Ståhlberg J, Johansson G, Pettersson G
Institute of Biochemistry, Uppsala University, Sweden.
Biochim Biophys Acta. 1993 May 7;1157(1):107-13. doi: 10.1016/0304-4165(93)90085-m.
Adsorption to and formation of insoluble reducing end groups on cellulose was studied for intact enzymes and catalytic domains, 'cores', of the four major cellulases from Trichoderma reesei, CBH I, CBH II, EG I and EG III. Individual enzymes were incubated with NaBH4-reduced, phosphoric acid swollen Avicel (regenerated cellulose) or with filter paper. Adsorption onto regenerated cellulose was rapid (equilibration reached within 2 min), but was slow onto filter paper (not completed after 24 h). On both substrates, less was bound of the core domains than of the intact enzymes. After reaching a maximum in adsorption, all the core domains except CBH I core were released again. In general, the desorption of the core enzymes was much faster than the rate of substrate conversion. All enzymes produced new reducing end groups on both substrates, and thus none of them is a true exo-cellulase. However, both the rate of formation and the amount was considerably higher for the EG enzymes than for the CBH's, which may justify the classification of cellulases into two groups, although the difference is quantitative rather than qualitative. EG III was the most endo-active of the enzymes, and CBH I the least.
研究了里氏木霉四种主要纤维素酶CBH I、CBH II、EG I和EG III的完整酶和催化结构域(“核心”)在纤维素上的吸附以及不溶性还原端基的形成。将单个酶与硼氢化钠还原的、磷酸膨胀的微晶纤维素(再生纤维素)或滤纸一起孵育。在再生纤维素上的吸附很快(2分钟内达到平衡),但在滤纸上的吸附很慢(24小时后未完成)。在两种底物上,核心结构域的结合量都比完整酶少。在吸附达到最大值后,除CBH I核心外的所有核心结构域都再次释放。一般来说,核心酶的解吸比底物转化的速度快得多。所有酶在两种底物上都产生了新的还原端基,因此它们都不是真正的外切纤维素酶。然而,EG酶的形成速率和量都比CBH酶高得多,这可能证明将纤维素酶分为两组是合理的,尽管差异是定量的而非定性的。EG III是这些酶中内切活性最高的,而CBH I是最低的。
