A modular spring-loaded actuator for mechanical activation of membrane proteins.

How cells respond to mechanical forces by converting them into biological signals underlie crucial cellular processes. Our understanding of mechanotransduction has been hindered by technical barriers, including limitations in our ability to effectively apply low range piconewton forces to specific mechanoreceptors on cell membranes without laborious and repetitive trials. To overcome these challenges we introduce the Nano-winch, a robust, easily assembled, programmable DNA origami-based molecular actuator. The Nano-winch is designed to manipulate multiple mechanoreceptors in parallel by exerting fine-tuned, low- piconewton forces in autonomous and remotely activated modes via adjustable single- and double-stranded DNA linkages, respectively. Nano-winches in autonomous mode can land and operate on the cell surface. Targeting the device to integrin stimulated detectable downstream phosphorylation of focal adhesion kinase, an indication that Nano-winches can be applied to study cellular mechanical processes. Remote activation mode allowed finer extension control and greater force exertion. We united remotely activated Nano-winches with single-channel bilayer experiments to directly observe the opening of a channel by mechanical force in the force responsive gated channel protein, BtuB. This customizable origami provides an instrument-free approach that can be applied to control and explore a diversity of mechanotransduction circuits on living cells.

The human estrogen receptor alpha dimer binds a single SRC-1 coactivator molecule with an affinity dictated by agonist structure.

Nuclear receptors act as ligand-inducible transcription factors. Agonist binding leads to interaction with coactivator proteins, and to the assembly of the general transcription machinery. In addition to structural information, a thorough understanding of transcriptional activation by the nuclear receptors requires the characterization of the thermodynamic parameters governing these protein/protein interactions. In this study we have quantitatively characterized the interactions of full-length baculovirus expressed human estrogen receptor alpha (ERalpha), as well as ERalpha hormone binding domain (ERHBD) with a fragment of the coactivator protein SRC-1 (amino acid residues 570 to 780). Fluorescence anisotropy and fluorescence correlation spectroscopy of fluorescently labeled SRC-1(570-780) demonstrate unambiguously that the stoichiometry of the SRC-1/ERalpha/estradiol complex is one coactivator molecule per ERalpha dimer. The affinity of the estradiol or estriol bound ERalpha/SRC-1 complexes was found to be significantly higher than that observed in the presence of estrone. No binding was observed in the absence of ligand or in the presence of antagonists. Distinct anisotropy values for the ERalpha-SRC-1 complexes with different agonists suggest distinct conformations of the complexes depending upon agonist structure.

Quantitative characterization of the interaction between purified human estrogen receptor alpha and DNA using fluorescence anisotropy.

In an effort to better define the molecular mechanisms of the functional specificity of human estrogen receptor alpha, we have carried out equilibrium binding assays to study the interaction of the receptor with a palindromic estrogen response element derived from the vitellogenin ERE. These assays are based on the observation of the fluorescence anisotropy of a fluorescein moiety covalently bound to the target oligonucleotide. The low anisotropy value due to the fast tumbling of the free oligonucleotide in solution increases substantially upon binding the receptor to the labeled ERE. The quality of our data are sufficient to ascertain that the binding is clearly cooperative in nature, ruling out a simple monomer interaction and implicating a dimerization energetically coupled to DNA binding in the nanomolar range. The salt concentration dependence of the affinity reveals formation of high stoichiometry, low specificity complexes at low salt concentration. Increasing the KCl concentration above 200 mM leads to specific binding of ER dimer. We interpret the lack of temperature dependence of the apparent affinity as indicative of an entropy driven interaction. Finally, binding assays using fluorescent target EREs bearing mutations of each of the base pairs in the palindromic ERE half-site indicate that the energy of interaction between ER and its target is relatively evenly distributed throughout the site.

Effect of ligand and DNA binding on the interaction between human transcription intermediary factor 1alpha and estrogen receptors.

