Add to ORKGIntroducing synthetic constructs into bacteria often carries a burden that leads to reduced fitness and selective pressure for organisms to mutate their constructs and hence to a reduced functional lifetime. Understanding burden requires suitable methods for accurate measurement and quantification. We develop a dynamic growth model from physiologically relevant first-principles that allows parameters relevant to burden to be extracted from standard growth curves. We test several possibilities for the response of a bacterium to a new environment in terms of resource allocation. We find that burden manifests in the time taken to respond to new conditions as well as the rate of growth in exponential phase. Furthermore, we see that the presence...
Bacteria in changing environments must constantly adapt to grow and survive. The adaptive response t...
Growth and reproduction are essential requirements of living systems. Previous studies of bacterial ...
<p><i>A:</i> Predicted quasi-linear relation between the maximal growth rate and the corresponding ...
Introducing synthetic constructs into bacteria often carries a burden that leads to reduced fitness ...
Bacterial growth follows simple laws in constant conditions. However, bacteria in nature often face ...
International audienceGaining a better comprehension of the growth of microorganisms is a major scie...
The growth rate should be a highly optimized process in bacteria since the battle for the conquest o...
This is essentially an extension of the work presented in an earlier communication (Singh, 1976) des...
Synthetic biology uses modeling to facilitate the design of new genetic constructions. In particular...
The ability of microbes to colonize the most improbable places can be partly attributed to the effic...
A grand challenge of systems biology is to predict the kinetic responses of living systems to pertur...
Predicting resource allocation between cell processes is the primary step towards decoding the evolu...
To respond to fluctuating conditions, microbes typically need to synthesize novel proteins. As this ...
Cells contain a finite set of resources that must be distributed across many processes to ensure sur...
Background The rising consensus that the cell can dynamically allocate its resources provides an int...
Bacteria in changing environments must constantly adapt to grow and survive. The adaptive response t...
Growth and reproduction are essential requirements of living systems. Previous studies of bacterial ...
<p><i>A:</i> Predicted quasi-linear relation between the maximal growth rate and the corresponding ...
Introducing synthetic constructs into bacteria often carries a burden that leads to reduced fitness ...
Bacterial growth follows simple laws in constant conditions. However, bacteria in nature often face ...
International audienceGaining a better comprehension of the growth of microorganisms is a major scie...
The growth rate should be a highly optimized process in bacteria since the battle for the conquest o...
This is essentially an extension of the work presented in an earlier communication (Singh, 1976) des...
Synthetic biology uses modeling to facilitate the design of new genetic constructions. In particular...
The ability of microbes to colonize the most improbable places can be partly attributed to the effic...
A grand challenge of systems biology is to predict the kinetic responses of living systems to pertur...
Predicting resource allocation between cell processes is the primary step towards decoding the evolu...
To respond to fluctuating conditions, microbes typically need to synthesize novel proteins. As this ...
Cells contain a finite set of resources that must be distributed across many processes to ensure sur...
Background The rising consensus that the cell can dynamically allocate its resources provides an int...
Bacteria in changing environments must constantly adapt to grow and survive. The adaptive response t...
Growth and reproduction are essential requirements of living systems. Previous studies of bacterial ...
<p><i>A:</i> Predicted quasi-linear relation between the maximal growth rate and the corresponding ...