Understanding how bacteria adapt so quickly to changes in their external environment with continued high growth rates is one of the major research challenges in molecular microbiology. This is important not least for our understanding of resistance to antibiotics.

A research study from Uppsala University is now presenting a model of how bacteria can rapidly adapt to environmental changes through smart regulation of their gene expression.

The study, published in the journal of the American National Academy of Sciences PNAS (Proceedings of the National Academy of Sciences), presents a theoretical model that determines the ultimate limit for how quickly bacteria can adapt their protein levels to changes in their living environment.

For rapid growth in different environments, bacteria need to adjust their enzyme levels in order to rapidly benefit from the nutrient mix that is currently available in the surrounding.

If the living environment undergoes rapid changes, the bacterium's own production of proteins has to conform to these changes in an effective way.

The growth of bacteria is determined not only by the composition of their surroundings but also by sudden changes in the living environment.

This has been known since the middle of the 20th century. High levels of bacteria growth in a stable environment requires a certain kind of physiology, but environmental changes also require rapid adjustments of the bacteria's protein production. The newly developed model indicates the 'minimum' time such adjustments require.

This is an attempt to begin to answer the detailed questions about how bacteria go about adapting so rapidly. The model shows the optimal strategy for the bacterium to genetically adapt its proteome, that is, the composition of its proteins.

The model is now being tested and will constitute an important point of departure for continued research in the field, says Mans Ehrenberg, professor at the Department of Cell and Molecular Biology, Uppsala University, and Scilifelab Uppsala.

Using this model, scientists can predict and test key aspects of the physiology of bacteria. It also ties together the physiology of bacteria with population genetics and growth/evolution and thus represents a systems biology view of bacterial growth and evolution.