Geraldine A. Toole

Endosperm development in Brachypodium distachyon

Grain development and its evolution in grasses remains poorly understood, despite cereals being our most important source of food. The grain, for which many grass species have been domesticated, is a single-seeded fruit with prominent and persistent endosperm. Brachypodium distachyon, a small wild grass, is being posited as a new model system for the temperate small grain cereals, but little is known about its endosperm development and how this compares with that of the domesticated cereals. A cellular and molecular map of domains within the developing Brachypodium endosperm is constructed. This provides the first detailed description of grain development in Brachypodium for the reference strain, Bd21, that will be useful for future genetic and comparative studies. Development of Brachypodium grains is compared with that of wheat. Notably, the aleurone is not regionally differentiated as in wheat, suggesting that the modified aleurone region may be a feature of only a subset of cereals. Also, the central endosperm and the nucellar epidermis contain unusually prominent cell walls that may act as a storage material. The composition of these cell walls is more closely related to those of barley and oats than to those of wheat. Therefore, although endosperm development is broadly similar to that of temperate small grain cereals, there are significant differences that may reflect its phylogenetic position between the Triticeae and rice.

Temporal and spatial changes in cell wall composition in developing grains of wheat cv. Hereward

A combination of enzyme mapping, FT-IR microscopy and NMR spectroscopy was used to study temporal and spatial aspects of endosperm cell wall synthesis and deposition in developing grain of bread wheat cv. Hereward. This confirmed previous reports that changes in the proportions of the two major groups of cell wall polysaccharides occur, with β-glucan accumulating earlier in development than arabinoxylan. Changes in the structure of the arabinoxylan occurred, with decreased proportions of disubstituted xylose residues and increased proportions of monosubstituted xylose residues. These are likely to result, at least in part, from arabinoxylan restructuring catalysed by enzymes such as arabinoxylan arabinofurano hydrolase and lead to changes in cell wall mechanical properties which may be required to withstand stresses during grain maturation and desiccation.

Mechanical properties of lettuce

The fracture properties of Spanish Iceberg and English Round lettuce tissues were investigated using a tensile test on notched specimens. The level of notch sensitivity was investigated for samples of differing colour and vein orientation. Vein orientation perpendicular to the test direction proved to be the most notch sensitive and samples with vein orientation parallel to the test direction proved to be very notch insensitive, samples with a diagonal (45°) orientation showed an intermediate response. This response was interpreted in terms of the interaction of veins with the crack path. The strengths of English Round tissues were broadly comparable with those of Spanish Iceberg although the upper limits depended on vein orientation and were in the order: parallel > diagonal ≈ perpendicular. A similar ranking of vein orientation was found in estimates of stiffness.

Remodelling of arabinoxylan in wheat (Triticum aestivum) endosperm cell walls during grain filling.

Previous studies using spectroscopic imaging have allowed the spatial distribution of structural components in wheat endosperm cell walls to be determined. FT-IR microspectroscopy showed differing changes in arabinoxylan (AX) structure, during grain development under cool/wet and hot/dry growing conditions, for differing cultivars (Toole et al. in Planta 225:1393–1403, 2007). These studies have been extended using Raman microspectroscopy, providing more details of the impact of environment on the polysaccharide and phenolic components of the cell walls. NMR studies provide complementary information on the types and levels of AX branching both early in development and at maturity. Raman microspectroscopy has allowed the arabinose:xylose (A/X) ratio in the cell wall AX to be determined, and the addition of ferulic acid and related phenolic acids to be followed. The changes in the A/X ratio during grain development were affected by the environmental conditions, with the A/X ratio generally being slightly lower for samples grown under cool/wet conditions than for those from hot/dry conditions. The degree of esterification of the endosperm cell walls with ferulic acid was also affected by the environment, being lower under hot/dry conditions. The results support earlier suggestions that AX is either delivered to the cell wall in a highly substituted form and is remodelled through the action of arabinoxylan arabinofuranohydrolases or arabinofuranosidases, or that low level substituted AX are incorporated into the wall late in cell wall development, reducing the average degree of substitution, and that the rate of this remodelling is influenced by the environment. 1H NMR provided a unique insight into the chemical structure of intact wheat endosperm cell walls, providing qualitative information on the proportions of mono- and disubstituted AX and the levels of branching of adjacent units. The A/X ratio did not change greatly with either the development stage or the growth conditions, but the ratio of mono- to disubstituted Xylp residues increased markedly (by about fourfold) in the more mature samples, confirming the changes in branching levels determined using FT-IR. To the best of our knowledge, this is the first time that intact endosperm cell walls have been studied by 1H NMR.

Fracture mechanics of the cell wall of Chara corallina.

Abstract. Previous mechanical studies using algae have concentrated on cell extension and growth using creep-type experiments, but there appears to be no published study of their failure properties. The mechanical strength of single large internode cell walls (up to 2 mm diameter and 100 mm in length) of the charophyte (giant alga) Chara corallina was determined by dissecting cells to give sheets of cell wall, which were then notched and fractured under tension. Tensile tests, using a range of notch sizes, were conducted on cell walls of varying age and maturity to establish their notch sensitivity and to investigate the propagation of cracks in plant cell walls. The thickness and stiffness of the walls increased with age whereas their strength was little affected. The strength of unnotched walls was estimated as 47 ± 13 MPa, comparable to that of some grasses but an order of magnitude higher than that published for model bacterial cellulose composite walls. The strength was notch-sensitive and the critical stress intensity factor K1c was estimated to be 0.63 ± 0.19 MNm−3/2, comparable to published values for grasses.

