Department of Biochemistry and Biotechnology, University of Gujrat, Pakistan.
Department of Biochemistry and Biotechnology, University of Gujrat, Pakistan.
Int J Biol Macromol. 2017 Nov;104(Pt A):242-250. doi: 10.1016/j.ijbiomac.2017.06.027. Epub 2017 Jun 7.
Biological macromolecules are primarily composed of complex polysaccharides that strengthen microbial growth for the production of industrially relevant enzymes. The presence of polysaccharides in the form of the disrupted cell wall and cell materials are among major challenges in the fruit juice industry. The breakdown of such biological macromolecules including cellulose and pectin is vital for the juices processing. In this background, pectinolytic enzymes including polygalacturonase (PG), pectin lyase (PL), and pectin methylesterase (PME) were isolated from Aspergillus ornatus, statistically optimized and purified via ammonium sulfate fractionation (ASF), dialysis, and Sephadex G-100 gel permeation chromatography. After passing through Sephadex G-100 column, PG, PL, and PME were 2.60-fold, 3.30-fold, and 4.52-fold purified with specific activities of 475.2U/mg, 557.1U/mg, and 205.7U/mg. The active PG, PL, and PME, each separately, were surface immobilized using various concentrations of chitosan and dextran polyaldehyde as a macromolecular crosslinking agent. Prior to exploit for juice clarification purposes, various parameters including pH, thermal and Michaelis-Menten kinetic constants of purified and chitosan-immobilized fractions were investigated. A considerable improvement in the pH and thermal profiles was recorded after immobilization. However, the negligible difference between the K and V values of purified free and chitosan-immobilized fractions revealed that the conformational flexibility of pectinolytics was retained as such. A significant color and turbidity reductions were recorded after 60min treatment with CTS-PG, followed by CTS-PME, and CTS-PL. It can be concluded that the clarification of apples, mango, peach, and apricot juices was greatly affected by CTS-PG, CTS-PME, and CTS-PL treatments rendering them as potential candidatures for food industry applications.
生物大分子主要由复杂的多糖组成,这些多糖可促进微生物生长,从而生产出具有工业应用价值的酶。多糖以破坏的细胞壁和细胞物质的形式存在,这是果汁行业面临的主要挑战之一。因此,纤维素和果胶等生物大分子的分解对果汁加工至关重要。在此背景下,从曲霉属中分离出聚半乳糖醛酸酶(PG)、果胶裂解酶(PL)和果胶甲酯酶(PME)等果胶酶,并通过硫酸铵分级沉淀(ASF)、透析和葡聚糖凝胶 G-100 凝胶过滤层析进行统计优化和纯化。经过葡聚糖凝胶 G-100 柱层析后,PG、PL 和 PME 的纯化倍数分别为 2.60 倍、3.30 倍和 4.52 倍,比活力分别为 475.2U/mg、557.1U/mg 和 205.7U/mg。分别将活性 PG、PL 和 PME 用不同浓度的壳聚糖和葡聚糖多醛作为高分子交联剂进行表面固定化。在用于果汁澄清之前,研究了各种参数,包括 pH 值、热稳定性和米氏常数动力学常数。固定化后,pH 值和热稳定性得到了显著改善。然而,纯化游离和壳聚糖固定化部分的 K 和 V 值之间的微小差异表明,果胶裂解酶的构象灵活性保持不变。用 CTS-PG、CTS-PME 和 CTS-PL 处理 60min 后,记录到显著的颜色和浊度降低。可以得出结论,CTS-PG、CTS-PME 和 CTS-PL 处理极大地影响了苹果、芒果、桃和杏汁的澄清度,使其成为食品工业应用的潜在候选物。
