Joan-Ramon Daban

Use of the hydrophobic probe Nile red for the fluorescent staining of protein bands in sodium dodecyl sulfate-polyacrylamide gels☆

In a previous work (J.-R. Daban, M. Samsó, and S. Bartolomé, Anal. Biochem. 199, 162-168, 1991) we observed that, in the presence of the detergent sodium dodecyl sulfate (SDS), diverse types of proteins produced a high increase in the fluorescence intensity of the hydrophobic probe 9-diethylamino-5H-benzo[alpha]-phenoxazine-5-one (Nile red). This enhancement of Nile red fluorescence was observed at SDS concentrations lower than the critical micelle concentration (CMC) of this detergent in the buffer (0.025 M Tris and 0.192 M glycine, pH 8.3) currently used in SDS-polyacrylamide gel electrophoresis. This observation led us to introduce a modification in the typical (U. K. Laemmli, Nature 227, 680-685, 1970) SDS-polyacrylamide gels, in which the SDS concentration in the gel after electrophoresis is lower than the CMC of this detergent but high enough to maintain the stability of the protein-SDS complexes in the bands. The staining of these modified gels with Nile red produces very high fluorescence in the protein-SDS bands and low background fluorescence. The Nile red staining method described in this paper is very rapid (i.e., the bands can be visualized and photographed within 6 min after the electrophoretic separation) and has a high sensitivity, similar to that obtained with the covalent fluorophores rhodamine B isothiocyanate and carboxytetramethyl-rhodamine succinimidyl ester also investigated in this work. Furthermore, our quantitative estimates indicate that most of the protein bands stained with Nile red show similar values of the fluorescence intensity per unit mass.

Use of nile red as a fluorescent probe for the study of the hydrophobic properties of protein-sodium dodecyl sulfate complexes in solution.

Our results show that the noncovalent dye 9-diethylamino-5H-benzo[alpha]phenoxazine-5-one (Nile red) can be used as a fluorescent probe to study the hydrophobic properties of proteins associated with the anionic detergent sodium dodecyl sulfate (SDS). Nile red can interact with both SDS micelles and protein-SDS complexes. The enhancement of Nile red fluorescence observed with diverse types of proteins occurs at SDS concentrations lower than the critical micelle concentration of this detergent. This is also observed using the covalent fluorophore rhodamine B isothiocyanate. Additional results obtained in studies in solution show that the fluorescence intensity and the spectral characteristics of Nile red associated with different proteins complexed with SDS are very similar. These spectroscopic similarities are probably related to the equivalent synchrotron X-ray scattering results found for various protein-SDS complexes in solution. The scattering results suggest that SDS induces the formation of complexes in which the basic structural properties are independent of the different initial structures of native proteins. We speculate that Nile red is bound to regions with equivalent hydrophobic characteristics located in the uniform structures produced by the association of SDS with proteins.

Electron microscopy and atomic force microscopy studies of chromatin and metaphase chromosome structure.

