原性。目前用于检测面筋的商业方法无法区分免疫原性和非免疫原性 CD 表位变体，因此无法准确量化特定小麦品种的整体 CD 表位负荷。这种量化对于正确选择潜在 CD 风险低的小麦品种是必不可少的。

结果

开发了一种针对包含三个主要 CD 表位及其变体的α-醇溶蛋白转录本的 454 RNA 扩增子测序方法。该方法用于筛选 61 种不同硬质小麦品种和品系植物上发育中的谷物。专门的序列分析管道共返回了 304 个独特的α-醇溶蛋白转录本，对应于总共 171 个α-醇溶蛋白的“独特推断蛋白片段”。从每个植物中获得的这些片段的数量用于计算这些小麦植物胚乳中表达的 CD 表位之间的定量和定量差异。一些植物显示出较低比例的编码 CD 表位的α-醇溶蛋白转录本，但没有一种植物不含 CD 表位。

结论

专用的 454 RNA 扩增子测序方法能够 1）根据α-醇溶蛋白转录本的遗传变异对小麦植物进行分组，2）筛选潜在的 CD 免疫原性较低的植物。由此产生的α-醇溶蛋白序列数据库将作为成熟小麦籽粒免疫原性的蛋白质组学分析的参考资料很有用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d536/3890609/c85d4782a013/1471-2164-14-905-1.jpg

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通过深度 RNA 扩增子测序鉴定到的杜伦小麦品种中乳糜泻表位的定量和定性差异。

Quantitative and qualitative differences in celiac disease epitopes among durum wheat varieties identified through deep RNA-amplicon sequencing.

机构信息

Plant Research International, Wageningen UR, P,O, Box 16, Wageningen, AA NL-6700, The Netherlands.