Impacts of Culture Conditions on Ligninolytic Enzymes (LIP, MNP, and Lac) Activity of Five Bacterial Strains

Date Received: Feb 27, 2020

Date Published: Sep 01, 2020

Views

1871

Download

588

Section:

ENGINEERING AND TECHNOLOGY

How to Cite:

Hien, P., Mau, T., Huyen, N., Dao, T., Giang, N., Hanh, T., … Canh, N. (2020). Impacts of Culture Conditions on Ligninolytic Enzymes (LIP, MNP, and Lac) Activity of Five Bacterial Strains. Vietnam Journal of Agricultural Sciences, 3(1), 520–529. https://doi.org/10.31817/vjas.2020.3.1.05

Impacts of Culture Conditions on Ligninolytic Enzymes (LIP, MNP, and Lac) Activity of Five Bacterial Strains

Pham Hong Hien (*) 1 , Tran Van Mau 2 , Nguyen Thanh Huyen 2 , Tran Thi Dao 2 , Nguyen Van Giang 2 , Tran Thi Hong Hanh 2 , Nguyen Thi Cam Chau 2   , Nguyen Xuan Canh 2

  • Corresponding author: nxcanh@vnua.edu.vn
  • 1 Department of Science and International Cooperation, Vietnam Academy of Agricultural Sciences, Hanoi 134000, Vietnam
  • 2 Faculty of Biotechnology, Vietnam National University of Agriculture, Hanoi 131000, Vietnam
  • Keywords

    ligninolytic enzymes, ligninase, lignin peroxidase, manganese peroxidase, laccase

    Abstract


    In this study, with the aim of determining and assessing the influence of several culture conditions on the ligninolytic enzyme (LiP, MnP, and Lac) activity of bacteria, five lignin-degrading bacteria strains were isolated from two different soil samples and cultured on minimum salt medium agar containing alkaline lignin (MSML agar). Among the five isolated strains, DL1 and X3 expressed strong and stable ligninase enzyme activity at various temperature levels (30°C, 37°C, 50°C, and 60°C) and were selected for further study. Notably, at 60°C, the ligninase activity of both strains lasted until the seventh day before decreasing. The effects of the culture medium conditions, namely, carbohydrate sources, nitrogen sources, and pH, on the ligninolytic system illustrated that both X3 and DL1 were able to generate good enzymatic activity at a pH range of 3.0 to 7.0. These strains could use various sources of carbohydrates and nitrogen, derived from glucose, lactose, peptone, meat extract, and yeast extract. In addition, the analyses of biochemical characteristics revealed that X3 was capable of hydrolyzing starch and cellulose, while DL1 was not. Therefore, the results of this study suggested the potential of applying selected lignin-degrading bacterial strains on lignin treatments of agricultural wastes.