DNA-protein interactions in nucleosomes and in chromatin. Structural studies of chromatin stabilized by ultraviolet-light induced crosslinking.

Crosslinking induced by ultraviolet light irradiation at 254 nm has been utilized to investigate the structure of chromatin and isolated nucleosomes. The results presented here imply that the four core histones, as well as histone H1, have reactive groups within a bond length of the DNA bases. In nucleosomes depleted of H1, all of the core histones react similarly with the DNA and form crosslinks. In chromatin, the rate of crosslinking of all histones to DNA is essentially similar. Comparison of mononucleosomes, dinucleosomes and whole chromatin shows that the rate of crosslinking increases significantly with increasing number of connected nucleosomes. These differences in the rate of crosslinking are interpreted in terms of interactions between neighbouring nucleosomes on the chromatin fiber, which are absent in an isolated mononucleosome.     

Stability of DNA-protein interactions in chromatin fractions with different sensitivity to nucleases

It was revealed by means of nucleoprotein-celite-chromatography that DNA-protein interactions in the chromatin fraction sensitive to micrococcal nuclease and DNase II are weaker that in the resistant one. The micrococcal nuclease destroys the DNA-matrix bond resistant to salt-urea, while DNase II does not change the DNA-matrix integrity. Tightness of the DNA-protein interactions is weakened by the increasing chromatin fragmentation, but does not depend on the size of chromatin particles.     

Thymine methyls and DNA-protein interactions.

Evidence is summarized showing that thymine methyls are as important in the recognition of specific sequences by proteins as are the more widely recognized hydrogen bonding sites of bases in the major groove (1). Strongest evidence has come from experiments using functional group mutagenesis (2) in which thymines in a specific recognition sequence (e.g., promoters, operators and restriction sites) are replaced by oligonucleotide synthesis with methyl-free uracil or cytosine and 5-methylcytosine. Such experiments have shown that thymine methyls can provide contact points via van der Waals interactions with amino acid side chains of specific DNA binding proteins. Actual contact between a thymine methyl and carbons of a glutamine side chain has been observed in a cocrystal of the phage 434 repressor and its operator by X-ray analysis. The issue of why thymine occurs in DNA is discussed in light of these findings.     

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.     

Stable DNA-protein complexes in eukaryotic chromatin

Demembranized sperm and somatic nuclei of mammalian origin were extracted with high salt/urea/2-mercaptoethanol, treated with detergents and purified in CsCl density gradients to isolate DNA. Under these conditions a protein component still remained bound to DNA. This stable DNA-protein complex could be reduced to an oligodeoxynucleotide-peptide complex by extensive sequential digestions with DNase I and Pronase E. Chemical and enzymatic treatments of this complex indicated the presence of a phosphoester bond between DNA and a hydroxyamino acid. Two-dimensional tryptic peptide mapping revealed a remarkable similarity among the covalently linked protein components in all types of chromatin studied. These maps differed from the maps of mammalian topoisomerases I and II.     

Studying DNA-protein interactions using NMR.

NMR spectroscopy is emerging as a powerful tool in molecular biology and biotechnology; one aspect of which is the use of one- and two-dimensional NMR methodologies to investigate the interactions of proteins with DNA. The dynamic and structural information which NMR can provide, on the changes in conformation and molecular flexibility, complements X-ray crystallography data and enables mechanistic models of DNA-protein interactions to be formulated.     

Polyamines alter sequence-specific DNA-protein interactions.

The polyamines are abundant biogenic cations implicated in many biological processes. Despite a plethora of evidence on polyamine-induced DNA conformational changes, no thorough study of their effects on the activities of sequence-specific DNA binding proteins has been performed. We describe the in vitro effects of polyamines on the activities of purified, representative DNA-binding proteins, and on complex protein mixtures. Polyamines at physiological concentrations enhance the binding of several proteins to DNA (e.g. USF, TFE3, Ig/EBP, NF-IL6, YY1 and ICP-4, a herpes simplex virus gene regulator), but inhibit others (e.g. Oct-1). The degree of enhancement correlates with cationic charge; divalent putrescine is ineffective whereas tetravalent spermine is more potent than trivalent spermidine. Polyamine effects on USF and ICP-4 result from increased rate of complex formation rather than a decreased rate of dissociation. DNAse I footprint analysis indicated that polyamines do not alter DNA-protein contacts. Polyamines also facilitate formation of complexes involving binding of more than one protein on a DNA fragment.     

Rearrangements of DNA-protein interactions in animal cells coupled with cellular growth-quiescence transitions.

Overall DNA-protein interactions in animal cells undergo drastic changes coupled with cellular transitions from quiescence to growth and reversely as revealed by nucleoprotein-Celite chromatography. DNA of chromatin was found to exist in one of the two sharply distinct alternative forms, namely, either tightly or weakly bound to protein moiety. These forms are specific for cycling and quiescent cells, respectively. The tight DNA-protein interactions characterize all cycling cells independent of the cell cycle phase. Transition of DNA of cycling cells from one form to another was observed as a result of treatment of isolated nuclei with DNase I.     

