Bioenergetic consequences of lactose starvation for continuously cultured Streptococcus cremoris.

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J Bacteriol. 1987 April; 169(4): 1460-1468

Bioenergetic consequences of lactose starvation for continuously cultured Streptococcus cremoris.

B Poolman, E J Smid, H Veldkamp and W N Konings

ABSTRACT

Streptococcus cremoris cells that had been grown in a chemostatwere starved for lactose. The viability of the culture remainedessentially constant in the first hours of starvation and subsequentlydeclined logarithmically. The viability pattern during starvationvaried with the previously imposed growth rates. The death rateswere 0.029, 0.076, and 0.298 h-1 for cells grown at dilutionrates of 0.07, 0.11 and 0.38 h-1, respectively. The proton motiveforce and the pools of energy-rich phosphorylated intermediatesin cells grown at a dilution rate of 0.10 h-1 fell to zero within2 h of starvation. The culture, however, remained fully viablefor at least 20 h, indicating that these energy-rich intermediatesare not crucial for survival during long-term lactose starvation.Upon starvation, the intracellular pools of several amino acidsdepleted with the proton motive force, while large concentrationgradients of the amino acids alanine, glycine, aspartate, andglutamate were retained for several hours. A quantitative analysisof the amino acids released indicated that nonspecific proteindegradation was not a major cause of the loss in viability.The response of the energy metabolism of starved S. cremoriscells upon refeeding with lactose was monitored. Upon lactosestarvation, the glycolytic activity and the rate of proton motiveforce generation decreased rapidly but the steady-state levelof the proton motive force decreased significantly only afterseveral hours. The decreasing steady-state level of the protonmotive force and consequently the capacity to accumulate aminoacids after the addition of lactose correlated well with theloss of viability. The response of the energy metabolism ofstarved S. cremoris cells upon refeeding with lactose was monitored.Upon lactose starvation, the glycolytic activity and the rateof proton motive force generation decreased rapidly but thesteady-state level of the proton motive force decreased significantlyonly after several hours. The decreasing steady-state levelof the proton motive force and consequently the capacity toaccumulate amino acids after the addition of lactose correlatedwell with the loss of viability. It is concluded that a regulatoryloss of glycolytic capacity has pivotal role in the survivalof S. cremoris under the conditions used.

J Bacteriol. 1987 April; 169(4): 1460-1468

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