Person: Choi, Jeong-Mo
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Choi
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Jeong-Mo
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Choi, Jeong-Mo
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Publication Protein Homeostasis Imposes a Barrier on Functional Integration of Horizontally Transferred Genes in Bacteria(Public Library of Science, 2015) Bershtein, Shimon; Serohijos, Adrian; Bhattacharyya, Sanchari; Manhart, Michael; Choi, Jeong-Mo; Mu, Wanmeng; Zhou, Jingwen; Shakhnovich, EugeneHorizontal gene transfer (HGT) plays a central role in bacterial evolution, yet the molecular and cellular constraints on functional integration of the foreign genes are poorly understood. Here we performed inter-species replacement of the chromosomal folA gene, encoding an essential metabolic enzyme dihydrofolate reductase (DHFR), with orthologs from 35 other mesophilic bacteria. The orthologous inter-species replacements caused a marked drop (in the range 10–90%) in bacterial growth rate despite the fact that most orthologous DHFRs are as stable as E.coli DHFR at 37°C and are more catalytically active than E. coli DHFR. Although phylogenetic distance between E. coli and orthologous DHFRs as well as their individual molecular properties correlate poorly with growth rates, the product of the intracellular DHFR abundance and catalytic activity (kcat/KM), correlates strongly with growth rates, indicating that the drop in DHFR abundance constitutes the major fitness barrier to HGT. Serial propagation of the orthologous strains for ~600 generations dramatically improved growth rates by largely alleviating the fitness barriers. Whole genome sequencing and global proteome quantification revealed that the evolved strains with the largest fitness improvements have accumulated mutations that inactivated the ATP-dependent Lon protease, causing an increase in the intracellular DHFR abundance. In one case DHFR abundance increased further due to mutations accumulated in folA promoter, but only after the lon inactivating mutations were fixed in the population. Thus, by apparently distinguishing between self and non-self proteins, protein homeostasis imposes an immediate and global barrier to the functional integration of foreign genes by decreasing the intracellular abundance of their products. Once this barrier is alleviated, more fine-tuned evolution occurs to adjust the function/expression of the transferred proteins to the constraints imposed by the intracellular environment of the host organism.Publication Influenza A H1N1 Pandemic Strain Evolution – Divergence and the Potential for Antigenic Drift Variants(Public Library of Science, 2014) Klein, Eili Y.; Serohijos, Adrian; Choi, Jeong-Mo; Shakhnovich, Eugene; Pekosz, AndrewThe emergence of a novel A(H1N1) strain in 2009 was the first influenza pandemic of the genomic age, and unprecedented surveillance of the virus provides the opportunity to better understand the evolution of influenza. We examined changes in the nucleotide coding regions and the amino acid sequences of the hemagglutinin (HA), neuraminidase (NA), and nucleoprotein (NP) segments of the A(H1N1)pdm09 strain using publicly available data. We calculated the nucleotide and amino acid hamming distance from the vaccine strain A/California/07/2009 for each sequence. We also estimated Pepitope–a measure of antigenic diversity based on changes in the epitope regions–for each isolate. Finally, we compared our results to A(H3N2) strains collected over the same period. Our analysis found that the mean hamming distance for the HA protein of the A(H1N1)pdm09 strain increased from 3.6 (standard deviation [SD]: 1.3) in 2009 to 11.7 (SD: 1.0) in 2013, while the mean hamming distance in the coding region increased from 7.4 (SD: 2.2) in 2009 to 28.3 (SD: 2.1) in 2013. These trends are broadly similar to the rate of mutation in H3N2 over the same time period. However, in contrast to H3N2 strains, the rate of mutation accumulation has slowed in recent years. Our results are notable because, over the course of the study, mutation rates in H3N2 similar to that seen with A(H1N1)pdm09 led to the emergence of two antigenic drift variants. However, while there has been an H1N1 epidemic in North America this season, evidence to date indicates the vaccine is still effective, suggesting the epidemic is not due to the emergence of an antigenic drift variant. Our results suggest that more research is needed to understand how viral mutations are related to vaccine effectiveness so that future vaccine choices and development can be more predictive.Publication Protein Homeostasis Imposes a Barrier on Functional Integration of Horizontally Transferred Genes in Bacteria(Public Library of Science, 2015) Bershtein, Shimon; Serohijos, Adrian; Bhattacharyya, Sanchari; Manhart, Michael; Choi, Jeong-Mo; Mu, Wanmeng; Zhou, Jingwen; Shakhnovich, EugeneHorizontal gene transfer (HGT) plays a central role in bacterial evolution, yet the molecular and cellular constraints on functional integration of the foreign genes are poorly understood. Here we performed inter-species replacement of the chromosomal folA gene, encoding an essential metabolic enzyme dihydrofolate reductase (DHFR), with orthologs from 35 other mesophilic bacteria. The orthologous inter-species replacements caused a marked drop (in the range 10–90%) in bacterial growth rate despite the fact that most orthologous DHFRs are as stable as E.coli DHFR at 37°C and are more catalytically active than E. coli DHFR. Although phylogenetic distance between E. coli and orthologous DHFRs as well as their individual molecular