Evolutionary Biology

Metabolism: Evolution retraces its steps to advance

Dec 15, 2015

Open access
Copyright information

Download
Cite
CommentOpen annotations (there are currently 0 annotations on this page).
Share

Daniel J Kliebenstein

University of California,Davis, United States

Selection can increase the fitness of a species in a stable environment by acting on random mutations. The same process can also create new traits if there is a change in the environment. Metabolism may evolve largely via the creation of new traits that either allow the organism to make use of new energy sources or provide new defense mechanisms in a complex environment (Blount et al. 2012; Prasad et al. 2012). However, we do not fully understand how new metabolic traits evolve or how they are integrated into existing metabolic networks.

Studying the creation of new traits is greatly complicated because evolution usually occurs over relatively long timescales. However, the Lenski long-term evolution experiment was designed to alleviate this problem and has been running at Michigan State University since 1988 (Fox and Lenski, 2015). Now, in eLife, Jeffrey Barrick and colleagues – including Erik Quandt as first author – make use of this resource to describe the molecular evolution of a new metabolic trait in E. coli (Quandt et al. 2015).

The long-term evolution experiment started with twelve identical populations of E. coli. These bacteria were forced to grow on culture medium that contained an excess of citrate, but very little glucose. Thus, for tens of thousands of generations of E. coli, the bacteria have been selected to evolve to use citrate as their main carbon source. This is something that E. coli would not normally do if they had access to oxygen. However, one of the populations did indeed evolve this exact ability (Blount et al. 2008; 2012). Sequencing the genome of this unique population throughout the long-term experiment identified the molecular changes that had generated this new trait. The new trait required two separate mutations within the gene that encodes an enzyme called citrate synthase (Quandt et al. 2015).

Barrick and colleagues – who are based at the University of Texas at Austin and Michigan State – now show that these two mutations have opposing effects (Quandt et al. 2015). The first mutation, called gltA1, abolished feedback inhibition in the enzyme and allowed the bacteria to use citrate, albeit weakly. This initial mutation was then followed by evolutionary shifts in genes that transcriptionally regulate primary metabolism (Leiby and Marx, 2014). Critically, this new transcriptional environment made the initial gltA1 mutation detrimental to fitness which, in turn, led to the rapid selection of variants of the citrate synthase gene that made the enzyme less active. Thus, while two opposing mutations within a single gene were required, they had to occur in a specific order and this order caused the mutations to be positive in both instances.

These new results show that the apparently unwavering march of evolution towards a new trait hides a meandering process underneath. In particular, they show that mutations that were at one time beneficial can consequently become a drag on fitness, and that mutations within existing genes can allow the creation of a new metabolic trait. This is in contrast to the standard view that the creation of new genes, often by gene duplication, is essential to the evolution of new metabolic traits (Chae et al. 2014; Wisecaver et al. 2014).

The use of the long-term evolution experiment has illuminated the complex mechanisms that allow adaptation to a consistent selective pressure in a single direction. However, it is possible that fluctuating and unpredictable stresses in the environment are more important drivers of evolution in nature (Kerwin et al. 2015), so there is a need for long-term experiments that include such stresses. The work of Quandt et al. represents, I hope, only the beginning of our ability to empirically study evolution in action.

References

(2012) Genomic analysis of a key innovation in an experimental escherichia coli population
Nature 489:513–518.
https://doi.org/10.1038/nature11514
- Google Scholar
(2008) Historical contingency and the evolution of a key innovation in an experimental population of escherichia coli
Proceedings of the National Academy of Sciences 105:7899–7906.
https://doi.org/10.1073/pnas.0803151105
- Google Scholar
1. Chae L
2. Kim T
3. Nilo-Poyanco R
4. Rhee SY
(2014) Genomic signatures of specialized metabolism in plants
Science 344:510–513.
https://doi.org/10.1126/science.1252076
- Google Scholar
1. Fox JW
2. Lenski RE
(2015) From here to eternity—the theory and practice of a really long experiment
PLOS Biology 13:e1002185.
https://doi.org/10.1371/journal.pbio.1002185
- Google Scholar
1. Kerwin R
2. Feusier J
3. Corwin J
4. Rubin M
5. Lin C
6. Muok A
7. Larson B
8. Li B
9. Joseph B
10. Francisco M
11. Copeland D
12. Weinig C
13. Kliebenstein DJ
(2015) Natural genetic variation in arabidopsis thaliana defense metabolism genes modulates field fitness
eLife 4:e05604.
https://doi.org/10.7554/eLife.05604
- Google Scholar
1. Leiby N
2. Marx CJ
3. Moran NA
(2014) Metabolic erosion primarily through mutation accumulation, and not tradeoffs, drives limited evolution of substrate specificity in escherichia coli
PLOS Biology 12:e1001789.
https://doi.org/10.1371/journal.pbio.1001789
- Google Scholar
(2012) A gain-of-function polymorphism controlling complex traits and fitness in nature
Science 337:1081–1084.
https://doi.org/10.1126/science.1221636
- Google Scholar
(2015) Fine-tuning citrate synthase flux potentiates and refines metabolic innovation in the lenski evolution experiment
eLife 4:e09696.
https://doi.org/10.7554/eLife.09696
- Google Scholar
(2014) The evolution of fungal metabolic pathways
PLOS Genetics 10:e1004816.
https://doi.org/10.1371/journal.pgen.1004816
- Google Scholar

Article and author information

Author details

Daniel J Kliebenstein, Reviewing editor

Department of Plant Sciences, University of California,Davis, Davis, United States

For correspondence
kliebenstein@ucdavis.edu

Competing interests
The author declares that no competing interests exist.

Publication history

Version of Record published: December 15, 2015 (version 1)

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.