A fundamental protein property, thermodynamic stability, revealed solely from large-scale measurements of protein function

Araya, Carlos L.; Fowler, Douglas M.; Chen, Wentao; Muniez, Ike; Kelly, Jeffery W.; Fields, Stanley

doi:10.1073/pnas.1209751109

Cited by 243 publications

(285 citation statements)

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“…We used deep sequencing to count each allele in the input phage population and after each round. We calculated E3 ligase scores by tracking the changes in the relative abundance of each allele during the selection (Araya et al 2012). The scores were normalized such that the wild type had a score of one and the mean score for variants with premature termination codons had a score of zero.…”

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confidence: 99%

Massively Parallel Functional Analysis of BRCA1 RING Domain Variants

et al. 2015

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Interpreting variants of uncertain significance (VUS) is a central challenge in medical genetics. One approach is to experimentally measure the functional consequences of VUS, but to date this approach has been post hoc and low throughput. Here we use massively parallel assays to measure the effects of nearly 2000 missense substitutions in the RING domain of BRCA1 on its E3 ubiquitin ligase activity and its binding to the BARD1 RING domain. From the resulting scores, we generate a model to predict the capacities of full-length BRCA1 variants to support homology-directed DNA repair, the essential role of BRCA1 in tumor suppression, and show that it outperforms widely used biological-effect prediction algorithms. We envision that massively parallel functional assays may facilitate the prospective interpretation of variants observed in clinical sequencing.KEYWORDS deep mutational scanning; BRCA1; variants of uncertain significance; human genetic variation; protein function I N an era of increasingly widespread genetic testing, DNA sequencing identifies many missense substitutions with unknown effects on protein function and disease risk. In the absence of genetic evidence, experimental measurement is the most reliable way to determine the functional impact of a variant of uncertain significance (VUS). However, initiating an experiment for each new variant observed in a gene is often impractical. When experiments are done, they are nearly always performed in a retrospective manner (Bouwman et al. 2013), such that the resulting data are not useful for the patient in whom the VUS was observed.By prospectively measuring, in a high-throughput fashion, the consequences of all possible missense mutations on a gene's function, we can generate a look-up table for interpreting newly observed VUS. Although functional analysis at this scale is made possible by deep mutational scanning (Fowler and Fields 2014), a central challenge is that any single assay may not recapitulate all the activities of a given protein in human disease. To address this challenge, we hypothesized that integrating the results of assays of multiple biochemical functions would strengthen estimates of the effects of mutations on disease risk (strategy outlined in Figure 1A). As a proof-ofconcept, we initiated massively parallel functional analysis of BRCA1, a protein for which there are multiple biochemical functions as well as known pathogenic and benign missense substitutions to benchmark results.BRCA1 has been subject to intense study since its implication in hereditary, early onset breast and ovarian cancer (Miki et al. 1994). All missense substitutions in BRCA1 that are known to be pathogenic occur in either the amino-terminal RING domain or the carboxy-terminal BRCT repeat (http:// brca.iarc.fr/LOVD/home.php?select_db=BRCA1). Although the RING domain represents only 5% of the BRCA1 protein, 58% of the pathogenic missense substitutions occur within this domain. Sixty-two missense substitutions in the RING domain have been observed in patient...

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Massively Parallel Functional Analysis of BRCA1 RING Domain Variants

et al. 2015

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“…We adapted our screening protocol to include a heat challenge and enriched for mutations that increase the enzyme's thermostability. An alternative approach for identifying stabilizing mutations from high-throughput sequence-function data was recently developed that involved scoring a residue's ability to rescue the deleterious effects of other mutations (27). However, the droplet-based screening approach is extremely versatile and could theoretically be used to identify variants with enhanced properties including increased k cat (reduced reaction time), decreased K m (reduced substrate concentration), increased tolerance to biomass pretreatments (increased ionic liquid concentration), and reduced product inhibition (increased glucose concentration).…”

Section: Discussionmentioning

confidence: 99%

Dissecting enzyme function with microfluidic-based deep mutational scanning

Romero

Tran

Abate

2015

Proc. Natl. Acad. Sci. U.S.A.

