吐温80培养基中分枝杆菌属细菌的生长及胆固醇氧化

Growth and cholesterol oxidation by Mycobacterium species in Tween 80 medium.

作者信息

Smith M, Zahnley J, Pfeifer D, Goff D

机构信息

Western Regional Research Center, U.S. Department of Agriculture, Albany, California 94710.

出版信息

Appl Environ Microbiol. 1993 May;59(5):1425-9. doi: 10.1128/aem.59.5.1425-1429.1993.

DOI:10.1128/aem.59.5.1425-1429.1993

PMID:8517738

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC182099/

Abstract

Mycobacterium strain DP was isolated from marine coastal sediment and tested for its ability to oxidize cholesterol in Tween 80-cholesterol (2.59 mM) medium. Strain DP degraded cholesterol to 4-cholesten-3-one (cholestenone), 4-androsten-3,17-dione (AD), 1,4-androstadien-3,17-dione (ADD), testosterone, and 1-dehydrotestosterone (DHT). Cholesterol disappeared in about 4 days. Cholestenone, AD, testosterone, and DHT accumulations were transient with peak concentrations of 300, 600, 30 to 40, and 21 microM. ADD production peaked after 6 days with a concentration of 1,100 microM. Peak ADD concentrations and production rates compared well with those reported for strain NRRL B3683 on cyclodextrin medium. Tween 80 medium was superior to finely dispersed cholesterol particles for both strains. In comparison, NRRL B3683 (patented for its ability to accumulate AD and ADD) on Tween 80 medium transiently accumulated more AD (approximately 1,000 microM) than did strain DP, but ADD accumulations (200 microM) were significantly lower than those for strain DP. Strain DP could be adapted to grow on ADD, which was initially inhibitory at 3.25 mM. ADD-adapted strain DP cultures produced approximately four times as much DHT from ADD than unadapted cultures did from cholesterol, showing that additional manipulation might enhance testosterone production. We believe that ADD toxicity might account for the low ADD accumulations by NRRL B3683 in Tween 80 medium.

摘要

分枝杆菌菌株DP是从海洋海岸沉积物中分离出来的，并在吐温80 - 胆固醇（2.59 mM）培养基中测试其氧化胆固醇的能力。菌株DP将胆固醇降解为4 - 胆甾烯 - 3 - 酮（胆甾烯酮）、4 - 雄甾烯 - 3,17 - 二酮（AD）、1,4 - 雄甾二烯 - 3,17 - 二酮（ADD）、睾酮和1 - 脱氢睾酮（DHT）。胆固醇在约4天内消失。胆甾烯酮、AD、睾酮和DHT的积累是短暂的，峰值浓度分别为300、600、30至40和21 microM。ADD的产生在6天后达到峰值，浓度为1100 microM。ADD的峰值浓度和产生速率与在环糊精培养基上报道的NRRL B3683菌株相当。对于这两种菌株，吐温80培养基优于精细分散的胆固醇颗粒。相比之下，在吐温80培养基上，NRRL B3683（因其积累AD和ADD的能力而获得专利）短暂积累的AD（约1000 microM）比菌株DP多，但ADD的积累（200 microM）明显低于菌株DP。菌株DP可以适应在ADD上生长，ADD最初在3.25 mM时具有抑制作用。适应ADD的菌株DP培养物从ADD产生的DHT大约是未适应培养物从胆固醇产生的DHT的四倍，这表明进一步的操作可能会提高睾酮的产量。我们认为ADD的毒性可能是NRRL B3683在吐温80培养基中ADD积累量低的原因。

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