Digestibility of gluten proteins is reduced by baking and enhanced by starch digestion

Scope Resistance of proteins to gastrointestinal digestion may play a role in determining immune‐mediated adverse reactions to foods. However, digestion studies have largely been restricted to purified proteins and the impact of food processing and food matrices on protein digestibility is poorly understood. Methods and results Digestibility of a total gliadin fraction (TGF), flour (cv Hereward), and bread was assessed using in vitro batch digestion with simulated oral, gastric, and duodenal phases. Protein digestion was monitored by SDS‐PAGE and immunoblotting using monoclonal antibodies specific for celiac‐toxic sequences (QQSF, QPFP) and starch digestion by measuring undigested starch. Whereas the TGF was rapidly digested during the gastric phase the gluten proteins in bread were virtually undigested and digested rapidly during the duodenal phase only if amylase was included. Duodenal starch digestion was also slower in the absence of duodenal proteases. Conclusion The baking process reduces the digestibility of wheat gluten proteins, including those containing sequences active in celiac disease. Starch digestion affects the extent of protein digestion, probably because of gluten‐starch complex formation during baking. Digestion studies using purified protein fractions alone are therefore not predictive of digestion in complex food matrices.

A novel transcriptomic approach to identify candidate genes for grain quality traits in wheat.

A novel methodology is described in which transcriptomics is combined with the measurement of bread-making quality and other agronomic traits for wheat genotypes grown in different environments (wet and cool or hot and dry conditions) to identify transcripts associated with these traits. Seven doubled haploid lines from the Spark x Rialto mapping population were selected to be matched for development and known alleles affecting quality. These were grown in polytunnels with different environments applied 14 days post-anthesis, and the whole experiment was repeated over 2 years. Transcriptomics using the wheat Affymetrix chip was carried out on whole caryopsis samples at two stages during grain filling. Transcript abundance was correlated with the traits for approximately 400 transcripts. About 30 of these were selected as being of most interest, and markers were derived from them and mapped using the population. Expression was identified as being under cis control for 11 of these and under trans control for 18. These transcripts are candidates for involvement in the biological processes which underlie genotypic variation in these traits.

Effect of dough mixing on wheat endosperm cell walls.

Dough-derived cell wall fragments isolated by ultracentrifugation were largely derived from the starchy endosperm, with some fragments deriving from the aleurone and outer layers, as indicated by fluorescence microscopy. Dough mixing had little effect on the structure and composition of cell wall fragments compared to thin grain sections, as determined by Fourier transform infrared (FTIR) and (1)H nuclear magnetic resonance (NMR) spectroscopy. These analyses confirmed that the fragments largely comprised water-unextractable arabinoxylan and β-glucan. FTIR microspectroscopy of dough-derived cell wall fragments prepared from five bread wheat cultivars showed that two largely comprised highly substituted arabinoxylan (cv. Manital and San Pastore), one comprised a mixture of low, medium, and highly substituted arabinoxylan (cv. Hereward), and the remaining two comprised a greater proportion of low substituted arabinoxylan (cv. Claire and Yumai 34). Yumai 34 yielded a greater mass of cell wall material, and its cell walls comprised a high proportion of medium substituted arabinoxylan. Such methods will allow for the impact of bakery ingredients and processing on endosperm cells, including the addition of xylanases, to be investigated in the future to ensure any potential health benefits arising from wheat breeding are realized in the food that reaches the consumer.

SPECTROSCOPIC TECHNIQUES FOR INVESTIGATING THE EFFECT OF GROWING ENVIRONMENT ON ENDOSPERM CELL WALL COMPOSITION

ABSTRACT Advances in the quality of Fourier Transform Infrared detectors have enabled microspectroscopic analyses to be performed on biological samples which combine information on chemical composition with spatial resolution. When combined with multivariate statistical methods, fine differences between spectra can be determined across microscope sections. Novel sample preparation methods have been developed which have allowed the application of these methodologies to the analysis of wheat endosperm cell wall composition. Compositional differences can be identified between lines, particularly in arabinoxylans, which are confined to particular cell types found within the endosperm cell walls. Such cell-dependent changes in composition have not been identified previously due to limitations in conventional chemical analysis and were only possible to observe using these methods. Through the BBSRCs Exploiting Genomics Initiative (A Genomic Approach to Improving Wheat Grain Quality for Breadmaking), these biophysical methods of analysis are being combined with transcriptome and proteomic analysis of developing wheat. These are being used to investigate the effect environmental stress has on gene expression during grain development and subsequent composition and physical properties of the mature grain, which determine wheat end-use quality. Preliminary results indicate that growing conditions affect both the arabinoxylan branching patterns and their spatial distribution across the endosperm. Given that wheat endosperm cell walls are comprised almost entirely of arabinoxylans, it is likely that these changes will have some effect on the mechanical properties of me cell walls which may possibly be related to milling texture.