properties correlate poorly with growth rates, the product of the intracellular DHFR abundance and catalytic activity (kcat/KM), correlates strongly with growth rates, indicating that the drop in DHFR abundance constitutes the major fitness barrier to HGT. Serial propagation of the orthologous strains for ~600 generations dramatically improved growth rates by largely alleviating the fitness barriers. Whole genome sequencing and global proteome quantification revealed that the evolved strains with the largest fitness improvements have accumulated mutations that inactivated the ATP-dependent Lon protease, causing an increase in the intracellular DHFR abundance. In one case DHFR abundance increased further due to mutations accumulated in folA promoter, but only after the lon inactivating mutations were fixed in the population. Thus, by apparently distinguishing between self and non-self proteins, protein homeostasis imposes an immediate and global barrier to the functional integration of foreign genes by decreasing the intracellular abundance of their products. Once this barrier is alleviated, more fine-tuned evolution occurs to adjust the function/expression of the transferred proteins to the constraints imposed by the intracellular environment of the host organism.Publication Graph’s Topology and Free Energy of a Spin Model on the Graph(American Physical Society (APS), 2017) Choi, Jeong-Mo; Gilson, Amy Ilana; Shakhnovich, EugeneIn this work we show that there is a direct relationship between a graph's topology and the free energy of a spin system on the graph. We develop a method of separating topological and enthalpic contributions to the free energy, and find that considering the topology is sufficient to qualitatively compare the free energies of different graph systems at high temperature, even when the energetics are not fully known. This method was applied to the metal lattice system with defects, and we found that it partially explains why point defects are more stable than high-dimensional defects. Given the energetics, we can even quantitatively compare free energies of different graph structures via a closed form of linear graph contributions. The closed form is applied to predict the sequence space free energy of lattice proteins, which is a key factor determining the designability of a protein structure.Publication Systems-Level Response to Point Mutations in a Core Metabolic Enzyme Modulates Genotype-Phenotype Relationship(Elsevier BV, 2015) Bershtein, Shimon; Choi, Jeong-Mo; Bhattacharyya, Sanchari; Budnik, Bogdan; Shakhnovich, EugeneLinking the molecular effects of mutations to fitness is central to understanding evolutionary dynamics. Here we establish a quantitative relation between the global effect of mutations on the E. coli proteome and bacterial fitness. We created E. coli strains with specific destabilizing mutations in the chromosomal folA gene encoding dihydrofolate reductase (DHFR) and quantified the ensuing changes in the abundances of 2000+ E. coli proteins in mutant strains using tandem mass tags with subsequent LC-MS/MS. mRNA abundances in the same E. coli strains were also quantified. The proteomic effects of mutations in DHFR are quantitatively linked to phenotype: the standard deviations of the distributions of logarithms of relative (to wild-type) protein abundances anti-correlate with bacterial growth rates. Proteomes hierarchically cluster first by media conditions, and within each condition, by the severity of the perturbation to DHFR function. These results highlight the importance of a systems-level layer in the genotype-phenotype relationship.Publication Multi-Scale Theoretical Investigations of Protein Interactions and Evolution(2016-05-12) Choi, Jeong-Mo; Shakhnovich, Eugene; Zhuang, Xiaowei; Levine, ErelEvolution of biological systems requires players of multiple layers, from atoms and molecules to organisms and populations. Expression of a gene is operated by molecular machineries for transcription, translation, regulation, and maintenance, which work in concert to produce certain macroscopic and observable phenotypes. And when these phenotypes are exposed to selective pressures, more fit phenotypes (with their genes, molecular machineries, and interaction networks) survive in the population. While the relationship of a gene to its cellular consequences is not fully elucidated, it is known that molecular interactions are one of the key factors that determine the relationship. In this dissertation, we introduce several theoretical tools to study protein interactions and evolution, and show their applications at various scales. The first tool is a coarse-grained scoring function that predicts binding free energy of a protein complex. The scoring function is a simple linear combination of exposed interface areas of different amino acids. In spite of the simplicity, it shows a reasonable predictive power, and predicts correct biochemistry qualitatively. The second is an analytical theory of a spin model on a simple graph, developed by using conventional statistical mechanics. We separated structural and energetic contributions to the free energy of the system, and also obtained a closed form of linear graph contributions. The closed form is applied to predict sequence space free energy of lattice proteins. Lastly, we introduce statistical methods to analyze cellular proteomes and transcriptomes. They can extract global responses of proteomes and transcriptomes to a perturbation, and also responses of specific gene groups. We applied the methods to E. coli and yeast systems to address questions on the genotype-phenotype relationship and evolution.