Interaction of sigma 70 with Escherichia coli RNA polymerase core enzyme studied by surface plasmon resonance.

The interaction between the core form of bacterial RNA polymerases and sigma factors is essential for specific promoter recognition, and for coordinating the expression of different sets of genes in response to varying cellular needs. The interaction between Escherichia coli core RNA polymerase and sigma 70 has been investigated by surface plasmon resonance. The His-tagged form of sigma 70 factor was immobilised on a Ni2+-NTA chip for monitoring its interaction with core polymerase. The binding constant for the interaction was found to be 1.9x10(-7) M, and the dissociation rate constant for release of sigma from core, in the absence of DNA or transcription, was 4x10(-3) s(-1), corresponding to a half-life of about 200 s.

Stretching of single collapsed DNA molecules.

The elastic response of single plasmid and lambda phage DNA molecules was probed using optical tweezers at concentrations of trivalent cations that provoked DNA condensation in bulk. For uncondensed plasmids, the persistence length, P, decreased with increasing spermidine concentration before reaching a limiting value 40 nm. When condensed plasmids were stretched, two types of behavior were observed: a stick-release pattern and a plateau at approximately 20 pN. These behaviors are attributed to unpacking from a condensed structure, such as coiled DNA. Similarly, condensing concentrations of hexaammine cobalt(III) (CoHex) and spermidine induced extensive changes in the low and high force elasticity of lambda DNA. The high force (5-15 pN) entropic elasticity showed worm-like chain (WLC) behavior, with P two- to fivefold lower than in low monovalent salt. At lower forces, a 14-pN plateau abruptly appeared. This corresponds to an intramolecular attraction of 0.083-0.33 kT/bp, consistent with osmotic stress measurements in bulk condensed DNA. The intramolecular attractive force with CoHex is larger than with spermidine, consistent with the greater efficiency with which CoHex condenses DNA in bulk. The transition from WLC behavior to condensation occurs at an extension about 85% of the contour length, permitting looping and nucleation of condensation. Approximately half as many base pairs are required to nucleate collapse in a stretched chain when CoHex is the condensing agent.

Sequence-dependent conformational differences of small RNAs revealed by native gel electrophoresis.

In this study, we use native polyacrylamide gel electrophoresis and one-dimensional NMR spectroscopy to analyze small RNA hairpins containing a UUCG tetraloop. The aggregation state of one RNA 16-mer (5'-CGGCUUCGGUCGACCA-3') in the presence of Mg(2+) was confirmed by laser light scattering. Although it is widely known in the RNA field that some RNAs tend to aggregate, especially when present at high concentrations, the sequence elements responsible for this effect are rarely identified. In this work, we show that Mg(2+)-induced aggregation of the 16-mer RNA hairpin is sensitive to the presence of the 3'-terminal base and a specific 2'-hydroxyl group. Our study highlights the fact that even small changes in a particular RNA sequence can increase its tendency to undergo Mg(2+)-dependent aggregation in an unpredictable manner. Our analysis also shows that native gel electrophoresis is a sensitive probe of RNA conformation with the capability to detect differences apparently caused by subtle base stacking effects at the ends of helices.

1-anilino-8-naphthalene sulfonate as a protein conformational tightening agent.

1-Anilino-8-naphthalene sulfonate (ANS) anion is conventionally considered to bind to preexisting hydrophobic (nonpolar) surfaces of proteins, primarily through its nonpolar anilino-naphthalene group. Such binding is followed by an increase in ANS fluorescence intensity, similar to that occurring when ANS is dissolved in organic solvents. It is generally assumed that neither the negative sulfonate charge on the ANS, nor charges on the protein, participate significantly in ANS-protein interaction. However, titration calorimetry has demonstrated that most ANS binding to a number of proteins occurs through electrostatic forces, in which ion pairs are formed between ANS sulfonate groups and cationic groups on the proteins (D. Matulis and R. E. Lovrien, Biophys. J., 1998, Vol. 74, pp. 1-8). Here we show by viscometry and diffusion coefficient measurements that bovine serum albumin and gamma-globulin, starting from their acid-expanded, most hydrated conformations, undergo extensive molecular compaction upon ANS binding. As the cationic protein binds negatively charged ANS anion it also takes up positively charged protons from water to compensate the effect of the negative charge, and leaves the free hydroxide anions in solution thus shifting pH upward (the Scatchard-Black effect). These results indicate that ANS is not always a definitive reporter of protein molecular conformation that existed before ANS binding. Instead, ANS reports on a conformationally tightened state produced by the interplay of ionic and hydrophobic characters of both protein and ligand.

Ionic effects on the elasticity of single DNA molecules.

We used a force-measuring laser tweezers apparatus to determine the elastic properties of lambda-bacteriophage DNA as a function of ionic strength and in the presence of multivalent cations. The electrostatic contribution to the persistence length P varied as the inverse of the ionic strength in monovalent salt, as predicted by the standard worm-like polyelectrolyte model. However, ionic strength is not always the dominant variable in determining the elastic properties of DNA. Monovalent and multivalent ions have quite different effects even when present at the same ionic strength. Multivalent ions lead to P values as low as 250-300 A, well below the high-salt "fully neutralized" value of 450-500 A characteristic of DNA in monovalent salt. The ions Mg2+ and Co(NH3)63+, in which the charge is centrally concentrated, yield lower P values than the polyamines putrescine2+ and spermidine3+, in which the charge is linearly distributed. The elastic stretch modulus, S, and P display opposite trends with ionic strength, in contradiction to predictions of macroscopic elasticity theory. DNA is well described as a worm-like chain at concentrations of trivalent cations capable of inducing condensation, if condensation is prevented by keeping the molecule stretched. A retractile force appears in the presence of multivalent cations at molecular extensions that allow intramolecular contacts, suggesting condensation in stretched DNA occurs by a "thermal ratchet" mechanism.

Lipid differentiation in MP26 junction enriched membranes of bovine lens fiber cells.

The present study was undertaken to address the question whether lipid differentiation occurs in junctional domains which could imply a functional requirement for specific lipids in junctional structures. Junction enriched membranes were isolated from bovine lens fiber cells using Tris and urea treatment, and the presence of junctional structures was ascertained by electron microscopy. Enrichment in major intrinsic protein (MIP, MP26) was monitored by SDS polyacrylamide gel electrophoresis. Junctional lipids were extracted by a modified Folch procedure, to quantitatively recover cholesterol, and lipid classes were analyzed. While 99.5% of total lens protein was solubilized in the course of junction isolation, 43.9% of cell phospholipids (PL) and 64.1% of cell cholesterol (Chol) were conserved. Cholesterol was by far the predominant lipid in the junction enriched lens fiber cell membranes (833 nmol/mg protein) and was more abundant than all phospholipids combined (682 nmol/mg protein). In isolating the junctional membranes, cholesterol levels increased 144-fold, and average phospholipid levels increased 99-fold, which resulted in an increase in Chol/PL ratio from 0.84 to 1.22. Different phospholipids showed substantially different degrees of enrichment with highest enrichments seen for the phosphatidylethanolamine fraction (152-fold) and sphingomyelin (101-fold). Thus, the phospholipids of the junction enriched membranes consisted mainly of ethanolamine glycerophospholipids (37.3%) and sphingomyelin (28.6%), with lesser amounts of choline glycerophospholipids (23.5%) and phosphatidylserine (9.2%) present. Our data suggest that the MP26 junction enriched membranes of bovine lens fiber cells contain differentiated lipid domains, and that cholesterol, ethanolamine glycerophospholipids and sphingomyelin are the prevalent boundary lipids of the major intrinsic protein in these domains.