Nucleosomes, the basic unit of eukaryotic chromosome structure, cover most of the DNA in eukaryotes, including regulatory sequences. Here, a recently developed Förster resonance energy transfer approach is used to compare structure and stability features of sea urchin 5S nucleosomes and nucleosomes reconstituted on two promoter sequences that are nucleosomal in vivo, containing the yeast GAL10 TATA or the major transcription response elements from the mouse mammary tumor virus promoter. All three sequences form mononucleosomes with similar gel mobilities and similar stabilities at moderate salt concentrations. However, the two promoter nucleosomes differ from 5S nucleosomes in (1) diffusion coefficient values, which suggest differences in nucleosome compaction, (2) intrinsic FRET efficiencies (in solution or in gels), and (3) the response of FRET efficiency to high (>or=600 mM) NaCl concentrations, subnanomolar nucleosome concentrations, and elevated temperatures (to 42 degrees C). These results indicate that nucleosome features can vary depending on the DNA sequence they contain and show that this fluorescence approach is sufficiently sensitive to detect such differences. Sequence-dependent variations in nucleosome structure or stability could facilitate specific nucleosome recognition, working together with other known genomic regulatory mechanisms. The variations in salt-, concentration-, and temperature-dependent responses all occur under conditions that have been shown previously to produce release of H2A-H2B dimers or terminal DNA from nucleosomes and could thus involve differences in those processes, as well as in other features.
To investigate the transition from non-cancerous to metastatic from a physical sciences perspective, the Physical Sciences–Oncology Centers (PS-OC) Network performed molecular and biophysical comparative studies of the non-tumorigenic MCF-10A and metastatic MDA-MB-231 breast epithelial cell lines, commonly used as models of cancer metastasis. Experiments were performed in 20 laboratories from 12 PS-OCs. Each laboratory was supplied with identical aliquots and common reagents and culture protocols. Analyses of these measurements revealed dramatic differences in their mechanics, migration, adhesion, oxygen response, and proteomic profiles. Model-based multi-omics approaches identified key differences between these cells' regulatory networks involved in morphology and survival. These results provide a multifaceted description of cellular parameters of two widely used cell lines and demonstrate the value of the PS-OC Network approach for integration of diverse experimental observations to elucidate the phenotypes associated with cancer metastasis.
When and where proteins associate with each other in living cells are key questions in many biological research projects. One way to address these questions is to measure the extent of Förster resonance energy transfer (FRET) between proteins that have been labeled with appropriate donor and acceptor fluorophores. When both proteins interact, donor and acceptor fluorophores are brought into close vicinity so that the donor can transmit a part of its excitation energy to the acceptor. As a result, both the intensity and the lifetime of the donor fluorescence decrease, whereas the intensity of the acceptor emission increases. This offers different approaches to determine FRET efficiency: One is to detect changes in the intensity of donor and acceptor emission, the other is to measure changes in the lifetime of the donor molecule. One important advantage of the fluorescence lifetime approach is that it allows to distinguish between free and associated donor molecules. However, like intensity measurements it lacks an intrinsic control ensuring that changes in the measured parameters are only due to FRET and not other quenching processes. Here, we show how this limitation can be overcome by spectrally resolved fluorescence lifetime measurements in the time domain. One technique is based on a streak camera system, the other technique is based on a time-correlated-single-photon-counting approach. Both approaches allow biologists to record both donor and acceptor fluorescence emitted by the sample in a single measurement.
Multidimensional time-correlated single photon counting (TCSPC) is based on the excitation of the sample by a high-repetition rate laser and the detection of single photons of the fluorescence signal in several detection channels. Each photon is characterized by its arrival time in the laser period, its detection channel number, and several additional variables such as the coordinates of an image area, or the time from the start of the experiment. Combined with a confocal or two-photon laser scanning microscope and a pulsed laser, multidimensional TCSPC makes a fluorescence lifetime technique with multiwavelength capability, near-ideal counting efficiency, and the capability to resolve multiexponential decay functions. We show that the same technique and the same hardware can be used for precision fluorescence decay analysis and fluorescence correlation spectroscopy (FCS) in selected spots of a sample.
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