Portable system for microbial sample preparation and oligonucleotide microarray analysis.

We have developed a three-component system for microbial identification that consists of (i) a universal syringe-operated silica minicolumn for successive DNA and RNA isolation, fractionation, fragmentation, fluorescent labeling, and removal of excess free label and short oligonucleotides; (ii) microarrays of immobilized oligonucleotide probes for 16S rRNA identification; and (iii) a portable battery-powered device for imaging the hybridization of fluorescently labeled RNA fragments with the arrays. The minicolumn combines a guanidine thiocyanate method of nucleic acid isolation with a newly developed hydroxyl radical-based technique for DNA and RNA labeling and fragmentation. DNA and RNA can also be fractionated through differential binding of double- and single-stranded forms of nucleic acids to the silica. The procedure involves sequential washing of the column with different solutions. No vacuum filtration steps, phenol extraction, or centrifugation is required. After hybridization, the overall fluorescence pattern is captured as a digital image or as a Polaroid photo. This three-component system was used to discriminate Escherichia coli, Bacillus subtilis, Bacillus thuringiensis, and human HL60 cells. The procedure is rapid: beginning with whole cells, it takes approximately 25 min to obtain labeled DNA and RNA samples and an additional 25 min to hybridize and acquire the microarray image using a stationary image analysis system or the portable imager.

Zero-length protein-nucleic acid crosslinking by radical-generating coordination complexes as a probe for analysis of protein-DNA interactions in vitro and in vivo.

Redox-active coordination complexes such as 1,10-phenanthroline-Cu(II) (OP-Cu) and bleomycin-Fe(III) are commonly used as "chemical nucleases" to introduce single-strand breaks in nucleic acids. Here we report that under certain conditions these complexes may crosslink proteins to nucleic acids. In vitro experiments suggest that proteins are crosslinked to DNA by a mechanism similar to dimethyl sulfate-induced crosslinking. Furthermore, we demonstrate that the OP-Cu complex can generate protein-DNA crosslinks in mammalian cells in vivo. By combining the OP-Cu crosslinking and a "protein shadow" hybridization assay we identify proteins interacting with DNA in isolated pea chloroplasts and show that this methodology can be applied to detect DNA-binding proteins on specific DNA sequences either in vitro or in vivo.

Nucleosome structural transition during chromatin unfolding is caused by conformational changes in nucleosomal DNA.

We have recently reported that certain core histone-DNA contacts are altered in nucleosomes during chromatin unfolding (Usachenko, S. I., Gavin I. M., and Bavykin, S. G. (1996) J. Biol. Chem. 271, 3831-3836). In this work, we demonstrate that these alterations are caused by a conformational change in the nucleosomal DNA. Using zero-length protein-DNA cross-linking, we have mapped histone-DNA contacts in isolated core particles at ionic conditions affecting DNA stiffness, which may change the nucleosomal DNA conformation. We found that the alterations in histone-DNA contacts induced by an increase in DNA stiffness in isolated core particles are identical to those observed in nucleosomes during chromatin unfolding. The change in the pattern of micrococcal nuclease digestion of linker histone-depleted chromatin at ionic conditions affecting chromatin compaction also suggests that the stretching of the linker DNA may alter the nucleosomal DNA conformation, resulting in a structural transition in the nucleosome which may play a role in rendering the nucleosome competent for transcription and/or replication.

Chromatin studies by DNA-protein cross-linking.

Our current level of understanding of chromatin structure was to a large extent achieved with the help of DNA-protein cross-linking. The versatile inventory of cross-linking techniques allows the identification of the contacts between DNA and proteins with a single nucleotide-single amino acid precision, to detect minor components of the complex nucleoprotein systems, to reveal the interactions of the flexible protein domains with DNA, and to assay for conformational changes in the nucleosomes.

Alterations in nucleosome core structure in linker histone-depleted chromatin.

We have previously shown that the sequential arrangement of histone-DNA contacts is essentially the same in the nucleosomal core of sea urchin sperm nuclei, where chromatin is highly condensed and repressed, and in nuclei from lily bud sepals or yeast, where chromatin is highly active in transcription and replication and is significantly or completely depleted of histone H1. However, the difference in the strength of some histone-DNA contacts has not been understood or discussed. In this work, we demonstrate that some of these differences are due to a conformational change in the nucleosomal core. We show that the nucleosomal core in linker histone-depleted chromatin is in a different conformational state compared with the nucleosomal core in folded chromatin or in isolated core nucleosomes. This conformational state is characterized by altered strengths in the histone H4 and H2A/H2B contacts with the regions of sharply bent nucleosomal DNA around sites +/-1 and +/-4 and site +/-5, respectively. We demonstrate that this conformation, which we call the "stretched nucleosome," is a general feature of unfolded linker histone-depleted chromatin and may occur during chromatin activation. Our results suggest that this nucleosome structural alteration does not depend on chromatin sources and histone variants studied in this work. In addition, we show that this alteration is reversible and is caused by the stretching of linker DNA during chromatin unfolding.

