Recent developments in high-performance capillary electrophoresis of cereal proteins.

Cereal proteins play important nutritional and functional roles in human foods and are also important components of animal feeds. As such, cereals are a major economic factor around the world. Because of their importance, cereal proteins have been widely studied. A new emerging technique for studying cereal proteins is high-performance capillary electrophoresis (HPCE). This review focuses mainly on new methods and applications of HPCE to cereal proteins that have been reported in the last three years.

High-performance capillary electrophoresis of meat, dairy, and cereal proteins.

Food proteins play important roles in food functionality, nutrition, and human health. For these reasons, new analytical methods are continually being developed to separate and characterize these important proteins. High-performance capillary electrophoresis (HPCE) is one of the latest analytical methods to be applied to the separation of food proteins. This review covers methods and applications for the separation of three major groups of food proteins, meat, dairy, and cereal proteins.

Electrophoresis of cereal storage proteins.

Cereal proteins have been studied by a number of analytical techniques over the years. One of the major methodologies utilized by cereal chemists has been electrophoresis. Starting with moving boundary electrophoresis and progressing to slab gels and high-performance capillary electrophoresis, innovative methods have been developed to provide high resolution separations of difficult to separate proteins. Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE), acid-PAGE, isoelectric focusing, free zone CE, and even high-resolution two-dimensional HPLC-HPCE methods have been developed to separate cereal proteins. This review focuses on electrophoretic methods for separating and characterizing cereal storage proteins.

Acetonitrile as a buffer additive for free zone capillary electrophoresis separation and characterization of maize (Zeamays L. ) and sorghum (Sorghum bicolor L. Moench) storage proteins.

An improved method for separating and characterizing maize (Zea mays L.) and sorghum (Sorghum bicolor L. Moench) storage proteins by free zone capillary electrophoresis (FZCE) was developed. Previous electrophoretic methods for analyzing these proteins required high concentrations of urea to maintain protein solubility during separation. To overcome disadvantages of urea, we developed a FZCE method that mimicked reversed-phase high-performance liquid chromatography (RP-HPLC) in that it used high levels of acetonitrile (ACN) at low pH. The optimized FZCE buffer system consisted of 80 mM phosphate-glycine buffer, nominal pH 2.5, containing 60% ACN and a cellulose derivative to dynamically coat capillary walls. Resolution was similar to or higher than that previously achieved by FZCE buffers utilizing 8 M urea as a buffer additive. ACN concentrations of at least 50% were necessary to achieve acceptable separations; this ACN concentration is approximately that necessary to extract these storage proteins. ACN was equally effective as traditional ethanol solvents and 8 M urea for solubilizing maize and sorghum proteins. The ACN-based FZCE buffer system gave high repeatability (<0.3% relative standard deviation, measured over 15 consecutive injections) for migration time. Subclasses of maize and sorghum storage proteins were identified, and genotypes of each cereal were successfully differentiated using ACN-containing buffers. This FZCE method may be applicable for the analysis of other hydrophobic proteins without the use of urea.

Ultrafast capillary electrophoretic analysis of cereal storage proteins and its applications to protein characterization and cultivar differentiation.

Free zone capillary electrophoresis conditions have been improved to allow rapid (2-8 min) separations of grain proteins from several cereals (wheat, oats, rice, barley, and rye) with high resolution and reproducibility. This new method utilized the isoelectric compound iminodiacetic acid (IDA) in conjunction with 20% acetonitrile and 0.05% hydroxypropylmethylcellulose. Cultivars of all cereals tested could be differentiated in 3 min, including wheat, using either prolamin or glutelin protein patterns. Resolution was similar to or higher than that of separations in other acidic buffers. Migration time repeatability was excellent with run-to-run variability <1% RSD, day-to-day <1.4% RSD, and capillary-to-capillary <3.3% RSD. Because larger inner diameter capillaries (50 microm) could be used with this buffer, sensitivity was improved and capillary rinse times could be reduced when compared to smaller capillaries (25 microm i.d.). This also served to reduce total separation time so that the majority of cereal storage protein from several types of cereals could be analyzed with total analysis times of 2-8 min with extremely high resolution and repeatability. This method would allow unattended, high-throughput ( approximately 180-400 samples/24 h) analysis of cereal proteins without the generation of much organic solvent waste as well as automated data analysis and storage.

Sodium dodecyl sulfate capillary electrophoresis of wheat proteins. 1. Uncoated capillaries.

Four different polymer/buffer systems (a commercial polymer from Bio-Rad, dextran, poly(ethylene oxide) (PEO), and non-crosslinked poly(acrylamide)) were evaluated for use in sodium dodecyl sulfate capillary electrophoresis (SDS-CE) separations of wheat proteins. These polymers were chosen on the basis of published reports of their use in uncoated or dynamically coated capillaries. Each polymer was optimized (where possible) by manipulating the polymer concentration and buffer concentration, and through the use of organic modifiers such as methanol and ethylene glycol. The addition of ethylene glycol to the separation buffer was found to improve the resolution of the separations, despite dilution of the sieving polymers. When PEO was used as the sieving polymer, however, no improvement was seen when ethylene glycol was added. Despite producing similar separations of molecular mass markers, the polymers did not all produce similar wheat protein separations. The commercial reagent and dextran produced similar separations, while the poly(acrylamide) produced faster separations than either. The poly(acrylamide) displayed much lower resolution in the 40-60 kDa range than the other polymers, though this polymer was able to separate the high molecular mass glutenin subunits (HMM-GS) without the use of added organic solvent. PEO produced much different wheat protein separations than the other polymers, despite similar separations of the molecular weight markers. This may have been due to interaction between the wheat proteins and PEO. Each polymer system also predicted different molecular masses of the various wheat protein fractions separated, with the PEO and poly(acrylamide) grossly overestimating the masses for all protein classes. This could have been due to protein-polymer interactions. Further work was done with the Bio-Rad buffer modified by the addition of ethylene glycol. Several different wheat protein fractions as well as proteins extracted from several different cultivars were separated with this buffer and compared. SDS-CE separations were also compared to SDS-poly(acrylamide) gel electrophoresis (PAGE) and several differences in the migration pattern of HMM-GS were noted.