The folding of the chromatin filament and, in particular, the organization of genomic DNA within metaphase chromosomes has attracted the interest of many laboratories during the last five decades. This review discusses our current understanding of chromatin higher-order structure based on results obtained with transmission electron microscopy (TEM), cryo-electron microscopy (cryo-EM), and different atomic force microscopy (AFM) techniques. Chromatin isolated from different cell types in buffers without cations form extended filaments with nucleosomes visible as separated units. In presence of low concentrations of Mg(2+), chromatin filaments are folded into fibers having a diameter of ∼ 30 nm. Highly compact fibers were obtained with isolated chromatin fragments in solutions containing 1-2mM Mg(2+). The high density of these fibers suggested that the successive turns of the chromatin filament are interdigitated. Similar results were obtained with reconstituted nucleosome arrays under the same ionic conditions. This led to the proposal of compact interdigitated solenoid models having a helical pitch of 4-5 nm. These findings, together with the observation of columns of stacked nucleosomes in different liquid crystal phases formed by aggregation of nucleosome core particles at high concentration, and different experimental evidences obtained using other approaches, indicate that face-to-face interactions between nucleosomes are very important for the formation of dense chromatin structures. Chromatin fibers were observed in metaphase chromosome preparations in deionized water and in buffers containing EDTA, but chromosomes in presence of the Mg(2+) concentrations found in metaphase (5-22 mM) are very compact, without visible fibers. Moreover, a recent cryo-electron microscopy analysis of vitreous sections of mitotic cells indicated that chromatin has a disordered organization, which does not support the existence of 30-nm fibers in condensed chromosomes. TEM images of partially denatured chromosomes obtained using different procedures that maintain the ionic conditions of metaphase showed that bulk chromatin in chromosomes is organized forming multilayered plate-like structures. The structure and mechanical properties of these plates were studied using cryo-EM, electron tomography, AFM imaging in aqueous media, and AFM-based nanotribology and force spectroscopy. The results obtained indicated that the chromatin filament forms a flexible two-dimensional network, in which DNA is the main component responsible for the mechanical strength observed in friction force measurements. The discovery of this unexpected structure based on a planar geometry has opened completely new possibilities for the understanding of chromatin folding in metaphase chromosomes. It was proposed that chromatids are formed by many stacked thin chromatin plates oriented perpendicular to the chromatid axis. Different experimental evidences indicated that nucleosomes in the plates are irregularly oriented, and that the successive layers are interdigitated (the apparent layer thickness is 5-6 nm), allowing face-to-face interactions between nucleosomes of adjacent layers. The high density of this structure is in agreement with the high concentration of DNA observed in metaphase chromosomes of different species, and the irregular orientation of nucleosomes within the plates make these results compatible with those obtained with mitotic cell cryo-sections. The multilaminar chromatin structure proposed for chromosomes allows an easy explanation of chromosome banding and of the band splitting observed in stretched chromosomes.

Association of nucleosome core particle DNA with different histone oligomers: Transfer of histones between DNA-(H2A,H2B) and DNA-(H3,H4) complexes

In non-denaturing low ionic strength gels, the titration of core DNA with H2A,H2B produces five well-defined bands. Quantitative densitometry and cross-linking experiments indicate that these bands are due to the successive binding of H2A,H2B dimers to core DNA. Only two bands are obtained with DNA-(H3,H4) samples. The slower of these bands is broad and presumably corresponds to two complexes containing one and two H3,H4 tetramers, respectively. In gels of higher ionic strength, DNA-(H2A,H2B) samples produce an ill-defined band, suggesting that the lifetime of the complexes containing H2A,H2B is relatively short. However, the low intensity of the free DNA band observed in these gels indicates that most of the DNA is associated with H2A,H2B. In agreement with this, our results obtained using different techniques (sedimentation, cross-linking, trypsin and nuclease digestions, and thermal denaturation) demonstrate that the association of H2A,H2B with core DNA occurs in free solution in both the absence and presence of NaCl (0.1 to 0.2 M). The low mobilities of DNA-(H2A,H2B) complexes, together with sedimentation and DNase I digestion results, indicate that the DNA in these complexes is not folded into the compact structure found in the core particle. Furthermore, non-denaturing gels have been used to study the dynamic properties of DNA-(H2A,H2B) and DNA-(H3,H4) complexes in 0.2 M-NaCl. Our results show that: (1) H2A,H2B and H3,H4 can associate, respectively, with DNA-(H3,H4) and DNA-(H2A,H2B) to produce complexes containing the four core histones; (2) DNA-(H2A,H2B) and DNA-(H3,H4) are able to transfer histones to free core DNA; (3) an exchange of histone pairs takes place between DNA-(H2A,H2B) and DNA-(H3,H4) and produces complexes with the same histone composition as that of the normal nucleosome core particle; and (4) although both histone pairs can exchange, histones H2A,H2B show a higher tendency than H3,H4 to migrate from one incomplete core particle to another. The complexes produced in these reactions have the same compact structure as reconstituted core particles containing the four core histones. Our kinetic results are consistent with a reaction mechanism in which the transfer of histones involves direct contacts between the reacting complexes. The possible participation of these spontaneous reactions on the mechanism of nucleosome assembly is discussed.