212

183

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Natural enzymes are incredibly proficient catalysts, but engineering them to have new or improved functions is challenging due to the complexity of how an enzyme's sequence relates to its biochemical properties. Here, we present an ultrahigh-throughput method for mapping enzyme sequence-function relationships that combines droplet microfluidic screening with next-generation DNA sequencing. We apply our method to map the activity of millions of glycosidase sequence variants. Microfluidic-based deep mutational scanning provides a comprehensive and unbiased view of the enzyme function landscape. The mapping displays expected patterns of mutational tolerance and a strong correspondence to sequence variation within the enzyme family, but also reveals previously unreported sites that are crucial for glycosidase function. We modified the screening protocol to include a hightemperature incubation step, and the resulting thermotolerance landscape allowed the discovery of mutations that enhance enzyme thermostability. Droplet microfluidics provides a general platform for enzyme screening that, when combined with DNAsequencing technologies, enables high-throughput mapping of enzyme sequence space.protein engineering | droplet-based microfluidics | high-throughput DNA sequencing E nzymes are powerful biological catalysts capable of remarkably accelerating the rates of chemical transformations (1). The molecular bases of these rate accelerations are often complex, using multiple steps, multiple catalytic mechanisms, and relying on numerous molecular interactions, in addition to those provided by the main catalytic groups. This complexity imposes a significant barrier to understanding how an enzyme's sequence impacts its function and, thus, on our ability to rationally design biocatalysts with new or enhanced functions (2-4).Comprehensive mappings of sequence-function relationships can be used to dissect the molecular basis of protein function in an unbiased manner (5). Growth selections or in vitro binding screens can be combined with next-generation DNA sequencing to generate detailed mappings between a protein's sequence and its biochemical properties, such as binding affinity, enzymatic activity, and stability (6-9). This deep mutational scanning approach has been used to study the structure of the protein fitness landscape, discover new functional sites, improve molecular energy functions, and identify beneficial combinations of mutations for protein engineering. However, these methods rely on functional assays coupled to cell growth or protein binding, severely limiting the types of proteins that can be analyzed. For example, most enzymes of biological or industrial relevance cannot be analyzed using existing methods because they do not catalyze a reaction that can be directly coupled to cell growth. Experimental advances are needed to broaden the applicability of deep mutational scanning to the diverse palette of functions performed by enzymes.In this paper, we present a general method for mapping protein sequence-func...

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“…Based on this logic, mutations that increase thermodynamic stability can be broadly permissive by increasing the tolerance of the protein to many secondary mutations that would result in unfolding in less thermodynamically stable sequence backgrounds (Gong et al 2013). Mutations that increased thermodynamic stability were recently identified from a systematic analysis of a large set of multiple mutations in a WW domain based on their capability to rescue the peptide binding function of secondary mutations that had binding defects in other sequence backgrounds (Araya et al 2012).…”

Section: Structural Interpretations Of Local Mutational Landscapesmentioning

confidence: 99%

“…Pioneering work by Fowler et al (2010) utilized gene synthesis with engineered degeneracy at many consecutive nucleotide positions to generate libraries containing the majority of single-nucleotide substitutions, a fraction of possible double nucleotide substitutions, along with smaller fractions of higher-order nucleotide substitutions. This approach, coined deep mutational scanning, provides outstanding opportunities to investigate the interdependency between mutations in the same gene (Araya et al 2012). A distinct approach (Hietpas et al 2011) Wright (1932) to conceptualize vast possible combinations of different alleles.…”

Section: Quantification Of Local Mutational Landscapes Using Sequencimentioning

confidence: 99%

Viewing Protein Fitness Landscapes Through a Next-Gen Lens

Boucher¹,

Cote²,

Flynn³

et al. 2014

Genetics

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High-throughput sequencing has enabled many powerful approaches in biological research. Here, we review sequencing approaches to measure frequency changes within engineered mutational libraries subject to selection. These analyses can provide direct estimates of biochemical and fitness effects for all individual mutations across entire genes (and likely compact genomes in the near future) in genetically tractable systems such as microbes, viruses, and mammalian cells. The effects of mutations on experimental fitness can be assessed using sequencing to monitor time-dependent changes in mutant frequency during bulk competitions. The impact of mutations on biochemical functions can be determined using reporters or other means of separating variants based on individual activities (e.g., binding affinity for a partner molecule can be interrogated using surface display of libraries of mutant proteins and isolation of bound and unbound populations). The comprehensive investigation of mutant effects on both biochemical function and experimental fitness provide promising new avenues to investigate the connections between biochemistry, cell physiology, and evolution. We summarize recent findings from systematic mutational analyses; describe how they relate to a field rich in both theory and experimentation; and highlight how they may contribute to ongoing and future research into protein structure-function relationships, systems-level descriptions of cell physiology, and population-genetic inferences on the relative contributions of selection and drift.

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A fundamental protein property, thermodynamic stability, revealed solely from large-scale measurements of protein function

Cited by 243 publications

References 37 publications

Massively Parallel Functional Analysis of BRCA1 RING Domain Variants

Massively Parallel Functional Analysis of BRCA1 RING Domain Variants

Dissecting enzyme function with microfluidic-based deep mutational scanning

Viewing Protein Fitness Landscapes Through a Next-Gen Lens

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