ABSTRACT
This study focused on the extraction, purification, and physicochemical characterization of γ-conglutin, a protein present in lupin seeds with properties of reducing blood glucose levels. Total protein was extracted with an alkaline-saline solvent, followed by isoelectric precipitation. Chromatographic purification of the precipitated fraction was performed using a cation exchange supermacroporous cryogel column. Electrophoresis of the eluted fraction from chromatography presented a single band of â¼48 kDa under non-reducing conditions (two bands of â¼30 and â¼17 kDa, under reducing conditions) confirming the success of the purification protocol. Liquid chromatography-tandem mass spectrometry analysis confirmed the identity of the protein as γ-conglutin. The purified γ-conglutin had an isoelectric point of 7.51, ß-sheets prevailing as a secondary structure, and denaturation temperature close to 68°C. The outcome of this work showed that γ-conglutin was obtained with a high degree of purity. The proposed purification protocol is simple and can be easily scaled up.
Subject(s)
Lupinus , Cations/analysis , Cryogels , Lupinus/chemistry , Lupinus/metabolism , Plant Proteins/analysis , Seeds/chemistryABSTRACT
In 2017-2019, we conducted the field and vegetation experiments at the field station of Russian State Agrarian University, Moscow Timiryazev Agricultural Academy to study the effect of sodium selenite on the yield and grain quality indicators of white lupine, Dega variety, and spring wheat, Yubileynaya-80 variety. The best way found to use selenium is to spray vegetative plants with 0.01% aqueous sodium selenite solution. The studies have shown an increase in grain yield by 15-17%, crude protein content by 9-15% and crude fat content by 5-7% when treated with sodium selenite. The obtained grain yield of white lupine has a higher feed and nutritional value and is suitable for feeding animals and preparing various types of feed and feed additives. The optimal way to use selenium is spraying vegetative plants before shooting. Treatment with sodium selenite contributes to an increase in wheat yield by 1.5 times. We have established the positive effect of sodium selenite on the quality indicators of wheat grain. An increase in the content of raw gluten and glassiness of grain has been noted, which determines high bread-making qualities.
Em 2017-2019, conduzimos os experimentos de campo e vegetação na estação de campo da Universidade Agrária Estatal Russa, Academia Agrícola Timiryazev de Moscou, para estudar o efeito do selenito de sódio nos indicadores de rendimento e qualidade de grãos de tremoço branco, variedade Dega, e trigo de primavera, variedade Yubileynaya-80. A melhor maneira encontrada para usar o selênio é pulverizar as plantas vegetativas com solução aquosa de selenito de sódio a 0,01%. Os estudos mostraram um aumento no rendimento de grãos em 15-17%, teor de proteína bruta em 9-15% e teor de gordura bruta em 5-7% quando tratados com selenito de sódio. O rendimento de grãos obtido de tremoço branco tem maior valor alimentar e nutricional e é adequado para alimentação de animais e preparação de vários tipos de rações e aditivos alimentares. A maneira ideal de usar o selênio é pulverizar plantas vegetativas antes de fotografar. O tratamento com selenito de sódio contribui para um aumento no rendimento do trigo em 1,5 vez. Estabelecemos o efeito positivo do selenito de sódio nos indicadores de qualidade do grão de trigo. Observou-se um aumento no teor de glúten cru e vítreo do grão, o que determina altas qualidades de panificação.
Subject(s)
Triticum/growth & development , Sodium Selenite , Lupinus/growth & developmentABSTRACT
Alkaloids are part of a structurally diverse group of over 21,000 cyclic nitrogen-containing secondary metabolites that are found in over 20% of plant species. Lupinus albus are naturally containing quinolizidine alkaloid (QA) legumes, with wild accessions containing up to 11% of QA in seeds. Notwithstanding their clear advantages as a natural protecting system, lupin-breeding programs have selected against QA content without proper understanding of quinolizidine alkaloid biosynthetic pathway. This review summarizes the current status in this field, with focus on the utilization of natural mutations such as the one contained in pauper locus, and more recently the development of molecular markers, which along with the advent of sequencing technology, have facilitated the identification of candidate genes located in the pauper region. New insights for future research are provided, including the utilization of differentially expressed genes located on the pauper locus, as candidates for genome editing. Identification of the main genes involved in the biosynthesis of QA will enable precision breeding of low-alkaloid, high nutrition white lupin. This is important as plant based high quality protein for food and feed is an essential for sustainable agricultural productivity.