Utilization of agro-industrial by-products as substrates for dextransucrase production by Leuconostoc mesenteroides T3: Process optimization using response surface methodology

Chemical Industry Pub Date : 2021-01-01 DOI:10.2298/HEMIND200710015M

Miona Miljkovic, Sladjana Davidović, A. Djukić‐Vuković, M. Ilić, Milica Simović, M. Rajilić-Stojanović, S. Dimitrijević-Branković

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Abstract

Dextransucrase (DS) is a glucosyltransferase (E. C. 2.4.1.5) that catalyzes the transfer of glucosyl residues from sucrose to dextran polymer and liberates fructose. This enzyme isassociated with a wide application range of dextran and oligosaccharides. DS production by Leuconostoc mesenteroidesT3 was optimized using a Central Composite Design under the Response Surface Methodology. Three variables were chosen for optimization: distillery stillage, sucrose and manganese concentration. The results showed that sucrose and manganese concentrations had a positive linear effect on DS production while all variable interactions (stillage-manganese, stillage-sucrose, and sucrose-manganese) had significant influences on the DS production. The maximal DS yield of 3.391?0.131 U cm-3, was obtained in the medium with 64.33 % distillery stillage concentration, 5.30% sucrose concentration and 0.022 % manganese concentration. Our study revealed the potential of distillery stillage combined with sugar beet molasses, supplemented with sucrose and manganese to be employed as a valuable medium growth for lactic acid bacteria and production of DS. Also, taking into consideration the origin of the substrates, utilization of industrial by-products in this way has a great environmental relevance and is in accordance with circular economy.

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利用农副产物作为底物生产右旋蔗糖酶:响应面法优化工艺

右旋蔗糖酶(DS)是一种葡萄糖基转移酶(e.c. 2.4.1.5)，它催化葡萄糖基残基从蔗糖转移到右旋糖酐聚合物并释放果糖。该酶与葡聚糖和低聚糖有广泛的应用范围。采用响应面法下的中心复合设计对Leuconostoc mesenteroidesT3产DS进行优化。选择了3个变量进行优化:蒸馏液、蔗糖和锰浓度。结果表明，蔗糖浓度和锰浓度对稻瘟病菌产量有显著的线性正相关影响，而所有变量交互作用(枯草-锰、枯草-蔗糖和蔗糖-锰)对稻瘟病菌产量均有显著影响。在酒糟浓度为64.33%、蔗糖浓度为5.30%、锰浓度为0.022%的培养基中，DS产率最高为3.391 ~ 0.131 U cm-3。我们的研究揭示了在甜菜糖蜜中添加蔗糖和锰作为乳酸菌生长和DS生产的培养基的潜力。此外，考虑到基材的来源，以这种方式利用工业副产品具有很大的环境相关性，并且符合循环经济。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Chemical Industry

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