Mollerup Filip, Parikka Kirsti, Vuong Thu V, Tenkanen Maija, Master Emma
Department of Biotechnology and Chemical Technology, Aalto University, 00076 Aalto, Finland.
Department of Food and Environmental Sciences, University of Helsinki, P.O. Box 27, Helsinki 00014, Finland.
Biochim Biophys Acta. 2016 Feb;1860(2):354-62. doi: 10.1016/j.bbagen.2015.10.023. Epub 2015 Oct 27.
Galactose oxidase (GaO) selectively oxidizes the primary hydroxyl of galactose to a carbonyl, facilitating targeted chemical derivatization of galactose-containing polysaccharides, leading to renewable polymers with tailored physical and chemical properties. Here we investigate the impact of a family 29 glucomannan binding module on the activity and binding of GaO towards various polysaccharides. Specifically, CBM29-1-2 from Piromyces equi was separately linked to the N- and C-termini of GaO.
Both GaO-CBM29 and CBM29-GaO were successfully expressed in Pichia pastoris, and demonstrated enhanced binding to galactomannan, galactoglucomannan and galactoxyloglucan. The position of the CBM29 fusion affected the enzyme function. Particularly, C-terminal fusion led to greatest increases in galactomannan binding and catalytic efficiency, where relative to wild-type GaO, kcat/Km values increased by 7.5 and 19.8 times on guar galactomannan and locust bean galactomannan, respectively. The fusion of CBM29 also induced oligomerization of GaO-CBM29.
Similar to impacts of cellulose-binding modules associated with cellulolytic enzymes, increased substrate binding impeded the action of GaO fusions on more concentrated preparations of galactomannan, galactoglucomannan and galactoxyloglucan; this was especially true for GaO-CBM29. Given the N-terminal positioning of the native galactose-binding CBM32 in GaO, the varying impacts of N-terminal versus C-terminal fusion of CBM29-1-2 may reflect competing action of neighboring CBMs.
This study thoroughly examines and discusses the effects of CBM fusion to non-lignocellulytic enzymes on soluble polysaccharides. Herein kinetics of GaO on galactose containing polysaccharides is presented for the first time.
半乳糖氧化酶(GaO)可将半乳糖的伯羟基选择性氧化为羰基,有助于对含半乳糖的多糖进行靶向化学衍生化,从而得到具有定制物理和化学性质的可再生聚合物。在此,我们研究了29家族葡甘露聚糖结合模块对GaO与各种多糖的活性及结合的影响。具体而言,将来自马胃蝇的CBM29-1-2分别连接到GaO的N端和C端。
GaO-CBM29和CBM29-GaO均在毕赤酵母中成功表达,并显示出与半乳甘露聚糖、半乳葡甘露聚糖和半乳木葡聚糖的结合增强。CBM29融合的位置影响酶的功能。特别是,C端融合导致半乳甘露聚糖结合和催化效率的最大提高,相对于野生型GaO,在瓜尔豆半乳甘露聚糖和刺槐豆半乳甘露聚糖上,kcat/Km值分别增加了7.5倍和19.8倍。CBM29的融合还诱导了GaO-CBM29的寡聚化。
与纤维素分解酶相关的纤维素结合模块的影响类似,增加的底物结合阻碍了GaO融合物对更高浓度的半乳甘露聚糖、半乳葡甘露聚糖和半乳木葡聚糖制剂的作用;对于GaO-CBM29尤其如此。鉴于GaO中天然半乳糖结合CBM32的N端定位,CBM29-1-2的N端与C端融合的不同影响可能反映了相邻CBM的竞争作用。
本研究全面考察并讨论了CBM与非木质纤维素酶融合对可溶性多糖的影响。本文首次报道了GaO对含半乳糖多糖的动力学研究。
