Stability-activity tradeoffs constrain the adaptive evolution of RubisCO

Studer, Romain A.; Christin, Pascal‐Antoine; Williams, Mark A.; Orengo, Christine A.

doi:10.1073/pnas.1310811111

Cited by 144 publications

(151 citation statements)

References 40 publications

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“…Studies of Rubisco evolution focused on the emergence of CO 2 management in recently derived C4 photosynthetic plants (Christin et al., 2008), the evolutionary pathways of thermostable Rubisco homologs (Miller, Mcguirl, & Carvey, 2013), and the underlying trade‐offs between destabilizing mutations and environmental tolerance in Rubisco functionality (Studer, Christin, Williams, & Orengo, 2014). Recently, Shih et al.…”

Section: Discussionmentioning

confidence: 99%

Constraining the timing of the Great Oxidation Event within the Rubisco phylogenetic tree

et al. 2017

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Ribulose 1,5‐bisphosphate (RuBP) carboxylase/oxygenase (RuBisCO, or Rubisco) catalyzes a key reaction by which inorganic carbon is converted into organic carbon in the metabolism of many aerobic and anaerobic organisms. Across the broader Rubisco protein family, homologs exhibit diverse biochemical characteristics and metabolic functions, but the evolutionary origins of this diversity are unclear. Evidence of the timing of Rubisco family emergence and diversification of its different forms has been obscured by a meager paleontological record of early Earth biota, their subcellular physiology and metabolic components. Here, we use computational models to reconstruct a Rubisco family phylogenetic tree, ancestral amino acid sequences at branching points on the tree, and protein structures for several key ancestors. Analysis of historic substitutions with respect to their structural locations shows that there were distinct periods of amino acid substitution enrichment above background levels near and within its oxygen‐sensitive active site and subunit interfaces over the divergence between Form III (associated with anoxia) and Form I (associated with oxia) groups in its evolutionary history. One possible interpretation is that these periods of substitutional enrichment are coincident with oxidative stress exerted by the rise of oxygenic photosynthesis in the Precambrian era. Our interpretation implies that the periods of Rubisco substitutional enrichment inferred near the transition from anaerobic Form III to aerobic Form I ancestral sequences predate the acquisition of Rubisco by fully derived cyanobacterial (i.e., dual photosystem‐bearing, oxygen‐evolving) clades. The partitioning of extant lineages at high clade levels within our Rubisco phylogeny indicates that horizontal transfer of Rubisco is a relatively infrequent event. Therefore, it is possible that the mutational enrichment periods between the Form III and Form I common ancestral sequences correspond to the adaptation of key oxygen‐sensitive components of Rubisco prior to, or coincident with, the Great Oxidation Event.

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Section: Discussionmentioning

confidence: 99%

Constraining the timing of the Great Oxidation Event within the Rubisco phylogenetic tree

et al. 2017

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“…On the other hand, thermodynamic stability can be compromised in evolution to ensure certain arrangements of catalytic and binding sites, which might not be energetically optimal (36, 42). In tumorigenesis, protein stability or binding may be reduced (or in some cases increased) due to cancer mutations.…”

Section: Discussionmentioning

confidence: 99%

Balancing Protein Stability and Activity in Cancer: A New Approach for Identifying Driver Mutations Affecting CBL Ubiquitin Ligase Activation

Kales

et al. 2016

Cancer Research

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Oncogenic mutations in the monomeric Casitas B-lineage lymphoma (Cbl) gene have been found in many tumors, but their significance remains largely unknown. Several human c-Cbl (CBL) structures have recently been solved depicting the protein at different stages of its activation cycle and thus provide mechanistic insight underlying how stability-activity tradeoffs in cancer-related proteins may influence disease onset and progression. In this study, we computationally modeled the effects of missense cancer mutations on structures representing four stages of the CBL activation cycle to identify driver mutations that affect CBL stability, binding, and activity. We found that recurrent, homozygous, and leukemia-specific mutations had greater destabilizing effects on CBL states than did random non-cancer mutations. We further tested the ability of these computational models assessing the changes in CBL stability and its binding to ubiquitin conjugating enzyme E2, by performing blind CBL-mediated EGFR ubiquitination assays in cells. Experimental CBL ubiquitin ligase activity was in agreement with the predicted changes in CBL stability and, to a lesser extent, with CBL-E2 binding affinity. Two-thirds of all experimentally tested mutations affected the ubiquitin ligase activity by either destabilizing CBL or disrupting CBL-E2 binding, whereas about one-third of tested mutations were found to be neutral. Collectively, our findings demonstrate that computational methods incorporating multiple protein conformations and stability and binding affinity evaluations can successfully predict the functional consequences of cancer mutations on protein activity, and provide a proof of concept for mutations in CBL.

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“…However, given that approximately 46% of the estimated 10,000 grass species use C4 photosynthesis [28], there must be many other C4 grasses which would be suitable targets for improvement for forage, despite their generally low nutritive value. C4 photosynthesis has evolved at least 24 times in the grasses [29], and there are significant efforts currently to engineer C4 rice (Oryza sativa L.) with the goal of significant increases in grain yield [30]. C4 plants significantly increase the CO2 concentration around Rubisco, which in principle would allow the use of more efficient forms of Rubisco, such as those originating in cyanobacteria [31].…”

Section: Carbon Fixationmentioning

confidence: 99%

Carbon Assimilation, Biomass Partitioning and Productivity in Grasses

Irving

2015

Agriculture

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Plant growth correlates with net carbon gain on a whole plant basis. Over the last several decades, the driving factors shaping plant morphology and performance have become increasingly clear. This review seeks to explore the importance of these factors for grass performance. Briefly, these fall into factors influencing photosynthetic rates directly, competition between plants in a canopy, and nutrient status and availability.

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Stability-activity tradeoffs constrain the adaptive evolution of RubisCO

Cited by 144 publications

References 40 publications

Constraining the timing of the Great Oxidation Event within the Rubisco phylogenetic tree

Constraining the timing of the Great Oxidation Event within the Rubisco phylogenetic tree

Balancing Protein Stability and Activity in Cancer: A New Approach for Identifying Driver Mutations Affecting CBL Ubiquitin Ligase Activation

Carbon Assimilation, Biomass Partitioning and Productivity in Grasses

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