Combinatorics of feedback in cellular uptake and metabolism of small molecules

Krishna, Sandeep; Semsey, Szabolcs; Sneppen, Kim

doi:10.1073/pnas.0706231105

Cited by 28 publications

(38 citation statements)

References 32 publications

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“…For example, the AA(ϩ/ϩ) loop motif indicates that the transcription of both transport and metabolic genes are activated, whereas the RR(Ϫ/Ϫ) motif demonstrates that the transcription of both genes are repressed. The possible logical structures of the feedback loop motifs can be characterized depending on how Lrp (or Lrp-leucine complex) activates or represses both T and E in response to the exogenous leucine: homeostasis (Ϫ/ϩ), nutrition (ϩ/ϩ), flow homeostasis (Ϫ/Ϫ), and accumulation (ϩ/Ϫ) (1). Based on the feedback loop motifs, we analyzed the behavior of logical structures of the transporters and metabolic enzymes in response to the exogenous leucine (Table S4).…”

Section: Resultsmentioning

confidence: 99%

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Genome-scale reconstruction of the Lrp regulatory network in Escherichia coli

Cho

Barrett

Knight

et al. 2008

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

170

225

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Broad-acting transcription factors (TFs) in bacteria form regulons. Here, we present a 4-step method to fully reconstruct the leucineresponsive protein (Lrp) regulon in Escherichia coli K-12 MG 1655 that regulates nitrogen metabolism.Step 1 is composed of obtaining high-resolution ChIP-chip data for Lrp, the RNA polymerase and expression profiles under multiple environmental conditions. We identified 138 unique and reproducible Lrp-binding regions and classified their binding state under different conditions. In the second step, the analysis of these data revealed 6 distinct regulatory modes for individual ORFs. In the third step, we used the functional assignment of the regulated ORFs to reconstruct 4 types of regulatory network motifs around the metabolites that are affected by the corresponding gene products. In the fourth step, we determined how leucine, as a signaling molecule, shifts the regulatory motifs for particular metabolites. The physiological structure that emerges shows the regulatory motifs for different amino acid fall into the traditional classification of amino acid families, thus elucidating the structure and physiological functions of the Lrp-regulon. The same procedure can be applied to other broad-acting TFs, opening the way to full bottom-up reconstruction of the transcriptional regulatory network in bacterial cells. ChIP-chip ͉ transcription factorT ranscriptional regulatory systems often regulate the formation rates and the concentration of small molecules by 2 feedback loops that regulate the transporters and metabolic enzymes. In many cases, these 2 feedback loops are connected by a common transcription factor (TF) that senses the concentration of the small molecule (1). Little is known at present about the transition between the regulatory modes in the feedback loop motifs for global TFs in bacteria. One such transcription factor is the leucineresponsive protein (Lrp), which is a global transcription regulator widely distributed throughout the bacteria including Escherichia coli (2-4). The Lrp regulon includes genes involved in amino acid biosynthesis and degradation, small molecule transport, pili synthesis, and other cellular functions including 1-carbon metabolism (2, 4-6). The regulatory action of Lrp on target genes is often modulated by the binding of the small effector molecule leucine and in effect endows Lrp with the ability to affect transcriptional regulation in all possible ways. That is, upon addition of leucine to the environment, the activity of Lrp can be enhanced, reversed, or unaffected (2, 4, 7). Little is known about in vivo Lrp-binding events at the genome scale in the presence or absence of leucine and the extent to which the different modes of regulation are used for different metabolites. Such information is needed to reconstruct the Lrp regulon and the understanding of nitrogen metabolism.In this study, we applied a systems approach by integrating genome-scale data from chromatin immunoprecipitation followed by microarray hybridization (ChIP-chip) for Lrp and...

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Section: Resultsmentioning

confidence: 99%

“…In many cases, these 2 feedback loops are connected by a common transcription factor (TF) that senses the concentration of the small molecule (1). Little is known at present about the transition between the regulatory modes in the feedback loop motifs for global TFs in bacteria.…”

mentioning

confidence: 99%

Genome-scale reconstruction of the Lrp regulatory network in Escherichia coli

Cho

Barrett

Knight

et al. 2008

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

170

225

View full text Add to dashboard Cite

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“…If the system did not reduce the rate of galactose utilization when the galactose influx decreases, the cell would quickly use up the intracellular galactose pool, leading to switching off of promoters by reactivated GalR and GalS and therefore reduced galactose transport and utilization. This effect can be overcome by changing the relative strengths of the transport and metabolism feedback loops (1). Limiting GalK production is an efficient way to block the metabolic feedback loop without compromising transport, allowing accumulation of intracellular galactose.…”

