Department of Biochemistry and Food Analysis, Poznan University of Life Sciences, Poznan, Poland.
Department of Meat Technology, Poznan University of Life Sciences, Poznan, Poland.
J Sci Food Agric. 2018 Nov;98(14):5212-5219. doi: 10.1002/jsfa.9057. Epub 2018 May 24.
Protein post-translational modifications are a key element for the functional diversity of the proteome. The modifications generally refer to the addition of functional groups to certain proteins; however, proteolytic cleavage is also one of the relevant events during protein maturation. γ-Conglutin is a unique protein fraction present in lupin seeds that is marked by numerous unusual properties. This protein fraction undergoes very complex post-translational maturation. Unfortunately, the precise mechanism of γ-conglutin post-translational processing is not yet fully understood.
Two independent methods were used to study γ-conglutin post-translational cleavage processing. Edman N-terminal sequencing indicates that the signal peptide is processed at Tyr34, while α- and β-subunit cleavage takes place between Ser295 and Ser296. High-resolution mass spectrometry revealed a great diversity of N-terminal sequences of γ-conglutin α-subunit. However, most abundant peptides also began from Tyr34. Mass spectrometric analyses additionally confirmed the subunit cleavage position between two serine residues.
The results indicate that the proteolytic processing of γ-conglutin signal peptide is not precise. On the other hand, the post-translational cleavage between α- and β-subunits of γ-conglutin is very conserved. Interestingly, the results also indicate that proteolytic processing leading to the formation of two subunits of γ-conglutin is incomplete, leaving a certain amount of the protein in an uncut form. © 2018 Society of Chemical Industry.
蛋白质翻译后修饰是蛋白质组功能多样性的关键因素。这些修饰通常是指在某些蛋白质上添加功能基团;然而,蛋白水解切割也是蛋白质成熟过程中的相关事件之一。γ-伴球蛋白是存在于羽扇豆种子中的一种独特蛋白质,具有许多不寻常的特性。这种蛋白质经历了非常复杂的翻译后成熟过程。不幸的是,γ-伴球蛋白翻译后加工的确切机制尚未完全了解。
使用两种独立的方法研究了γ-伴球蛋白翻译后切割加工。Edman N 末端测序表明信号肽在 Tyr34 处加工,而 α 和 β 亚基切割发生在 Ser295 和 Ser296 之间。高分辨质谱揭示了 γ-伴球蛋白α亚基的 N 末端序列具有很大的多样性。然而,最丰富的肽也始于 Tyr34。质谱分析还证实了两个丝氨酸残基之间的亚基切割位置。
结果表明γ-伴球蛋白信号肽的蛋白水解加工并不精确。另一方面,γ-伴球蛋白α和β亚基之间的翻译后切割非常保守。有趣的是,结果还表明,导致γ-伴球蛋白两个亚基形成的蛋白水解加工是不完全的,使得一定量的蛋白质以未切割的形式存在。© 2018 化学工业协会。
