John O. Wooll scite author profile

Charge is a fundamental property of macromolecules that is inextricably linked to their structure, solubility, stability, and interactions. Progress has been made on the theoretical and structural aspects of these relationships. However, for several reasons, charge is difficult to measure in solution. Consequently, there is a lack of experimental data that, independent of other macro-ion properties, determines the effective charge. To overcome this problem, novel instrumentation and methods are being developed in our laboratory. Described here is an analytical electrophoresis apparatus that permits both the measurement of electrophoretic mobilities and the determination of steady-state electrophoresis concentration distributions. The latter provides a different-perspective on the processes that influence macro-ion behavior in an electric field. In addition, the apparatus permits the determination of diffusion coefficients either from boundary spreading during transport or from the decay of a concentration gradient. All of these determinations can be made with a single, 8-microL sample in a variety of solvents, thus providing unique insights into the charge properties of a macro-ion. Presented here is a progress report about this emerging technology, including the description of a prototype apparatus and examples of its use with a DNA oligonucleotide.

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Role of Protein−Protein Bridging Interactions on Cooperative Assembly of DNA-Bound CRP−CytR−CRP Complex and Regulation of the Escherichia Coli CytR Regulon

Chahla

Wooll

Laue

et al. 2003

Biochemistry

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The unlinked operons that comprise the Escherichia coli CytR regulon are controlled coordinately through interactions between two gene regulatory proteins, the cAMP receptor protein (CRP) and the cytidine repressor (CytR). CytR controls the balance between CRP-mediated recruitment and activation of RNA polymerase and transcriptional repression. Cooperative interactions between CytR, when bound to an operator (CytO) located upstream of a CytR-regulated promoter, and CRP, when bound to flanking tandem promoters, are critical to the regulatory role of CytR. When CytR binds cytidine, cooperativity is reduced resulting in increased transcriptional activity. However, this cytidine-mediated effect varies among promoters, suggesting that coupling between cytidine binding to CytR and CytR-CRP association is sensitive to promoter structure. To investigate the chemical and structural basis for these effects, we investigated how cytidine binding affects association between CytR and CRP in solution and how it affects the binding of CytR deletion mutants lacking the DNA binding HTH domain, with tandem CRP dimers bound to either udpP or deoP2. Deletion mutants that, as we show here, retain the native functions of the allosteric, inducer-binding domain but do not bind DNA were expressed and purified. We refer to these as Core domain. Despite only weak association between CytR and CRP in solution, our results demonstrate the formation of a relatively stable complex in which the Core domain forms a protein bridge between tandem CRP dimers when bound to either udpP or deoP2. The DeltaG(o) for bridge complex formation is about -7.8 kcal/mol. This is well in excess of that required to account for cooperativity (-2.5 to -3 kcal/mol). The bridge complexes are significantly destabilized by cytidine binding, and to the same extent in both promoter complexes (DeltaDeltaG(o) approximately +2 kcal/mol). Even with this destabilization, DeltaG(o) for bridge complex formation by cytidine-liganded Core domain is still sufficient by itself to account for cooperativity. These findings demonstrate that direct coupling between cytidine binding to CytR and CytR-CRP association does not account for promoter-specific effects on cooperativity. Instead, cytidine binding must induce a CytR conformation that is more rigid or in some other way less tolerant of the variation in the geometric arrangement of operator sites between different promoters.

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John O. Wooll

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Role of Protein−Protein Bridging Interactions on Cooperative Assembly of DNA-Bound CRP−CytR−CRP Complex and Regulation of the Escherichia Coli CytR Regulon

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