TY - JOUR
T1 - Optimizing the biocatalytic productivity of an engineered sialidase from Trypanosoma rangeli for 3′-sialyllactose production
AU - Zeuner, Birgitte
AU - Luo, Jianquan
AU - Nyffenegger, Christian
AU - Aumala, Ville
AU - Mikkelsen, Jørn Dalgaard
AU - Meyer, Anne S.
PY - 2014
Y1 - 2014
N2 - An engineered sialidase, Tr6, from Trypanosoma rangeli was used for biosynthetic production of 3′-sialyllactose, a human milk oligosaccharide case compound, from casein glycomacropeptide (CGMP) and lactose, components abundantly present in industrial dairy side streams. Four different enzyme re-use methods were compared to optimize the biocatalytic productivity, i.e. 3′-sialyllactose formation per amount of Tr6 employed: (i) His-tag immobilization on magnetic Cu2+-iminodiacetic acid-functionalized nanoparticles (MNPs), (ii) membrane immobilization, (iii) calcium alginate encapsulation of cross-linked Tr6, and (iv) Tr6 catalysis in a membrane reactor. Tr6 immobilized on MNPs gave a biocatalytic productivity of 84mg 3′-sialyllactose/mg Tr6 after seven consecutive reaction runs. Calcium-alginate and membrane immobilization were inefficient. Using free Tr6 in a 10kDa membrane reactor produced a 9-fold biocatalytic productivity increase compared to using free Tr6 in a batch reactor giving 306mg 3′-sialyllactose/mg Tr6 after seven consecutive reaction runs. The 3′-sialyllactose yield on α-2,3-bound sialic acid in CGMP was 74%. Using circular dichroism, a temperature denaturation midpoint of Tr6, Tm, of 57.2°C was determined. The thermal stability of free Tr6 was similarly high and the Tr6 was stable at the reaction temperature (25°C) for at least 24h.
AB - An engineered sialidase, Tr6, from Trypanosoma rangeli was used for biosynthetic production of 3′-sialyllactose, a human milk oligosaccharide case compound, from casein glycomacropeptide (CGMP) and lactose, components abundantly present in industrial dairy side streams. Four different enzyme re-use methods were compared to optimize the biocatalytic productivity, i.e. 3′-sialyllactose formation per amount of Tr6 employed: (i) His-tag immobilization on magnetic Cu2+-iminodiacetic acid-functionalized nanoparticles (MNPs), (ii) membrane immobilization, (iii) calcium alginate encapsulation of cross-linked Tr6, and (iv) Tr6 catalysis in a membrane reactor. Tr6 immobilized on MNPs gave a biocatalytic productivity of 84mg 3′-sialyllactose/mg Tr6 after seven consecutive reaction runs. Calcium-alginate and membrane immobilization were inefficient. Using free Tr6 in a 10kDa membrane reactor produced a 9-fold biocatalytic productivity increase compared to using free Tr6 in a batch reactor giving 306mg 3′-sialyllactose/mg Tr6 after seven consecutive reaction runs. The 3′-sialyllactose yield on α-2,3-bound sialic acid in CGMP was 74%. Using circular dichroism, a temperature denaturation midpoint of Tr6, Tm, of 57.2°C was determined. The thermal stability of free Tr6 was similarly high and the Tr6 was stable at the reaction temperature (25°C) for at least 24h.
KW - trans-Sialidase
KW - Trypanosoma rangeli
KW - 3′-Sialyllactose
KW - Enzyme immobilization
KW - Enzymatic membrane reactor
KW - Thermal stability
U2 - 10.1016/j.enzmictec.2013.12.009
DO - 10.1016/j.enzmictec.2013.12.009
M3 - Journal article
C2 - 24411449
SN - 0141-0229
VL - 55
SP - 85
EP - 93
JO - Enzyme and Microbial Technology
JF - Enzyme and Microbial Technology
ER -