Separation and characterization of barley (Hordeum vulgare L.) hordeins by free zone capillary electrophoresis.

Extraction conditions, separation conditions, and capillary rinsing protocols were optimized for the separation of barley hordeins by free zone capillary electrophoresis. Stable hordein extracts were obtained with a single 5 min extraction after the albumins and globulins were removed. Hordeins had to be reduced for optimal resolution. Optimum separation conditions for hordein separations were 100 mM phosphate-glycine buffer containing 20% acetonitrile and 0.05% hydroxypropylmethylcellulose. The addition of zwitterionic sulfobetaine detergents containing hydrocarbon tails of eight and ten carbons slightly improved the resolution of the separations, but not enough to warrant their use on a routine basis. The migration positions of the hordein subclasses were determined by two- dimensional reversed-phase high-performance liquid chromatography x free zone capillary electrophoresis mapping. The hordein subclasses formed clusters similar to those of wheat gliadins. Separation-to-separation repeatability was good, with migration time relative standard deviations < 1% for a 15-run period. For routine discrimination of cultivars, a 2 min post-separation rinse with 500 mM acetic acid was necessary to prevent protein build-up on the capillary walls. An example of successfully differentiating barley cultivars using this technique is shown.

High-performance capillary electrophoresis of cereal proteins.

Cereal grains are widely used of human foods and animal feed throughout the world. Cereals provide dietary protein, which also often has a functional role, as wheat gluten does in bread. Cereal proteins are unique in many ways: they are highly complex and heterogeneous, are often difficult to extract, and aggregate readily, making them difficult to characterize. Because of the economic importance and widespread use of cereal proteins, however, many techniques have been used for their analysis. High-performance capillary electrophoresis (HPCE) is one of the newest techniques to be so used. This review describes the development of charge- and size-based HPCE methods for analysis of cereal grain proteins, and the use of these methods for cultivar identification, classification, and prediction of quality. HPCE is versatile, rapid, easily automated, readily quantified, and provides high-resolution separations. Clearly, HPCE is a valuable addition to other methods of cereal protein analysis and should, in time, be applicable to all protein classes from all cereals.

Faster capillary electrophoresis separation of wheat proteins through modifications to buffer composition and sample handling.

Studies were conducted to produce faster, simpler, more rugged protocols for separating wheat proteins by high performance capillary electrophoresis (HPCE). Three areas were targeted for improvement: initial capillary equilibration procedures, buffer composition, and post-separation rinsing procedures. For the initial equilibration of capillaries, a brief rinse with a hydroxypropylmethylcellulose (HPMC) solution was the most critical factor for successful separation of wheat proteins. To reduce separation time and maintain resolution, beta-alanine and glycine were each used in place of sodium phosphate as buffer ions. Two isoelectric buffers, aspartic acid and iminodiacetic acid (IDA) were also tested. Each of these four buffer systems generated substantially lower currents, and provided faster separations, than sodium phosphate-based buffers. Finally, post-separation rinsing procedures were re-examined with the goal of reducing the time necessary to rinse the capillary after each separation. A critical factor in achieving this goal was removal of albumins and globulins prior to separation. These proteins bind to the capillary wall and cause rising baselines and excessive peak tailing. Once these proteins were removed, capillaries could be rinsed with buffer for only 2 min between separations. Capillary equilibration procedures were shortened from 90 min to 30 min. Likewise, separation times were reduced by approximately 40% (25 min to 15 min) by using glycine in place of sodium phosphate in the separation buffer. Finally, post-separation times were reduced by 80% (10 min to 2 min). Overall, these factors resulted in a reduction in total separation time of 50% (35 to 17 min) and maintained high resolution separations and good run-to-run repeatability.

Heritable somaclonal variation in gliadin proteins of wheat plants derived from immature embryo callus culture.

Fertile r0 plants of the winter wheat line ND7532 (Triticum aestivum L.) were regenerated from callus tissue after 60-190 days in culture. Seeds produced from these self-pollinated plants were planted in the field. Of the 5586 R1 plants, 32 differed for one or more agronomic traits from plants not passed through tissue culture process. Gliadin electrophoregrams were prepared from bulk samples of R2 seed from these 32 plants. Four of the 32 produced gliadin patterns different from controls, so 12 seeds of each of these four lines were examined individually. Three of the four mutant lines were fixed for the presence of a mutant protein of 50 relative mobility units (RMU) and the corresponding loss of a parental protein of 26 RMU. The remaining line segregated for the presence/absence of band 50 and the corresponding loss/retention of band 26. The mutant protein of 50 RMU was never seen in control plants. This indicated that either band 50 was coded for by a mutant gene allelic to the gene that coded for band 26 or that bands 26 and 50 were coded for by two different structural alleles under the control of a common regulatory locus. Each of the 12 seeds from the four mutant lines contained a prominent protein band at 30 (RMU), which was only observed as a faint band in one control seed. The types of variation in gliadin patterns observed in somaclones of ND7532 were similar to those reported for the line 'Yaqui 50E', except that, gliadin changes occurred less frequently in ND7532.