Visualizing chromatin and chromosomes in living cells

The dynamic organization of eukaryotic genomes in cell nuclei recently came into the focus of research interest. The kinetics of genome dynamics can be addressed only by approaches involving live cell microscopy. Different methods are available to visualize chromatin, specific chromatin fractions, or individual chromosome territories within nuclei of living mammalian cells. Appropriate labeling procedures as well as cell chamber systems and important controls for live cell microscopy are described.     

Histone modification and chromatin remodeling during NER

Here we review our developments of and results with high resolution studies on global genome nucleotide excision repair (GG-NER) in Saccharomyces cerevisiae. Technologies were developed to examine NER at nucleotide resolution in yeast sequences of choice and to determine how these related to local changes in chromatin. We focused on how GG-NER relates to histone acetylation for its functioning and we identified the histone acetyltransferase Gcn5 and acetylation at lysines 9/14 of histone H3 as a major factor in enabling efficient repair. Factors influencing this Gcn5-mediated event are considered which include Rad16, a GG-NER specific SWI/SNF factor and the yeast histone variant of H2AZ (Htz1). We describe results employing primarily MFA2 as a model gene, but also those with URA3 located at subtelomeric sequences. In the latter case we also see a role for acetylation at histone H4. We then consider the development of a high resolution genome-wide approach that enables one to examine correlations between histone modifications and the NER of UV-induced cyclobutane pyrimidine dimers throughout entire yeast genome. This is an approach that will enable rapid advances in understanding the complexities of how compacted chromatin in chromosomes is processed to access DNA damage before it is returned to its pre-damaged status to maintain epigenetic codes.     

Histone modifications and chromatin remodeling during bacterial infections

The link between bacteria and host chromatin remodeling is an emerging topic. The exciting recent discoveries on bacterial impact on host epigenetics, as discussed in this Review, highlight yet another strategy used by bacterial pathogens to interfere with key cellular processes. The study of how pathogens provoke host chromatin changes will also provide new insights into host epigenetic regulation mechanisms.     

Characterizing locus specific chromatin structure and dynamics with correlative conventional and super-resolution imaging in living cells

The dynamic rearrangement of chromatin is critical for gene regulation, but mapping both the spatial organization of chromatin and its dynamics remains a challenge. Many structural conformations are too small to be resolved via conventional fluorescence microscopy and the long acquisition time of super-resolution photoactivated localization microscopy (PALM) precludes the structural characterization of chromatin below the optical diffraction limit in living cells due to chromatin motion. Here we develop a correlative conventional fluorescence and PALM imaging approach to quantitatively map time-averaged chromatin structure and dynamics below the optical diffraction limit in living cells. By assigning localizations to a locus as it moves, we reliably discriminate between bound and unbound dCas9 molecules, whose mobilities overlap. Our approach accounts for changes in DNA mobility and relates local chromatin motion to larger scale domain movement. In our experimental system, we show that compacted telomeres move faster and have a higher density of bound dCas9 molecules, but the relative motion of those molecules is more restricted than in less compacted telomeres. Correlative conventional and PALM imaging therefore improves the ability to analyze the mobility and time-averaged nanoscopic structural features of locus specific chromatin with single molecule sensitivity and yields unprecedented insights across length and time scales.     

In vitro dynamics of chromatin organization and migration

The organization of eukaryotic chromatin is not static but changes as a function of cell status during processes such as proliferation, differentiation, and migration. DNA quantification has not been used extensively to investigate chromatin dynamics in combination with cellular migration. In this context, an optimized DNA-specific, nonperturbant method has been developed for studying chromatin organization, using the fluorescent vital bisbenzimidazole probe Hoechst 33342: this property has been described by Hamori et al. (1980). Computer-assisted image analysis was used to follow migratory activity and chromatin organization of L929 fibroblasts during in vitro wound healing. Cell movements were analyzed using an optical flow technique, which consists in the calculation of the velocity field of cells and nuclear movements in the frame. This system allows the correlation of cell migration and position in the cell cycle. It makes it possible to study chromatin dynamics using a quantitative analysis of nuclear differentiation reorganization (nuclear texture) and to correlate this with migration characteristics. The present system would be of interest for studying cell-extracellular matrix interactions using differing substrates, and also the migratory response to chemotactic factors. Such a model is a prerequisite for gaining better understanding of drug action.     