[Heterogeneity of the structural organization of the chromatin domain including the dihydrofolate reductase gene in Chinese hamster ovary cell culture]. / Geterogennost' strukturnoi organizatsii khromatina domena, vkliuchaiushchego gen digidrofolatreduktazy, v kul'ture kletok iaichnikov kitaiskogo khomiachka.

We investigated histone-DNA interactions in chromatin of amplified about 1000 fold dihydrofolate reductase (DHFR) domain in methotrexate resistant Chinese hamster ovary cell line CHOC 400. We explored chromatin structure of DHFR-gene and extended region lying 3'-downstream of the DHFR-gene, which includes two zones of DNA replication initiation, Ori-beta and Ori-gamma, and matrix attachment region (MAR). Using the method of hybridization with "protein images" we found that the yield of both core histones and histone H1 cross-linked with DNA in 5'-region of the DHFR-gene, in Ori-gamma and regions flanked from either side MAR is significantly decreased in comparison with 3'-transcribed region of the DHFR-gene, Ori-beta and MAR. It was shown previously that decreased yield of histones cross-linked with DNA is typical for 5'-region of actively transcribed genes. So, histone-DNA interactions in chromatin of the 5'-region of the house-keeping and moderately transcribed DHFR-gene, Ori-gamma and regions which flank MAR resemble those in 5'-regions of actively transcribed genes. Significant differences in amount of histones cross-linked with DNA in various parts of the DHFR-domain testify to high level of heterogeneity of chromatin structure in the domain.

Rearrangement of the histone H2A C-terminal domain in the nucleosome.

Using zero-length covalent protein-DNA crosslinking, we have mapped the histone-DNA contacts in nucleosome core particles from which the C- and N-terminal domains of histone H2A were selectively trimmed by trypsin or clostripain. We found that the flexible trypsin-sensitive C-terminal domain of histone H2A contacts the dyad axis, whereas its globular domain contacts the end of DNA in the nucleosome core particle. The appearance of the histone H2A contact at the dyad axis occurs only in the absence of linker DNA and does not depend on the absence of linker histones. Our results show the ability of the histone H2A C-terminal domain to rearrange. This rearrangement might play a biological role in nucleosome disassembly and reassembly and the retention of the H2A-H2B dimer (or the whole octamer) during the passing of polymerases through the nucleosome.

Structure of nucleosomes and organization of internucleosomal DNA in chromatin.

We have compared the mononucleosomal pattern produced by micrococcal nuclease digestion of condensed and unfolded chromatin and chromatin in nuclei from various sources with the repeat length varying from 165 to 240 base-pairs (bp). Upon digestion of isolated H1-containing chromatin of every tested type in a low ionic strength solution (unfolded chromatin), a standard series of mononucleosomes (MN) was formed: the core particle, MN145, and H1-containing, MN165, MN175, MN185, MN195, MN205 and MN215 (the indexes give an approximate length of the nucleosomal DNA that differs in these particles by an integral number of 10 bp). In addition to the pattern of unfolded chromatin, digestion of whole nuclei or condensed chromatin (high ionic strength of Ca2+) gave rise to nuclei-specific, H1-lacking MN155. Digestion of H1-lacking chromatin produced only MN145, MN155 and MN165 particles, indicating that the histone octamer can organize up to 165 bp of nucleosomal DNA. Although digestion of isolated sea urchin sperm chromatin (repeat length of about 240 bp) at a low ionic strength gave a typical "unfolded chromatin pattern", digests of spermal nuclei contained primarily MN145, MN155, MN235 and MN245 particles. A linear arrangement of histones along DNA (primary organization) of the core particle was found to be preserved in the mononucleosomes, with the spacer DNA length from 10 to 90 bp on one (in MN155) or both sides of core DNA being a multiple of about 10 bp. In MN235, the core particle occupies preferentially a central position with the length of the spacer DNA on both sides of the core DNA being usually about 30 + 60 or 40 + 50 bp. Histone H1 is localized at the ends of these particles, i.e. close to the centre of the spacer DNA. The finding that globular part of histones H3 and sea urchin sperm H2B can covalently bind to spacer DNA suggests their involvement in the organization of chromatin superstructure. Our data indicate that decondensation of chromatin is accompanied by rearrangement of histone H1 on the spacer DNA sites adjacent to the core particle and thus support a solenoid model for the chromatin superstructure in nuclei in which the core DNA together with the spacer DNA form a continuous superhelix.

