earticle

영어

The effects of carbon sources for exopolysaccharide production during batch cultivation of an Enterobacter sp. isolated from the composter were investigated. The highest amount of exopolysaccharide was obtained when lactose was used as carbon source. Lactose in medium was converted into glucose and galactose. Glucose was metabolized fast and was completely
consumed, but about 20% of lactose was accumulated as galactose. On the other hand, enzyme activity was about 350～450 unit with the increase of lactose concentration. Thus, it was considered that the exopolysaccharide might be produced in the course of that lactose was hydrolyzed into glucose and galactose by β-galactosidase with respect to that enzyme activity
on lactose hydrolysis was accorded to the exopolysaccharide production. When glucose and galactose were added to lactose medium, respectively, it could be considered that glucose was as a repressor and galactose was as a inducer for β -galactosidase synthesis even though the mechanisms were not elucidated. The increase of lactose concentration was almost
ineffective to the specific growth rate (0.133～0.151 hr-1) but showed the difference in the biomass content. The higher carbon source concentration, the more residual sugar remained. It was assumed that the optimum lactose concentration for exopolysaccharide production was 30～70 g/L. On the other hand, it was considered that the nitrogen acted as growth limiting nutrients to the cell growth. In the cases of 30 and 70 g/L of the fixed carbon concentrations, the increase of the nitrogen sources concentration caused a remarkable increase within the range of 0.059～0.225 hr-1 and 0.141～0.237 hr-1 of the specific growth rate, respectively, while there was no significant difference in biomass.

한국어

유기성 폐기물의 composting에 사용된 토양유래의 복합 발효 미생물 제제로부터 분리, 동정된 다당 생성 균주인 Enterobacter sp.를 이용하여 서로 다른 기질 및 이의 농도에 따른 발효 특성을 조사하였다. 본 균주는 단당 및 단당의 혼합 탄소원인 경우보다는 lactose에서의 균체 생육 및 다당 생산량이 매우 높아 lactose를 효율적으로 이용하는 특징을 보였다. 공급된 lactose는 20% 정도가 galactose로 발효액에 축적되어 서서히 감소하였고, glucose는 소량이 존재하였으나, 곧 고갈되었다. 한편, lactose 농도를 증가시킨 결과, 효소 활성도의 증가 폭은 약 350～450 unit를 나타내었다. 즉, lactose의 분해 효소 활성도는 다당 생성 경향과 잘 일치하여 β-galactosidase에 의해 lactose가 구성당인 glucose와 galactose로 분해되는 과정에서 다당이 생성되는 것으로 추론되었다.
또 lactose 배지에 첨가한 glucose와 galactose는 각각 효소 생성의 repressor와 inducer로써 작용하는 것으로 판단하였다.
한편, 탄소원 농도를 증가한 결과, 비증식속도 (0.133～0.151hr-1)에는 거의 영향을 미치지 않았고, 균체량의 차이를 나타내었으며, 고농도의 탄소원을 사용할 경우는 배지내의 잔존당량이 높아져 수율이 감소하였으므로, 다당 생산의 최적 lactose 농도는 30～70 g/L인 것으로 판단하였다. 반면, 탄소원의 농도를 각각 30 및 70 g/L로 고정시킨 후, 질소원의 농도를 달리하였을 때는 질소원 농도의 증가로 균체량보다는 비증식속도가 0.059～0.225 hr-1 및 0.141～0.237 hr-1로 크게 증가하므로 질소원이 증식 속도의 제한 기질로 작용하는 것으로 판단하였다.