Fluorescent labeling of proteins with Nile red and 2-methoxy-2,4-diphenyl-3(2H)-furanone: Physicochemical basis and application to the rapid staining of sodium dodecyl sulfate polyacrylamide gels and Western blots

The fluorescent hydrophobic dye Nile red allows the rapid, sensitive, and general staining of proteins in sodium dodecyl sulfate (SDS)‐polyacrylamide gels. Nile red staining does not preclude further electroblotting of protein bands onto polyvinylidene difluoride (PVDF) membranes. The resulting Western blot can be stained with the covalent fluorescent dye 2‐methoxy‐2,4‐diphenyl‐3(2H)‐furanone (MDPF) using a simple procedure. MDPF staining allows further N‐terminal microsequencing and immunodetection of specific bands. This review considers the physicochemical, structural, and analytical studies that have led to the development of Nile red and MDPF staining methods. The usefulness of these procedures is discussed in comparison to other currently available fluorescent and nonfluorescent protein detection methods.

Rapid fluorescent staining of histones in sodium dodecyl sulfate-polyacrylamide gels

The increase in the fluorescence intensity of 1-anilinonaphthalene-8-sulfonate (ANS) produced by core histones is higher than that produced by very lysine-rich histones (H1 and H5). In the presence of the anionic detergent sodium dodecyl sulfate (SDS) the enhancement of ANS fluorescence caused by these two groups of histones is roughly the same, but much lower than that observed for core histones in the absence of this detergent. However, the increase of ANS fluorescence produced by histone-SDS complexes is high enough to use it for the staining of these proteins separated in SDS-polyacrylamide gels. Histone bands are stained with ANS after electrophoresis and visualized by transillumination of the gel with a uv light source. The method described in this work allows the rapid detection of less than 0.5 microgram of histone per band.

Green‐light transilluminator for the detection without photodamage of proteins and DNA labeled with different fluorescent dyes

The excitation spectra of Nile red and SYPRO red, two currently used dyes for the fluorescent staining of protein bands in sodium dodecyl sulfate (SDS)‐polyacrylamide gels, show an excitation peak in the UV region and another in the visible region (maximum at about 550 nm). Ethidium bromide and other intercalating dyes, e.g. propidium iodide, ethidium dimers, and benzoxazolium‐4‐quinolinium dimer‐3 (YOYO), used for the fluorescent staining of DNA bands in agarose gels also show an excitation peak in the same region of the visible spectrum. We have designed and constructed a green‐light transilluminator with an emission maximum at 542 nm. This visible transilluminator allows the detection of protein bands stained with Nile red and SYPRO red with the same sensitivity obtained with a 300 nm UV transilluminator. The green‐light transilluminator also allows the detection of about 2 ng of DNA per band in gels stained with ethidium bromide and the other intercalating dyes indicated above. In contrast to the UV transilluminators, the green‐light transilluminator does not produce photodamage of DNA even after long exposures (10 min). This makes this transilluminator very useful for preparative work. Furthermore, the green‐light transilluminator does not require UV safety equipment and, consequently, it can be very convenient for teaching laboratories.

