AI Article Synopsis
- The study examines the relationship between transcription regulation (promoters) and gene products (proteins), focusing on glutamate dehydrogenase, which plays a key role in carbon and nitrogen metabolism.
- The research identifies two versions (paralogues) of the enzyme: GudB, which is constantly active, and RocG, which is tightly controlled; while they perform similarly, swapping their promoters and enzymes leads to significant fitness drawbacks.
- Findings highlight the importance of promoter-enzyme coevolution, emphasizing that misalignment in their regulation can either cause excessive enzyme activity or insufficient function, affecting the organism's growth under varying conditions.
Article Abstract
The linkage between regulatory elements of transcription, such as promoters, and their protein products is central to gene function. Promoter-protein coevolution is therefore expected, but rarely observed, and the manner by which these two regulatory levels are linked remains largely unknown. We study glutamate dehydrogenase-a hub of carbon and nitrogen metabolism. In , two paralogues exist: GudB is constitutively transcribed whereas RocG is tightly regulated. In their active, oligomeric states, both enzymes show similar enzymatic rates. However, swaps of enzymes and promoters cause severe fitness losses, thus indicating promoter-enzyme coevolution. Characterization of the proteins shows that, compared to RocG, GudB's enzymatic activity is highly dependent on glutamate and pH Promoter-enzyme swaps therefore result in excessive glutamate degradation when expressing a constitutive enzyme under a constitutive promoter, or insufficient activity when both the enzyme and its promoter are tightly regulated. Coevolution of transcriptional and enzymatic regulation therefore underlies paralogue-specific spatio-temporal control, especially under diverse growth conditions.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5494520 | PMC |
| http://dx.doi.org/10.15252/embr.201743990 | DOI Listing |
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