Growth-Rate Dependent And Nutrient-Specific Gene Expression Resource Allocation In Fission Yeast

Kleijn, Istvan T.; Martínez-Segura, Amalia; Bertaux, François; Saint, Malika; Kramer, Holger; Shahrezaei, Vahid; Marguerat, Samuel

doi:10.1101/2021.03.16.435638

Cited by 3 publications

(5 citation statements)

References 119 publications

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“…While this could be an underestimation given that such networks are still incomplete, this result highlights the role of general biological mechanisms that may guide differential protein expression. One known such factor is the growth rate, known to be correlated with changes in proteome and transcriptome (Airoldi et al, 2009; Fazio et al, 2008; Hughes et al, 2000a; Kemmeren et al, 2014; Kleijn et al, 2022; Slavov and Botstein, 2011; Wytock and Motter, 2019; Yu et al, 2021). Here, our large-scale dataset provides a differentiated picture about the role of growth-rate-dependent changes in differential protein expression.…”

Section: Resultsmentioning

confidence: 99%

The Proteomic Landscape of Genome-Wide Genetic Perturbations

Messner

Demichev

Muenzner

et al. 2022

Preprint

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SummaryFunctional genomic strategies help to address the genotype phenotype problem by annotating gene function and regulatory networks. Here, we demonstrate that combining functional genomics with proteomics uncovers general principles of protein expression, and provides new avenues to annotate protein function. We recorded precise proteomes for all non-essential gene knock-outs in Saccharomyces cerevisiae. We find that protein abundance is driven by a complex interplay of i) general biological properties, including translation rate, turnover, and copy number variations, and ii) their genetic, metabolic and physical interactions, including membership in protein complexes. We further show that combining genetic perturbation with proteomics provides complementary dimensions of functional annotation: proteomic profiling, reverse proteomic profiling, profile similarity and protein covariation analysis. Thus, our study generates a resource in which nine million protein quantities are linked to 79% of the yeast coding genome, and shows that functional proteomics reveals principles that govern protein expression.Highlights-Nine million protein quantities recorded in ~4,600 non-essential gene deletions in S. cerevisiae reveal principles of how the proteome responds to genetic perturbation-Genome-scale protein expression is determined by both functional relationships between proteins, as well as common biological responses-Broad protein expression profiles in slow-growing strains can be explained by chromosomal aneuploidies-Protein half-life and ribosome occupancy are predictable from protein abundance changes across knock-outs-Functional proteomics annotates missing gene function in four complementary dimensions

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Section: Resultsmentioning

confidence: 99%

The Proteomic Landscape of Genome-Wide Genetic Perturbations

Messner

Demichev

Muenzner

et al. 2022

Preprint

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“…As growth rate continues to increase, the active constraints change (blue shaded region in Figure 3), and so does the predicted metabolic behavior. At very fast growth rates, instead of mitochondrial proteome capacity, the unspecified protein (UP) fraction (a proxy for the cytosolic proteome capacity), starts to limit growth (UP mass fraction in the proteome reaches the minimal value we estimated on the basis of proteomics data (Kleijn et al, 2022)). As a result, any increase in growth has to be accompanied by trading in mitochondrial proteins for cytosolic ones (Figure 3d, panel “Mito.…”

Section: Resultsmentioning

confidence: 96%

“…Next we assessed the peptide elongation rate of the cytosolic ribosomes and the fraction of proteome, occupied by “inactive” ribosomes Φ R,0 (following (Metzl-Raz et al, 2017)), other key parameters, as shown for the pcYeast model (Elsemman et al, 2022) (Figure 2c). We used quantitative proteomics data from turbidostat experiments in EMM2 media (2% glucose), supplemented with different single nitrogen sources (Kleijn et al, 2022). First, we computed the fraction of “inactive” ribosomes Φ R,0 ≈ 0.05 g ( g protein ) ‒1 from the linear regression of the experimental data points (Figure 2c, black dashed line).…”

Section: Resultsmentioning

confidence: 99%

“…Existing experimental datasets of S. pombe , unfortunately, are not as comprehensive. Although many of the datasets are of high-quality, they consider only one aspect of cell growth, for instance, exometabolite fluxes (de Jong-Gubbels et al, 1996), or proteome composition (Kleijn et al, 2022). For modelling purposes, systemic experiments which cover several layers of information at once (e.g.…”