Section: Discussionmentioning

confidence: 99%

“…Assay of ␤-Glucuronidase Activity-Cells were grown overnight in LB medium containing 100 g/ml Zeocin and diluted 1000-fold for further growth in M63 medium containing 10 g/ml Zeocin and supplemented with 0.4% (w/v) D-galactose, 0.1% (w/v) casamino acids (Sigma A2427), and 0.004% (w/v) vitamin B 1 . At various times, aliquots of cells were removed, diluted in 1 ml of LB medium to OD 600 ϭ 0.2, pelleted, resuspended in M63 medium containing 100 g/ml chloramphenicol, and stored at Ϫ70°C.…”

Section: Methodsmentioning

confidence: 99%

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Timing of Gene Transcription in the Galactose Utilization System of Escherichia coli

Horváth

Hunziker²,

Erdőssy

et al. 2010

Journal of Biological Chemistry

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In the natural environment, bacterial cells have to adjust their metabolism to alterations in the availability of food sources. The order and timing of gene expression are crucial in these situations to produce an appropriate response. We used the galactose regulation in Escherichia coli as a model system for understanding how cells integrate information about food availability and cAMP levels to adjust the timing and intensity of gene expression. We simulated the feast-famine cycle of bacterial growth by diluting stationary phase cells in fresh medium containing galactose as the sole carbon source. We followed the activities of six promoters of the galactose system as cells grew on and ran out of galactose. We found that the cell responds to a decreasing external galactose level by increasing the internal galactose level, which is achieved by limiting galactose metabolism and increasing the expression of transporters. We show that the cell alters gene expression based primarily on the current state of the cell and not on monitoring the level of extracellular galactose in real time. Some decisions have longer term effects; therefore, the current state does subtly encode the history of food availability. In summary, our measurements of timing of gene expression in the galactose system suggest that the system has evolved to respond to environments where future galactose levels are unpredictable rather than regular feast and famine cycles.Transport and metabolism of several sugars are controlled via two feedback loops connected by a common regulator that senses the intracellular concentration of the small molecule (1, 2). The simplest systems (e.g. the lactose utilization system in Escherichia coli) consist of two operons, a regulator gene and a regulated operon containing at least two cistrons, one encoding a transporter and the other encoding an enzyme that modifies/degrades the small molecule (3). In such systems, the genes encoding the sugar transporter (e.g. lacY) and the enzyme for sugar degradation (e.g. lacZ) are regulated simultaneously. However, many sugar utilization systems reached higher levels of complexity, e.g. having multiple transporters, regulators, or several enzymes of a metabolic pathway. For example, the gal system of E. coli contains genes involved in the transport (galP and mglBAC) and amphibolic utilization (galETKM) of the sugar D-galactose. Genes of the gal regulon belong to different operons (4). This setup allows differential regulation of functions when needed. Regulation of the gal system is governed by two similar regulators, GalR and GalS, which are regulated in different ways (5-7). Previous studies suggested that GalS plays only a minor role in steady-state conditions but becomes important transiently when a high level of extracellular galactose is quickly decreased (8). Besides sensing the intracellular sugar level, galactose utilization is also regulated by the cAMP-cAMP receptor protein (CRP) 2 complex. cAMP is a signal of carbon shortage and is sensed by CRP. cAMP is synthesi...

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Engineering Microbial Metabolite Dynamics and Heterogeneity

Schmitz

Hartline

Zhang

2017

Biotechnology Journal

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As yields for biological chemical production in microorganisms approach their theoretical maximum, metabolic engineering requires new tools, and approaches for improvements beyond what traditional strategies can achieve. Engineering metabolite dynamics and metabolite heterogeneity is necessary to achieve further improvements in product titers, productivities, and yields. Metabolite dynamics, the ensemble change in metabolite concentration over time, arise from the need for microbes to adapt their metabolism in response to the extracellular environment and are important for controlling growth and productivity in industrial fermentations. Metabolite heterogeneity, the cell-to-cell variation in a metabolite concentration in an isoclonal population, has a significant impact on ensemble productivity. Recent advances in single cell analysis enable a more complete understanding of the processes driving metabolite heterogeneity and reveal metabolic engineering targets. The authors present an overview of the mechanistic origins of metabolite dynamics and heterogeneity, why they are important, their potential effects in chemical production processes, and tools and strategies for engineering metabolite dynamics and heterogeneity. The authors emphasize that the ability to control metabolite dynamics and heterogeneity will bring new avenues of engineering to increase productivity of microbial strains.

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Combinatorics of feedback in cellular uptake and metabolism of small molecules

Cited by 28 publications

References 32 publications

Genome-scale reconstruction of the Lrp regulatory network in Escherichia coli

Genome-scale reconstruction of the Lrp regulatory network in Escherichia coli

Timing of Gene Transcription in the Galactose Utilization System of Escherichia coli

Engineering Microbial Metabolite Dynamics and Heterogeneity

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