Immobilization of Lactobacillus bulgaricus with gellan gum and its application in continuous fermentation of D-lactic acid from corn straw.
- Author:
Yongxin GUO
1
;
Gang WANG
1
;
Kexin LI
1
;
Jiaqi HAN
1
;
Huan CHEN
1
;
Sitong ZHANG
1
;
Yanli LI
1
;
Guang CHEN
1
Author Information
- Publication Type:Journal Article
- Keywords: Lactobacillus delbrueckii; calcium alginate; corn straw; cyclic fermentation; gellan gum; immobilized
- MeSH: Fermentation; Lactobacillus delbrueckii; Zea mays; Lactic Acid; Alginates/chemistry*; Glucose
- From: Chinese Journal of Biotechnology 2023;39(3):1083-1095
- CountryChina
- Language:Chinese
- Abstract: Biorefinery of chemicals from straw is an effective approach to alleviate the environmental pollution caused by straw burning. In this paper, we prepared gellan gum immobilized Lactobacillus bulgaricus T15 gel beads (LA-GAGR-T15 gel beads), characterized their properties, and established a continuous cell recycle fermentation process for D-lactate (D-LA) production using the LA-GAGR-T15 gel beads. The fracture stress of LA-GAGR-T15 gel beads was (91.68±0.11) kPa, which was 125.12% higher than that of the calcium alginate immobilized T15 gel beads (calcium alginate-T15 gel beads). This indicated that the strength of LA-GAGR-T15 gel beads was stronger, and the strain was less likely to leak out. The average D-LA production was (72.90±2.79) g/L after fermentation for ten recycles (720 h) using LA-GAGR-T15 gel beads as the starting strain and glucose as the substrate, which was 33.85% higher than that of calcium alginate-T15 gel beads and 37.70% higher than that of free T15. Subsequently, glucose was replaced by enzymatically hydrolyzed corn straw and fermented for ten recycles (240 h) using LA-GAGR-T15 gel beads. The yield of D-LA reached (1.74±0.79) g/(L·h), which was much higher than that of using free bacteria. The wear rate of gel beads was less than 5% after ten recycles, which indicated that LA-GAGR is a good carrier for cell immobilization and can be widely used in industrial fermentation. This study provides basic data for the industrial production of D-LA using cell-recycled fermentation, and provides a new way for the biorefinery of D-LA from corn straw.
