Super life--how and why 'cell selection' leads to the fastest-growing eukaryote.

What is the highest possible replication rate for living organisms? The cellular growth rate is controlled by a variety of processes. Therefore, it is unclear which metabolic process or group of processes should be activated to increase growth rate. An organism that is already growing fast may already have optimized through evolution all processes that could be optimized readily, but may be confronted with a more generic limitation. Here we introduce a method called 'cell selection' to select for highest growth rate, and show how such a cellular site of 'growth control' was identified. By applying pH-auxostat cultivation to the already fast-growing yeast Kluyveromyces marxianus for a sufficiently long time, we selected a strain with a 30% increased growth rate; its cell-cycle time decreased to 52 min, much below that reported to date for any eukaryote. The increase in growth rate was accompanied by a 40% increase in cell surface at a fairly constant cell volume. We show how the increase in growth rate can be explained by a dominant (80%) limitation of growth by the group of membrane processes (a 0.7% increase of specific growth rate to a 1% increase in membrane surface area). Simultaneous activation of membrane processes may be what is required to accelerate growth of the fastest-growing form of eukaryotic life to growth rates that are even faster, and may be of potential interest for single-cell protein production in industrial 'White' biotechnology processes.

Oxygen protection of nitrogen fixation in free-living Azorhizobium caulinodans: the role of cytochrome aa3.

The growth properties of Azorhizobium caulinodans wild-type and a cytochrome aa3 mutant strain, both growing with N2 as N source at fixed dissolved partial oxygen pressures in the range 0.5--4.0 kPa, were studied by making use of continuous cultures (chemostats and pH-auxostats) and transient cultures. In succinate-limited chemostats, the wild-type exhibited a higher growth yield than the aa3 mutant at every dissolved oxygen tension tested, indicating activity of cytochrome aa3 in this entire oxygen regime. The growth yield of both the wild-type and the aa3 mutant declined when the dissolved oxygen tension was raised. In contrast, for growth on ammonia at the same dilution rate, the wild-type showed an increase in growth yield with increasing dissolved oxygen tension, whereas the growth yield of the aa3 mutant remained constant. The transient changes in growth properties observed in chemostat cultures after pulsing with succinate pointed to a negative effect of oxygen on the maximum specific growth rate. This was studied further in steady-state pH-auxostat cultures. The specific growth rate of both strains decreased with increasing dissolved oxygen tension. The less steep decline in growth rate of the wild-type compared to the aa3 mutant confirmed that cytochrome aa3 is active in the wild-type. Again, the growth yield of both strains decreased with the dissolved oxygen tension, but in contrast to the results obtained with chemostats, no difference in growth yield was observed between wild-type and mutant at any oxygen tension. In either type of continuous culture a decrease in the overall P/O ratio with increasing dissolved oxygen tension is improbable for the wild-type, and even more so for the aa3 mutant. Therefore, the adverse effects of oxygen on the growth of A. caulinodans are not readily explained by respiratory protection; alternatively, it is proposed that the catalytic oxidation of nitrogen-fixation-specific redox enzymes by oxygen (auto-protection) enables the bacterium to deal with intracellular oxygen at the expense of reducing equivalents and free energy. To compensate for the loss of free energy, respiration increases and an active cytochrome aa3 contributes to this by keeping the P/O ratio high.

Expression of the mau gene cluster of Paracoccus denitrificans is controlled by MauR and a second transcription regulator.

The mau gene cluster of Paracoccus denitrificans constitutes 11 genes (10 are located in the transcriptional order mauFBEDACJGMN; the 11th, mauR, is located upstream and divergently transcribed from these genes) that encode a functional methylamine-oxidizing electron transport branch. The mauR gene encodes a LysR-type transcriptional activator essential for induction of the mau operon. In this study, the characteristics of that process were established. By using lacZ transcriptional fusions integrated into the genome of P. denitrificans, it was found that the expression of the mauR gene during growth on methylamine and/or succinate was not autoregulated, but proceeded at a low and constant level. The mauF promoter activity was shown to be controlled by MauR and a second transcriptional regulator. This activity was very high during growth on methylamine, low on succinate plus methylamine, and absent on succinate alone. MauR was overexpressed in Escherichia coli by using a T7 RNA polymerase expression system. Gel shift assays indicated that MauR binds to a 403 bp DNA fragment spanning the mauR-mauF promoter region. It is concluded from these results that the expression of the structural mau genes is dependent on MauR and its inducer, methylamine, as well as on another transcription factor. Both activators are required for high-level transcription from the mauF promoter. It is hypothesized that the two activators act synergistically to activate transcription: the effects of the two activators are not additive and either one alone activates the mauF promoter rather weakly.