Back

A genetic toolkit to reduce wheat immunogenicity and incidence of celiac disease

Rottersman, M. G.; Laudencia-Chingcuanco, D.; Zhang, W.; Guzman-Lopez, M. H.; Lin, J. W.; Zhang, J.; Caseys, C.; Burguener, G.; Kim, S.; Zhang, X.; Yunusbaev, U.; Akhunov, E.; Lee, J.-Y.; Dubcovsky, J.

2026-07-08 plant biology
10.64898/2026.06.23.734071 bioRxiv
Show abstract

Celiac disease (CeD) is an immune-mediated condition triggered by wheat gluten in genetically predisposed individuals. The immune reaction in people with CeD is driven by particular gluten amino acid sequences, or immunogenic epitopes. Some of these epitopes elicit strong immune responses in the majority of CeD patients and are designated as immunodominant epitopes. Previous research has shown correlations between the amount of immunogenic wheat epitopes consumed and the onset of CeD, suggesting that reducing wheat immunogenic epitopes may reduce CeD incidence at the population level. Gluten consists of gliadins and glutenins, with gliadins having the majority of the immunodominant epitopes and glutenins playing a major role in dough strength and breadmaking quality (BMQ). This study used radiation-induced deletions, chemical mutagenesis, and natural variation in wheat (Triticum aestivum) to generate genetic stocks with reduced immunogenic epitope content. Most lines were developed in the wheat cultivar Summit, for which we produced a full genome assembly and annotation. We used exome capture to characterize these deletions and identify prolamins located within and outside the deletions. We combined different deletions and developed molecular markers to facilitate their deployment. For chromosome arms 1BS and 1DS, we generated two alternative lines: one lacking immunogenic epitopes for the development of CeD-safe genetic stocks for research purposes, and another retaining selected glutenins for breeding commercial lines with reduced immunogenicity and adequate BMQ. By making these non-transgenic genetic stocks publicly available, we aim to accelerate the development of wheat varieties with reduced immunogenicity and, eventually, a fully CeD-safe wheat.

Matching journals

The top 6 journals account for 50% of the predicted probability mass.

1
Plant Biotechnology Journal
64 papers in training set
Top 0.1%
18.6%
2
The Plant Genome
57 papers in training set
Top 0.1%
11.9%
3
Theoretical and Applied Genetics
49 papers in training set
Top 0.1%
7.9%
4
G3: Genes, Genomes, Genetics
252 papers in training set
Top 0.8%
5.5%
5
Frontiers in Plant Science
256 papers in training set
Top 1%
5.5%
6
Scientific Reports
3612 papers in training set
Top 18%
5.2%
50% of probability mass above
7
PLOS ONE
5266 papers in training set
Top 31%
4.9%
8
Nature Communications
5641 papers in training set
Top 32%
4.1%
9
New Phytologist
346 papers in training set
Top 2%
4.1%
10
Horticulture Research
47 papers in training set
Top 0.3%
3.3%
11
Journal of Experimental Botany
219 papers in training set
Top 2%
2.4%
12
G3: Genes|Genomes|Genetics
35 papers in training set
Top 0.1%
2.1%
13
Proceedings of the National Academy of Sciences
2444 papers in training set
Top 26%
1.9%
14
Communications Biology
993 papers in training set
Top 12%
1.9%
15
eLife
5828 papers in training set
Top 48%
1.7%
16
Plant Phenomics
18 papers in training set
Top 0.1%
1.7%
17
BMC Genomics
406 papers in training set
Top 6%
1.1%
18
Genome Biology
637 papers in training set
Top 7%
1.1%
19
Nature Plants
94 papers in training set
Top 2%
0.9%
20
GigaScience
212 papers in training set
Top 4%
0.8%
21
Science Advances
1243 papers in training set
Top 30%
0.8%
22
Molecular Plant-Microbe Interactions®
57 papers in training set
Top 1%
0.6%