Hormonal regulation of gene activity is mediated by nuclear receptors acting as ligand-activated transcription factors. To achieve efficient regulation of gene expression, these receptors must interact with different type of molecules: 1) the steroid hormone, 2) the DNA response element, and 3) various proteins acting as transcriptional cofactors. In the present study, we have investigated how ligand and DNA binding influence the in vitro interaction between estrogen receptors (ERs) and the transcription intermediary factor hTIF1alpha (human transcriptional intermediary factor 1alpha). We first optimized conditions for the coactivator-dependent receptor ligand assay to lower ED50, and we then analyzed the ability of various natural and synthetic estrogens to allow the binding of the two types of proteins. Results were compared with the respective affinities of these ligands for the receptor. We then developed a protein-protein-DNA assay allowing the quantification of cofactor-ER-estrogen response element (ERE) complex formation in the presence of ligand and used measurements of fluorescence anisotropy to define the equilibrium binding parameters of the interaction. We demonstrated that the leucine-charged domain of hTIF1alpha is sufficient to interact with ERE-bound ERalpha in a ligand-dependent manner and showed that binding of ERalpha onto DNA does not significantly affect its hormone-dependent association with TIF1alpha. Finally, we show that, mainly in the absence of hormone, hTIF1alpha interacts better with ERbeta than with ERalpha independently of the presence of ERE.

Visualization of trp repressor and its complexes with DNA by atomic force microscopy.

We used tapping mode atomic force microscopy to visualize the protein/protein and the protein/DNA complexes involved in transcriptional regulation by the trp repressor (TR). Plasmid fragments bearing the natural operators trp EDCBA and trp R, as well as nonspecific fragments, were deposited onto mica in the presence of varying concentrations of TR and imaged. In the presence of L-tryptophan, both specific and nonspecific complexes of TR with DNA are apparent, as well as free TR assemblies directly deposited onto the mica surface. We observed the expected decrease in specificity of TR for its operators with increasing protein concentration (1-5 nM). This loss of DNA-binding specificity is accompanied by the formation of large protein assemblies of varying sizes on the mica surface, consistent with the known tendency of the repressor to oligomerize in solution. When the co-repressor is omitted, no repressor molecules are seen, either on the plasmid fragments or free on the mica surface, probably because of the formation of larger aggregates that are removed from the surface upon washing. All these findings support a role for protein/protein interactions as an additional mechanism of transcriptional regulation by the trp repressor.

Electron spin resonance detection of extracellular superoxide anion released by cultured endothelial cells.

OBJECTIVE AND METHODS: Endothelium produces oxygen-derived free radicals which play a major role in vessel wall physiology and pathology. Whereas NO* production from endothelium has been extensively characterized, little is known about endothelium-derived O2-*. In the present study, we determined the O2-* production of bovine aortic endothelial cells (BAEC) using the spin trap 5,5-dimethyl-1 pyrroline-N-oxide (DMPO) and electron spin resonance (ESR) spectroscopy. RESULTS: An ESR adduct DMPO-OH detected in the supernatant of BAEC after stimulation with the calcium ionophore A23187 originated from the trapping of extracellular O2-*, because coincubation with superoxide dismutase (30 U/ml) completely suppressed the ESR signal, whereas catalase (2000 U/ml) had no effect. A23187 stimulated extracellular O2-* production in a time- and dose-dependent manner. The coenzymes NADH and NADPH both increased the ESR signal, whereas a flavin antagonist, diphenylene iodonium, abolished the ESR signal. Phorbol myristate acetate potentiated, whereas bisindolylmaleimide I inhibited the A23187-stimulated O2-* production, suggesting the involvement of protein kinase C. These signals were not altered L-NAME, a NO-synthase inhibitor, suggesting that the endogenous production of NO* did not alter O2-* production. Finally, the amount of O2-* generated by A23187-stimulated post-confluent BAEC was one order of magnitude higher than that evoked by rat aortic smooth muscle cells stimulated under the same conditions.