Thomas E. Kuhlman scite author profile

An increasing number of small RNAs (sRNAs) have been shown to regulate critical pathways in prokaryotes and eukaryotes. In bacteria, regulation by trans-encoded sRNAs is predominantly found in the coordination of intricate stress responses. The mechanisms by which sRNAs modulate expression of its targets are diverse. In common to most is the possibility that interference with the translation of mRNA targets may also alter the abundance of functional sRNAs. Aiming to understand the unique role played by sRNAs in gene regulation, we studied examples from two distinct classes of bacterial sRNAs in Escherichia coli using a quantitative approach combining experiment and theory. Our results demonstrate that sRNA provides a novel mode of gene regulation, with characteristics distinct from those of protein-mediated gene regulation. These include a threshold-linear response with a tunable threshold, a robust noise resistance characteristic, and a built-in capability for hierarchical cross-talk. Knowledge of these special features of sRNA-mediated regulation may be crucial toward understanding the subtle functions that sRNAs can play in coordinating various stress-relief pathways. Our results may also help guide the design of synthetic genetic circuits that have properties difficult to attain with protein regulators alone.

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Transcriptional regulation by the numbers: applications

Bintu

Buchler

García

et al. 2005

Current Opinion in Genetics & Development

366

466

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With the increasing amount of experimental data on gene expression and regulation, there is a growing need for quantitative models to describe the data and relate them to their respective context. Thermodynamic models provide a useful framework for the quantitative analysis of bacterial transcription regulation. This framework can facilitate the quantification of vastly different forms of gene expression from several well-characterized bacterial promoters that are regulated by one or two species of transcription factors; it is useful because it requires only a few parameters. As such, it provides a compact description useful for higher-level studies (e.g. of genetic networks) without the need to invoke the biochemical details of every component. Moreover, it can be used to generate hypotheses on the likely mechanisms of transcriptional control.

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Combinatorial transcriptional control of the lactose operon of Escherichia coli

Kuhlman

Zhang

Saier

et al. 2007

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

238

274

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The goal of systems biology is to understand the behavior of the whole in terms of knowledge of the parts. This is hard to achieve in many cases due to the difficulty of characterizing the many constituents involved in a biological system and their complex web of interactions. The lac promoter of Escherichia coli offers the possibility of confronting ''system-level'' properties of transcriptional regulation with the known biochemistry of the molecular constituents and their mutual interactions. Such confrontations can reveal previously unknown constituents and interactions, as well as offer insight into how the components work together as a whole. Here we study the combinatorial control of the lac promoter by the regulators Lac repressor (LacR) and cAMP-receptor protein (CRP). A previous in vivo study [Setty Y, Mayo AE, Surette MG, Alon U (2003) Proc Natl Acad Sci USA 100:7702-7707] found gross disagreement between the observed promoter activities and the expected behavior based on the known molecular mechanisms. We repeated the study by identifying and removing several extraneous factors that significantly modulated the expression of the lac promoter. Through quantitative, systematic characterization of promoter activity for a number of key mutants and guided by the thermodynamic model of transcriptional regulation, we were able to account for the combinatorial control of the lac promoter quantitatively, in terms of a cooperative interaction between CRP and LacR-mediated DNA looping. Specifically, our analysis indicates that the sensitivity of the inducer response results from LacR-mediated DNA looping, which is significantly enhanced by CRP.DNA looping ͉ gene regulation ͉ lac promoter ͉ systems biology T he lac promoter (Plac) of Escherichia coli is one of the most extensively studied systems of molecular biology (1-6). The knowledge and insight gained from these studies have shaped much of how we now think about gene regulation. It is well known that E. coli cells repress the expression of the lac operon when glucose is abundant in the growth medium. Only when the glucose level is low and the lactose level is high is the operon fully expressed. Thus, the regulation of this operon represents an example of ''combinatorial control'' widely seen in prokaryotes and eukaryotes (7,8). In this case, the combinatorial control is implemented molecularly by two transcription factors, the Lac repressor (LacR), which represses transcription and the cAMP receptor protein (CRP) which activates transcription. Activation by CRP requires the inducer cAMP, which is used by E. coli cells as a signal of glucose shortage (9-15). Repression by LacR is activated in a nearly all-or-none manner upon varying the amount of lactose or one of the several synthetic inducers in growth medium with poor carbon sources (16,17). The foldchange in repression is very large (Ͼ1,000-fold) and has been shown to involve LacR-mediated DNA looping (5, 6, 18-21).Here we quantitatively investigate the competing effects of activation and repression on the...

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Site-specific chromosomal integration of large synthetic constructs

Kuhlman¹,

Cox²

2010

237

272

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We have developed an effective, easy-to-use two-step system for the site-directed insertion of large genetic constructs into arbitrary positions in the Escherichia coli chromosome. The system uses λ-Red mediated recombineering accompanied by the introduction of double-strand DNA breaks in the chromosome and a donor plasmid bearing the desired insertion fragment. Our method, in contrast to existing recombineering or phage-derived insertion methods, allows for the insertion of very large fragments into any desired location and in any orientation. We demonstrate this method by inserting a 7-kb fragment consisting of a venus-tagged lac repressor gene along with a target lacZ reporter into six unique sites distributed symmetrically about the chromosome. We also demonstrate the universality and repeatability of the method by separately inserting the lac repressor gene and the lacZ target into the chromosome at separate locations around the chromosome via repeated application of the protocol.

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Thomas E. Kuhlman

Quantitative Characteristics of Gene Regulation by Small RNA

Transcriptional regulation by the numbers: applications

Combinatorial transcriptional control of the lactose operon of Escherichia coli

Site-specific chromosomal integration of large synthetic constructs

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