College of Resources and Environmental Sciences, Nanjing Agricultural University, Jiangsu Province, People's Republic of China; Jiangsu Key Lab of Marine Biology, Nanjing, People's Republic of China.
College of Resources and Environmental Sciences, Nanjing Agricultural University, Jiangsu Province, People's Republic of China.
Int J Biol Macromol. 2018 Mar;108:9-17. doi: 10.1016/j.ijbiomac.2017.11.110. Epub 2017 Nov 20.
Inulinases from microorganisms have been extensively studied for their role in the production of fructose from fructan. Fructan can also be hydrolyzed by plant fructan exohydrolases (FEHs), but these enzymes have not been used to produce fructose commercially. Two Ht1-FEHs (Ht1-FEH I and Ht1-FEH II) were recently characterized in Jerusalem artichoke. In this study, we cloned the third member of the Ht1-FEH family in Jerusalem artichoke (i.e., Ht1-FEH III). When heterologously expressed in Pichia pastoris X-33, Ht1-FEH III not only demonstrated hydrolysis activity towards β (2, 1)-linked fructans and β (2, 6)-linked levan, but also towards sucrose. To explore the potential industrial applications, we heterologously expressed and purified six plant 1-FEHs from two typical fructan plants (i.e., chicory and Jerusalem artichoke) and showed that chicory Ci1-FEH IIa had the highest hydrolysis capacity to fructan in vitro. Furthermore, we immobilized Ci1-FEH IIa on resin and optimized the immobilization conditions. We found that inulin-type fructan or the tuber extract from Jerusalem artichoke could be rapidly degraded into fructose and sucrose by immobilized Ci1-FEH IIa. The capacity of Ci1-FEH IIa to release fructose from fructans was comparable to that of some inulinases from microorganisms. Thus, plant FEHs have potential applications in fructose production.
微生物来源的菊粉酶在从菊粉生产果糖方面的作用已得到广泛研究。植物的果聚糖外切水解酶(FEHs)也可以水解果聚糖,但这些酶尚未被用于商业生产果糖。最近在菊苣中鉴定了两种 Ht1-FEH(Ht1-FEH I 和 Ht1-FEH II)。在本研究中,我们克隆了菊苣中 Ht1-FEH 家族的第三个成员(即 Ht1-FEH III)。当在巴斯德毕赤酵母 X-33 中异源表达时,Ht1-FEH III 不仅对 β(2,1)-连接的果聚糖和 β(2,6)-连接的蔗果聚糖具有水解活性,而且对蔗糖也具有水解活性。为了探索潜在的工业应用,我们从两种典型的果聚糖植物(即菊苣和菊芋)中异源表达和纯化了 6 种植物 1-FEH,并表明菊苣 Ci1-FEH IIa 在体外对果聚糖具有最高的水解能力。此外,我们将 Ci1-FEH IIa 固定在树脂上并优化了固定化条件。我们发现,菊苣型果聚糖或菊芋块茎提取物可以通过固定化 Ci1-FEH IIa 迅速降解为果糖和蔗糖。Ci1-FEH IIa 从果聚糖释放果糖的能力与一些微生物来源的菊粉酶相当。因此,植物 FEHs 在果糖生产方面具有潜在的应用前景。