Section: Discussionmentioning

confidence: 99%

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A computational toolbox to investigate the metabolic potential and resource allocation in fission yeast

Grigaitis

Grundel

Pelt-KleinJan

et al. 2022

Preprint

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The fission yeast Schizosaccharomyces pombe is a popular eukaryal model organism for cell division and cell cycle studies. With this extensive knowledge of its cell and molecular biology, S. pombe also holds promise for use in metabolism research and industrial applications. However, unlike the baker's yeast Saccharomyces cerevisiae, a major workhorse in these areas, cell physiology and metabolism of S. pombe remain less explored. One way to advance understanding of organism-specific metabolism is construction of computational models and their use for hypothesis testing. To this end, we leverage existing knowledge of S. cerevisiae to generate a manually-curated high-quality reconstruction of S. pombe's metabolic network, including a proteome-constrained version of the model. Using these models, we gain insights into the energy demands for growth, as well as ribosome kinetics in S. pombe. Furthermore, we predict proteome composition and identify growth-limiting constraints that determine optimal metabolic strategies under different glucose availability regimes, and reproduce experimentally determined metabolic profiles. Notably, we find similarities in metabolic and proteome predictions of S. pombe with S. cerevisiae, which indicate that similar cellular resource constraints operate to dictate metabolic organization. With these use cases, we show, on the one hand, how these models provide an efficient means to transfer metabolic knowledge from a well-studied to a lesser-studied organism, and on the other, how they can successfully be used to explore the metabolic behaviour and the role of resource allocation in driving different strategies in fission yeast.

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“…It means that two options, 3 and 4, are justified, and s can be considered as the common independent factor affecting the SGR and rRNA expression (the SGR dependence on s was discovered 80 years ago [43] and is beyond any doubt). Finally, all the studied microorganisms, prokaryotic or eucaryotic, uniformly follow the so-called 'ribosomal growth law', which states that the ribosomal content in cells is the principal internal bottleneck [16,17,44,45]; the translation process is recognized as the slowest biosynthetic step; hence, growth acceleration can be achieved only through an increase of the ribosomal copy numbers. In other words, the SGR depends on the rRNA level, not the opposite!…”

Section: Sgr and MMCC The Chicken And The Egg Dilemmamentioning

confidence: 99%

Genome-Scale Reconstruction of Microbial Dynamic Phenotype: Successes and Challenges

Panikov

2021

Microorganisms

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This review is a part of the SI ‘Genome-Scale Modeling of Microorganisms in the Real World’. The goal of GEM is the accurate prediction of the phenotype from its respective genotype under specified environmental conditions. This review focuses on the dynamic phenotype; prediction of the real-life behaviors of microorganisms, such as cell proliferation, dormancy, and mortality; balanced and unbalanced growth; steady-state and transient processes; primary and secondary metabolism; stress responses; etc. Constraint-based metabolic reconstructions were successfully started two decades ago as FBA, followed by more advanced models, but this review starts from the earlier nongenomic predecessors to show that some GEMs inherited the outdated biokinetic frameworks compromising their performances. The most essential deficiencies are: (i) an inadequate account of environmental conditions, such as various degrees of nutrients limitation and other factors shaping phenotypes; (ii) a failure to simulate the adaptive changes of MMCC (MacroMolecular Cell Composition) in response to the fluctuating environment; (iii) the misinterpretation of the SGR (Specific Growth Rate) as either a fixed constant parameter of the model or independent factor affecting the conditional expression of macromolecules; (iv) neglecting stress resistance as an important objective function; and (v) inefficient experimental verification of GEM against simple growth (constant MMCC and SGR) data. Finally, we propose several ways to improve GEMs, such as replacing the outdated Monod equation with the SCM (Synthetic Chemostat Model) that establishes the quantitative relationships between primary and secondary metabolism, growth rate and stress resistance, process kinetics, and cell composition.

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Growth-Rate Dependent And Nutrient-Specific Gene Expression Resource Allocation In Fission Yeast

Cited by 3 publications

References 119 publications

The Proteomic Landscape of Genome-Wide Genetic Perturbations

The Proteomic Landscape of Genome-Wide Genetic Perturbations

A computational toolbox to investigate the metabolic potential and resource allocation in fission yeast

Genome-Scale Reconstruction of Microbial Dynamic Phenotype: Successes and Challenges

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