Behaviors of ATP‐dependent chromatin remodeling factors during maturation of bovine oocytes in vitro

The mammalian oocyte undergoes dynamic changes in chromatin structure to reach complete maturation. However, little known is about behaviors of ATP‐dependent chromatin remodeling factors (ACRFs) during meiosis. Here, we found that respective ACRFs may differently behave in the process of oocyte maturation in the bovine. All ACRFs interacted with oocytic chromatin at the germinal vesicle (GV) stage. Mi‐2 and hSNF2H disappeared from GV‐chromatin within 1 hr of in vitro culture whereas Brg‐1 and BAF‐170 were retained throughout germinal vesicle break down (GVBD). Brg‐1 was localized on the condensed chromatin outside, whereas BAF‐170 was entirely excluded from condensed chromatin. Thereafter, Brg‐1 and BAF‐170 interacted with metaphase I and metaphase II chromosomes. These results imply that Mi‐2 and hSNF2H may initiate the meiotic resumption, and Brg‐1 and BAF‐170 may support chromatin condensation during meiosis. In addition, DNA methylation and methylation of histone H3 at lysine 9 (H3K9) seem to be constantly retained in the oocyte chromatin throughout in vitro maturation. Inhibition of ACRF activity by treatment with the inhibitor apyrase led to retarded chromatin remodeling in bovine oocytes, thereby resulting in poor development of fertilized embryos. Therefore, these results indicate that precise behaviors of ACRFs during meiosis are critical for nuclear maturation and subsequent embryonic development in the bovine. Mol. Reprod. Dev. 77: 126–135, 2010. © 2009 Wiley‐Liss, Inc.     

Protein dynamics in living cells

A protein's structure is most often used to explain its function, but function also depends on dynamics. To date, protein dynamics have been studied only in vitro under dilute solution conditions where solute concentrations are typically less than 10 g/L, yet proteins function in a crowded environment where the solute concentration can exceed 400 g/L. Does the intracellular environment affect protein dynamics? The answer will help in assessing the biological significance of the NMR-derived dynamics data collected to date. We investigated fast protein dynamics inside living Escherichia coli by using in-cell NMR. The backbone dynamics of apocytochrome b5 were quantified using {1H}-15N nuclear Overhauser effect (nOe) measurements, which characterize motions on the pico- to nanosecond time scale. The overall trend of backbone dynamics remains the same in cells. Some of the nOe values differ, but most of the differences track the increased intracellular viscosity rather than a change in dynamics. Therefore, it appears that dilute solution steady-state {1H}-15N nOe measurements provide biologically relevant information about pico- to nanosecond backbone motion in proteins.     

Ligand-specific state transitions of the membrane-bound acetylcholine receptor

We have developed a simple, direct and time-resolved method to monitor ligand-induced changes in agonist affinity of the membrane-bound acetylcholine receptor. The assay is based on the quenching of fluorescence of NBD-5-acylcholine observed upon binding of this cholinergic agonist to the receptor. Under conditions of partial saturation with the fluorescent agonist, agonists and local anesthetics but not antagonists can induce an increase in affinity of the receptor for NBD-5-acylcholine. The effect is not observed with receptor fully saturated with the fluorescent agonist. The half-life of the observed change in affinity is independent of the nature of the agonist or local anesthetic applied (t1/2 approximately 60 s at 22 degrees C). We conclude that the same state transition of the receptor can be induced by two groups of cholinergic ligands that are assumed to be non-competitive with each other and to have distinctly different modes of action. The time course of the transition is reminiscent of the slow process of desensitization observed in vivo.     

Pyrene-labeled lipids: versatile probes of membrane dynamics in vitro and in living cells

Pyrene-labeled analogs of fatty acids have been studied as probes of lipid metabolism in vitro and in cultured cells. Procedures for the synthesis of complex pyrenyl lipids and the analytical methods for their separation and quantification are described. Pyrenyl-lipids have been used to quantify the relationship between lipid structure and the rates of spontaneous lipid transfer. Modifications of these methods have also been used to monitor protein-mediated lipid transfer, lipolysis and lipid translocation across bilayer membranes. According to several criteria, pyrene dodecanoic acid has been identified as a good analog of some naturally occurring fatty acids. Digital imaging microscopy has been used to monitor the rate of accumulation of pyrenyl lipids in living cells.