[Structure of nucleosomes and organization of inter-nucleosomal DNA in chromatin]. / Struktura nukleosom i organizatsiia mezhnukleosomnoi DNK v khromatine.

We have compared mononucleosomes that were obtained by hydrolysis of chromatin micrococcal nuclease from a number of sources with the length of a nucleosomal repeat 185--245 b. p. long. For hydrolysis of chromatin isolated from nuclei, a series of nucleosomes was formed: MN145 (core particle), MN165, MN175...MN205, MN215, the lengths of their DNAs differing (by approximately 10.n b.p. where n = 1, 2, 3...) by a factor of 10. A feature of hydrolysis of chromatin in nuclei was the appearance of an additional H1-depleted MN155 particle. It is suggested that upon isolation of chromatin from nuclei, its partial decompactization takes place. This decompactization changes the character of nuclease splitting and seems to be connected with rearrangement of histone H1. These observations demonstrate that besides core particles MN145 and chromatosomes MN165, the major particles of digest of nuclei appear to be MN155, and for isolated chromatin--MN175. Unlike this standard picture, mainly MN145, MN155, MN235 and MN245 are formed upon hydrolysis of sea urchin sperm nuclei.

[Comparison of the primary structure of reconstructed minimal nucleosomes and nucleosomes isolated from the chromatin]. / Sravnenie pervichnoi organizatsii rekonstruirovannykh i vydelennykh iz khromatina minimal'nykh nukleosom.

We have reconstructed nucleosomes from a histone octamer (H2A, H2B, H3, H4)2 and DNA 146 b.p. or 2-3 thousands b.p. in length. Comparison by means of DNA-histone cross-links of the primary organization of minimal nucleosomes obtained by reconstruction or isolated from chromatin of chicken erythrocyte nuclei has demonstrated a high similarity in histone location on their DNAs. Simultaneously, there have been observed some variations in the character of interaction for all core histones with DNA on nucleosomes. Thus, the cross-link of histone H4 with DNA of a core particle at H4 sites (65), unlike H4(55) and H4(88) sites, significantly depends on the superstructure of chromatin, ionic strength of solution and the presence of denaturating agents. All these differences are expected to probe the existence of conformational isomers for core particles. (Bracketed is the distance from the histone interaction site with the DNA of the core particle to the DNA 5'-terminus.)

Primary organization of nucleosomal core particles is invariable in repressed and active nuclei from animal, plant and yeast cells.

A refined map for the linear arrangement of histones along DNA in nucleosomal core particles has been determined by DNA-protein crosslinking. On one strand of 145-bp core DNA, histones are aligned in the following order: (5') H2B25,35-H455,65-H375,85,95/H488-H2B105,11 5-H2A118-H3135,145/H2A145 (3') (the subscripts give approximate distance in nucleotides of the main histone contacts from the 5'-end). Hence, the histone tetramer (H3,H4)2 and two dimers (H2A-H2B) are arranged on double-stranded core DNA in a symmetrical and rather autonomous way: H2A/H3-(H2A-H2B)-(H3,H4)2-(H2B-H2A)-H3/H2A. The primary organization was found to be very similar in core particles isolated from repressed nuclei of sea urchin sperm and chicken erythrocytes, from active in replication and transcription nuclei of Drosophila embryos and yeast and from somatic cells of lily. These data show that (i) the core structure is highly conserved in evolution and (ii) the overall inactivation of chromatin does not affect the arrangement of histones along DNA and thus does not seem to be regulated on this level of the core structure.

[Primary organization of nucleosome core particles in active and repressed nuclei]. / Pervichnaia organizatsiia minimal'nykh nukleosom aktivnykh i repressirovannykh iader.