Laminar flow cells for single-molecule studies of DNA-protein interactions

Microfluidic flow cells are used in single-molecule experiments, enabling measurements to be made with high spatial and temporal resolution. We discuss the fundamental processes affecting flow cell operation and describe the flow cells in use at present for studying the interaction of optically trapped or mechanically isolated, single DNA molecules with proteins. To assist the experimentalist in flow cell selection, we review the construction techniques and materials used to fabricate both single- and multiple-channel flow cells and the advantages of each design for different experiments.     

Radiolysis of chromatin extracted from cultured mammalian cells: formation of DNA-protein cross links.

Chromatin extracted from Chinese hamster lung fibroblasts has been examined for the formation of radiation-induced DNA-protein cross links, using a membrane filter assay. The relative efficiencies of the aqueous radical intermediates, OH., eaq- and O2-, were investigated. Cross links were found in gamma-irradiated isolated chromatin and in chromatin irradiated in the cell before isolation. When isolated chromatin was irradiated under conditions in which the chromosomal proteins were dissociated from the DNA, no cross links were detectable. The most efficient radical for the production of cross links in irradiated, isolated chromatin was found to be the hydroxyl radical, whereas, the superoxide radical was essentially ineffective. For chromatin irradiated in the cell before isolation, the greatest effect was seen for cells irradiated in an atmosphere of nitrous oxide, suggesting the hydroxyl radical may be involved in the formation of cross links in intact cells also. The formation of cross links in chromatin irradiated in cells before isolation was considerable less efficient than in irradiated, isolated chromatin.     

Fluorescence-based methods in the study of protein-protein interactions in living cells

Multiprotein complexes partake in nearly all cell functions, thus the characterization and visualization of protein-protein interactions in living cells constitute an important step in the study of a large array of cellular mechanisms. Recently, noninvasive fluorescence-based methods using resonance energy transfer (RET), namely bioluminescence-RET (BRET) and fluorescence-RET (FRET), and those centered on protein fragment complementation, such as bimolecular fluorescence complementation (BiFC), have been successfully used in the study of protein interactions. These new technologies are nowadays the most powerful approaches for visualizing the interactions occurring within protein complexes in living cells, thus enabling the investigation of protein behavior in their normal milieu. Here we address the individual strengths and weaknesses of these methods when applied to the study of protein-protein interactions.     

DNA-protein interactions and chromosome banding

Pancreatic DNase I was used as a probe to study DNA-protein interactions in condensed and extended chromatin fractions isolated from Chinese hamster liver, and in human lymphocyte and mouse L cell metaphase chromosomes in situ. By studying the rate of digestion of chromatin DNA by DNase, we have previously shown that DNA in extended chromatin is more sensitive to DNase digestion than that in condensed chromatin. In the current investigation, we have examined whether this differential sensitivity of the chromatin fractions to DNase is due to differences in protein binding to DNA or differences in the degree of chromatin condensation. By “decondensing” the condensed chromatin and comparing its rate of digestion to that of untreated condensed and extended chromatin, it was found that differences in the degree of binding of proteins to DNA rather than the degree of condensation of the chromatin primarily determines the sensitivity of each fraction to DNase. Extraction of the various classes of chromosomal proteins, followed by DNase digestion of the residual chromatin revealed that both the histone and non-histone proteins protect the DNA in the chromatin fractions from DNase attack; however, the more tightly associated non-histones appear to be specifically responsible for the differential sensitivity of the chromatin fractions to DNase digestion. These non-histones may be more tightly associated with the DNA in condensed than in extended chromatin, thereby protecting the DNA in condensed chromatin against DNase attack to a greater extent than that in extended chromatin. When metaphase chromosomes were briefly digested with DNase in situ and subsequently stained with Feulgen reagent, incontrovertible C-banding and some G-banding was obtained. This DNaseinduced banding demonstrates that the DNA in C-band and possibly G-band regions is less accessible to DNase than that in the interband regions, and our biochemical data suggest that this differential accessibility is caused by differential DNA-protein binding such that the non-histones are more tightly coupled to the DNA in the G- and C-band regions than they are in the interbands. Differences in the binding of non-histones to DNA in different segments of the metaphase chromosome may be involved in the mechanism of G- and C-banding.     

Inducible DNA-protein interactions of the murine kappa immunoglobulin enhancer in intact cells: comparison with in vitro interactions.

The large intron of the kappa immunoglobulin gene contains a cis-acting enhancer element, which is important in the tissue-specific expression of the gene. We have confirmed the binding activity of a sequence-specific factor present in lymphoid extracts derived from cell lines expressing, or induced to express, the kappa gene. We have extended these studies to show the binding activity is present in normal activated splenic B cells as well as lambda producing cells, and have demonstrated by DNAse footprint analysis full protection of a sequence containing the 11 bp homology to the SV-40 core enhancer. We have compared these in vitro binding studies with an analysis of protein-DNA interactions in intact murine cell lines using genomic sequencing techniques. We demonstrate significant alterations in DMS reactivity of DNA in the murine 70Z/3 cell line after it is induced to kappa expression. These alterations occur at guanine residues which are part of the the 11 bp core sequence, and are identical to those observed in cells constitutively expressing kappa. This provides direct evidence for the induced binding of the tissue specific factor to intact chromatin. In intact chromatin we also observed significant alteration in the reactivity of a guanine, 3' of the core sequence, which is part of a potential secondary DNA structure, and protection of four residues that are part of a region homologous to the heavy chain enhancer.