Electrophoresis of Chromatin on Nondenaturing Agarose Gels Containing Mg2+ SELF-ASSEMBLY OF SMALL CHROMATIN FRAGMENTS AND FOLDING OF THE 30-nm FIBER

We show that nondenaturing agarose gels can be used for the study of the structure and dynamic properties of native (uncross-linked) chromatin. In gels containing 1.7 mM Mg, chicken erythrocyte chromatin fragments having from about 6 to 50 nucleosomes produce well defined bands. These bands have an electrophoretic mobility that decreases only slightly with molecular weight. This surprising behavior is not observed in low ionic strength gels. Fragments with less than 6 nucleosomes and low content of histones H1-H5 give rise to broad bands in gels with Mg. In contrast, fragments containing only 3-4 nucleosomes but with the normal H1-H5 content are able to form associated structures with a mobility similar to that observed for high molecular weight chromatin. Electron microscopy results indicate that the associated fragments and the fragments of higher molecular weight show similar electrophoretic properties because they become very compact in the presence of Mg and form cylindrical structures with a diameter of 33 nm. Our results suggest that the interactions involved in the self-assembly of small fragments are the same that direct the folding of larger fragments; in both cases, the resulting compact chromatin structure is formed from a basic element containing 5-7 nucleosomes.

Irregular orientation of nucleosomes in the well-defined chromatin plates of metaphase chromosomes.

In previous studies with partially denatured metaphase chromosomes, we detected platelike structures instead of the chromatin fibers currently considered in different structural models for chromosomes. Here we have observed that dilution of compact metaphase chromosomes with hyposmotic solutions can transform whole chromatids into extended plates formed by many layers. Since this treatment is soft and it does not change the ionic conditions, these observations indicate that native chromosomes are formed by stacked plates. This strengthens our hypothesis about the multilayer structure of chromosomes, which was originally based on results obtained using stronger denaturing conditions. We have investigated the structure of plates emanated from chromosomes using electron tomography. Our three-dimensional reconstructions demonstrate conclusively that the surface of the plates is very smooth and do not show repetitive structures supporting any regular organization of nucleosomes; even the nucleosomes in plate edges show irregular orientations. Furthermore, we have used polarizing microscopy for the study of whole chromosomes in metaphase cells in aqueous solution. Our results show that condensed chromosomes are not birefringent under structuring ionic conditions similar to those used with plates. This observation is incompatible with the existence of parallel columns of nucleosomes within chromosomes. In summary, we have not detected any regular orientation of nucleosomes, but at the same time, our results indicate that the bulk of chromatin in native chromosomes is organized forming very well-defined plates, in which the nucleosomes of the successive layers are interdigitated. Presumably, this dense structure is required for safe transfer of DNA to daughter cells.

Inhibition of peroxyoxalate chemiluminescence by intercalation of fluorescent acceptors between DNA bases.

Abstract— We have examined the ability of different fluorescent DNA dyes to become chemically excited by the peroxyoxalate chemiluminescent reaction. The intercalating dyes ethidium bromide and propidium iodide, and the bis‐intercalating dyes ethidium homodimer‐1, benzoxazolium‐4‐pyridinium dimer‐1 and benzoxazolium‐4‐quinolinium dimer‐1, exhibit an intense Chemiluminescence when they are excited by the bis(2,4,6‐trichlorophenyl)oxalate (TCPO)‐H2O2 reaction in the absence of DNA. However, the Chemiluminescence of these dyes is very low when they are bound to double‐stranded DNA (dsDNA). In contrast, the minor groove‐binding dye Hoechst 33258 excited by the TCPO‐H2O2 reaction shows approximately the same Chemiluminescence intensity when it is free in solution or complexed with dsDNA. Structural alterations or partial dissociation of dsDNA‐bis‐intercalating dye complexes produced by the addition of acetone, NaCl, MgCl2 or the cationic surfactant cetyltrimethylammonium bromide increases the Chemiluminescence intensity. A moderate Chemiluminescence intensity is observed when bis‐intercalating dyes are complexed with single‐stranded DNA. Our results indicate that the energy from the intermediates produced in the peroxyoxalate chemiluminescent reaction cannot be efficiently transferred to fluorescent dyes complexed with DNA; chemiexcitation is almost completely inhibited when dyes are buried in the dsDNA structure by intercalation between the base pairs.