Selenomonas ruminantium HD4 and Bacteroides ruminicola B(1)4 were grown in continuous culture with glucose as the energy source, and heat production was measured continuously with a microcalorimeter. Because the bacteria were grown under steady-state conditions, it was possible to calculate complete energy balances for substrate utilization and product formation (cells, fermentation acids, and heat). As the dilution rate increased from 0.04 to 0.60 per h, the heat of fermentation declined from 19 to 2% and from 34 to 8% for S. ruminantium and B. ruminicola, respectively. At slow dilution rates the specific rate of heat production remained relatively constant (135 mW/g [dry weight] or 190 mW/g of protein for S. ruminantium and 247 mW/g [dry weight] or 467 mW/g of protein for B. ruminicola). Since the heat due to growth-related functions was small compared to maintenance expenditures, total heat production provided a reasonable estimate of maintenance under glucose-limiting conditions. As the dilution rate was increased, glucose eventually accumulated in the chemostat vessel and the specific rates of heat production increased more than twofold. Pulses of glucose added to glucose-limited cultures (0.167 per h) caused an immediate doubling of heat production and little increase in cell protein. These experiments indicate that bacterial maintenance energy is not necessarily a constant and that energy source accumulation was associated with an increase in heat production.
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机译:以葡萄糖为能源,在连续培养条件下培养反刍假单胞菌HD4和小白杆菌B(1)4,并用微量热量计连续测量热量的产生。由于细菌在稳态条件下生长,因此有可能计算出用于底物利用和产物形成(细胞,发酵酸和热量)的完整能量平衡。随着稀释率从0.04每小时增加到0.60每小时,反刍葡萄球菌和反刍芽孢杆菌的发酵热分别从19%降低到2%和从34%降低到8%。在较低的稀释速率下,比产热速率保持相对恒定(对于反刍动物,为135 mW / g [干重]或190 mW / g蛋白质,对于247 MW / g [干重]或467 mW / g蛋白质)。 B. ruminicola)。由于与生长相关的功能所产生的热量与维护支出相比很小,因此总热量产生可以合理地估算葡萄糖限制条件下的维护成本。随着稀释率的增加,葡萄糖最终会积聚在化学恒温器的容器中,并且比热的产生率增加两倍以上。添加到葡萄糖受限培养物中的葡萄糖脉冲(每小时0.167)导致热量产生立即加倍并且细胞蛋白质几乎没有增加。这些实验表明细菌维持能量不一定是恒定的,并且能量积累与热量产生的增加有关。
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