Plasticity of growth laws tunes resource allocation strategies in bacteria

Author:

Mukherjee AvikORCID,Chang Yu-Fang,Huang YanqingORCID,Benites Nina Catherine,Ammar LeanderORCID,Ealy Jade,Polk Mark,Basan MarkusORCID

Abstract

Bacteria like E. coli grow at vastly different rates on different substrates, however, the precise reason for this variability is poorly understood. Different growth rates have been attributed to ‘nutrient quality’, a key parameter in bacterial growth laws. However, it remains unclear to what extent nutrient quality is rooted in fundamental biochemical constraints like the energy content of nutrients, the protein cost required for their uptake and catabolism, or the capacity of the plasma membrane for nutrient transporters. Here, we show that while nutrient quality is indeed reflected in protein investment in substrate-specific transporters and enzymes, this is not a fundamental limitation on growth rate, at least for certain ‘poor’ substrates. We show that it is possible to turn mannose, one of the ‘poorest’ substrates of E. coli, into one of the ‘best’ substrates by reengineering chromosomal promoters of the mannose transporter and metabolic enzymes required for mannose degradation. This result falls in line with previous observations of more subtle growth rate improvement for many other carbon sources. However, we show that this faster growth rate comes at the cost of diverse cellular capabilities, reflected in longer lag phases, worse starvation survival and lower motility. We show that addition of cAMP to the medium can rescue these phenotypes but imposes a corresponding growth cost. Based on these data, we propose that nutrient quality is largely a self-determined, plastic property that can be modulated by the fraction of proteomic resources devoted to a specific substrate in the much larger proteome sector of catabolically activated genes. Rather than a fundamental biochemical limitation, nutrient quality reflects resource allocation decisions that are shaped by evolution in specific ecological niches and can be quickly adapted if necessary.

Funder

National Institute of General Medical Sciences

Giovanni Armenise-Harvard Foundation

National Science Foundation Graduate Research Fellowship Program

Systems, Synthetic, and Quantitative Biology Training grant

Publisher

Public Library of Science (PLoS)

Reference27 articles.

1. Coordination of bacterial proteome with metabolism by cyclic AMP signalling;C You;Nature,2013

2. Different levels of catabolite repression optimize growth in stable and variable environments;AM New;PLoS Biol,2014

3. Interdependence of cell growth and gene expression: Origins and consequences;M Scott;Science (1979).,2010

4. Bacterial growth laws and their applications;M Scott;Curr Opin Biotechnol,2011

5. Emergence of robust growth laws from optimal regulation of ribosome synthesis;M Scott;Mol Syst Biol,2014

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