A refined high-resolution map for the linear arrangement of histones along DNA in the nucleosomal core particles has been determined by DNA-protein crosslinking. Histones are aligned on one strand of the 145 bp core DNA in the following order: (5') H2B25,35--H455,65--H375,85,, 95/H488--H2B105, 115--H2A118--H3135, 145/H2A145 (3') (the subscripts indicate the approximate distance in nucleotides of the main histone binding sites from the 5'-end of the core DNA). This suggests a symmetrical and rather autonomous arrangement of the histone tetramer (H3, H4)2 and two dimers (H2A, H2B) on the double-stranded core DNA: H2A/H3--(H2A, H2B)--(H3, H4)2--(H2B, H2A)--H3/H2A. The arrangement of histones on DNA was found to be very similar for the cores isolated from the repressed nuclei of sea urchin sperm and chicken erythrocytes and from the active in transcription and replication Drosophila embryo and yeast nuclei. This indicates that the core nucleosome structure is highly conserved through evolution and that the overall inactivation of chromatin does not affect the primary organization of the cores. A new binding site H2B58 was found for a sea urchin spermal variant of H2B which contains an additional basic segment within the N-terminal part of the molecule. The core isolation procedure was shown to introduce changes into the core structure which are reflected in the appearance of a new binding site H2A75.

Alignment of nucleosomes along DNA and organization of spacer DNA in Drosophila chromatin.

A series of mono- and dinucleosomal DNAs characterized by an about ten-base periodicity in the size were revealed in the micrococcal nuclease digests of Drosophila chromatin which have 180 +/- 5 base pair (bp) nucleosomal repeat. 20, 30, and 40 bp spacers were found to be predominant in chromatin by trimming DNA in dinucleosomes to the core position. Among several identified mononucleosomes (MN), MN170, MN180 and MN190 were isolated from different sources (the figures indicate the DNA length in bp). The presence of the 10, 20, and 30 bp long spacers was shown in these mononucleosomes by crosslinking experiments. The interaction of histone H3 with the spacer in the Drosophila MN180 particle was also shown by the crosslinking /5/. We conclude from these results that the 10 n bp long intercore DNA (n = 2, 3 and 4) is organized by histone H3, in particular, and together with the core DNA forms a continuous superhelix. Taken together, these data suggest that Drosophila chromatin consists of the regularly aligned and tightly packed MN180, as a repeating unit, containing 10 and 20 bp spacers at the ends of 180 bp DNA. Within the asymmetric and randomly oriented in chromatin MN180, the cores occupy two alternative positions spaced by 10 bp.

Stability of the primary organization of nucleosome core particles upon some conformational transitions.

The sequential arrangement of histones along DNA in nucleosome core particles was determined between 0.5 and 600 mM salt and from 0 to 8 M urea. These concentrations of salt and urea up to 6 M had no significant effect on the linear order of histones along DNA but 8 M urea caused the rearrangement of histones. Conformational changes in cores have been identified within these ranges of conditions by several laboratories 8-21. Also, abrupt structural changes in the cores, apparently their unfolding, were found by gel electrophoresis to occur at urea concentration, between 4 and 5 M. 600 mM salt and 6 M urea were shown to relax the binding of histones to DNA in cores but do not however release histones or some part of their molecules from DNA. It appears therefore that nucleosomal cores can undergo some conformational transitions and unfolding whereas their primary organization remains essentially unaffected. These results are consistent with a model of the core particles in which the histone octamer forms something like a helical "rim" along the superhelical DNA and histone-histone interactions beyond the "rim" are rather weak in comparison with those within the "rim".

[Interaction of histones with DNA in chromatin. A new method of covalent binding of histones to DNA available for their localization on DNA]. / Vzaimodeistvie gistonov s DNK v khromatine. Novyi metod kovalentnogo sviazyvaniia gistonov s DNK, udobnyi dlia ikh lokalizatsii na DNK.

A new method for covalent binding of histones to partially apurinized DNA was developed. Partial apurinization of DNA methylated within the composition of chromatin results in a formation of aldehyde groups interacting with the epsilon-amino groups of chromatin proteins lysine residues. The resulting Schiff's bases covalently and reversibly bind the protein molecules to DNA. This covalent binding is accompanied by a specific one-chain cleavage of DNA at the cross-linkage point in such a way that only the newly formed 5'-terminal fragment of DNA in bound to the protein. These cross-links can be stabilized via reduction of Schiff's bases by sodium borohydrate. Determination of the size of the bound DNA fragment allows to establish the localization of the cross-linkage point and the position of the protein molecule on DNA. The method of cross-linkage with a "zero length" allows to fix the immediate DNA--protein interactions and can be extensively used to study the protein--DNA interactions in cases when the epsilon-amino groups of protein lysine residues interact with DNA.