乙酸和氢气对嗜热共培养物中丁酸盐代谢的产物抑制作用。
Product inhibition of butyrate metabolism by acetate and hydrogen in a thermophilic coculture.
机构信息
Institute of Biotechnology, Block 223, The Technical University of Denmark, 2800 Lyngby, Denmark, and Department of General Microbiology, University of Copenhagen, Sølvgade 83 H, 1307 Copenhagen K, Denmark.
出版信息
Appl Environ Microbiol. 1988 Oct;54(10):2393-7. doi: 10.1128/aem.54.10.2393-2397.1988.
Abstract
Studies on product inhibition of a thermophilic butyrate-degrading bacterium in syntrophic association with Methanobacterium thermoautotrophicum showed that a gas phase containing more than 2 x 10 atm (2.03 kPa) of hydrogen prevented growth and butyrate consumption, while a lower hydrogen partial pressure of 1 x 10 to 2 x 10 atm (0.1 to 2.03 kPa) gradually inhibited the butyrate consumption of the coculture. No inhibition of butyrate consumption was found on the addition of 0.75 x 10 atm (76 Pa) of hydrogen to the gas phase. A slight inhibition of butyrate consumption by the coculture occurred at an acetate concentration of 16.4 mM. Inhibition gradually increased with increasing acetate concentration up to 81.4 mM, when complete inhibition of butyrate consumption occurred. When the culture contained an acetate-utilizing methanogen in addition to M. thermoautotrophicum, the inhibition of the triculture by acetate was gradually reversed as the acetate concentration was lowered by the aceticlastic methanogen. The results show that optimal growth conditions for the thermophilic butyrate-degrading bacterium depend on both hydrogen and acetate removal.
摘要
与产甲烷菌嗜热甲烷杆菌协同作用的嗜热丁酸降解菌的产物抑制研究表明,气相中含有超过 2 x 10 大气压(2.03 kPa)的氢气会阻止生长和丁酸消耗,而较低的氢气分压为 1 x 10 至 2 x 10 大气压(0.1 至 2.03 kPa)逐渐抑制共培养物的丁酸消耗。向气相中添加 0.75 x 10 大气压(76 Pa)的氢气不会抑制丁酸的消耗。在 16.4 mM 的醋酸盐浓度下,共培养物对丁酸的消耗有轻微抑制。随着醋酸盐浓度的增加,抑制作用逐渐增加,当丁酸消耗完全抑制时,抑制作用达到 81.4 mM。当培养物除了嗜热甲烷杆菌外还含有利用醋酸盐的产甲烷菌时,随着醋酸裂解产甲烷菌降低醋酸盐浓度,三培养物受醋酸盐的抑制作用逐渐逆转。结果表明,嗜热丁酸降解菌的最佳生长条件取决于氢气和醋酸盐的去除。
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