Abstract
SummaryFree asparagine is the precursor for acrylamide, which forms during the baking, toasting and high‐temperature processing of foods made from wheat. In this study, CRISPR/Cas9 was used to knock out the asparagine synthetase gene, TaASN2, of wheat (Triticum aestivum) cv. Cadenza. A 4‐gRNA polycistronic gene was introduced into wheat embryos by particle bombardment and plants were regenerated. T1 plants derived from 11 of 14 T0 plants were shown to carry edits. Most edits were deletions (up to 173 base pairs), but there were also some single base pair insertions and substitutions. Editing continued beyond the T1 generation. Free asparagine concentrations in the grain of plants carrying edits in all six TaASN2 alleles (both alleles in each genome) were substantially reduced compared with wildtype, with one plant showing a more than 90 % reduction in the T2 seeds. A plant containing edits only in the A genome alleles showed a smaller reduction in free asparagine concentration in the grain, but the concentration was still lower than in wildtype. Free asparagine concentration in the edited plants was also reduced as a proportion of the free amino acid pool. Free asparagine concentration in the T3 seeds remained substantially lower in the edited lines than wildtype, although it was higher than in the T2 seeds, possibly due to stress. In contrast, the concentrations of free glutamine, glutamate and aspartate were all higher in the edited lines than wildtype. Low asparagine seeds showed poor germination but this could be overcome by exogenous application of asparagine.
Highlights
The accumulation of free asparagine in grains, tubers, storage roots, beans and other crop products is the focus of much research because free asparagine is the precursor for acrylamide (CH2=CHC(O)NH2) formation during cooking and processing (Mottram et al, 2002; Stadler et al, 2002)
The guide RNAs (gRNAs) all showed at least two mismatches to the other TaASN genes in the PAM-proximal region shown to be crucial for Cas9 function (Kuscu et al, 2014), with the gRNA4 position lacking the requisite PAM sequence
The use of the technology in wheat protoplasts was described in 2014 (Shan et al, 2014), and Wang et al (2014) used it to knock out the A genome TaMLO1 gene, which is involved in powdery mildew resistance
Summary
The accumulation of free (soluble, non-protein) asparagine in grains, tubers, storage roots, beans and other crop products is the focus of much research because free asparagine is the precursor for acrylamide (CH2=CHC(O)NH2) formation during cooking and processing (Mottram et al, 2002; Stadler et al, 2002). In 2006, a United Nations’ Food and Agriculture Organisation and World Health Organisation Joint Expert Committee on Food Additives (JECFA) report stated that the potential cancer-causing effects of acrylamide in the diet were a concern (JECFA, 2006), and the European Food Safety Authority (EFSA) Panel on Contaminants in the Food Chain (CONTAM) came to a similar conclusion in 2015 (CONTAM Panel, 2015) This led to the adoption of European Commission (EC) Regulation (EU) 2017/2158 (European Commission, 2017), which states that ‘acrylamide in food potentially increases the risk of developing cancer for consumers in all age groups’, sets Benchmark Levels for acrylamide in different food types, and threatens the introduction of Maximum Levels (levels above which it would be illegal to sell a food product). (November 2019) the European Commission issued Recommendation (EU) 2019/1888, which stated that levels of acrylamide should be monitored in a range of foods that did not fall within the scope of Regulation (EU) 2017/2158, including a number of bakery and cereal products (European Commission, 2019)
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