DIGITAL IMAGE ANALYSIS OF CHROMATIN FIBRE PHENOTYPE AFTER ‘IN SITU’ DIGESTION WITH RESTRICTION ENDONUCLEASES

Restriction Endonucleases (REs) may recognize, cleave and remove DNA from fixed chromatin producing specific chromosome banding patterns. However, the modifications produced in the chromatin fibre are not easy to evaluate and compare. The aim of the present investigation was to visualize differences resulting in the texture of the chromatin fibre from metaphase chromosomes after each digestion using digital image analysis (DIA) facilities. To this purpose, metaphase chromosomes derived from a L-929 mouse cell line were digested with different REs (AluI,HpaII andHaeIII). Since light microscopy does not permit the observation of the chromatin fibre, DIA was performed on digitalized images of metaphase chromosomes under electron microscopy. The application of a LUT (Look Up Table) within the DIA software assigns a colour to each grey level of a digital image. The results obtained using a particular LUT, which permits the discrimination of specific chromatin fibre phenotypes resulting from each digestion, are reported and compared with those obtained under the light microscope.     

Electron microscopy and biochemical analysis of mouse metaphase chromosomes after digestion with restriction endonucleases

Electron microscopy (EM) of whole mounted mouse chromosomes, light microscopy (LM), and agarose gel electrophoresis of DNA were used to investigate the cytological effect on chromosomes of digestion with the restriction endonucleases (REs) AluI, HinfI, HaeIII and HpaII. Treatment with AluI produces C-banding as seen by LM, cuts DNA into small fragments, and reduces the density of centromeres and disperses the chromatin of the arms as determined by EM. Treatment with HinfI produces C-banding, cuts DNA into slightly larger fragments than does AluI and increases the density of centromeres and disperses the fibres in the chromosomal arms. Exposure to HaeIII produces G- + C-banding, cuts the DNA into large fragments, and results in greater density of centromeres and reduced density of arms. Finally HpaII digestion produces G-like bands, cuts the DNA into the largest fragments found and results in greater density of centromeres and the best preservation of chromosomal arms detected by EM. These results provide evidence for: (1) REs producing identical effects in the LM (AluI and HinfI) produce different effects in the EM. (2) All enzymes appear to affect C-bands but while REs such as AluI reduce the density of these regions, other enzymes such as HpaII, HaeIII or HinfI increase their density. Conformational changes in the chromatin could explain this phenomenon. (3) The appearance of chromosomes in the EM is related to the action of REs on isolated DNA. The more the DNA is cut by the enzyme, the greater the alteration of the chromosomal ultrastructure.     

Dense chromatin plates in metaphase chromosomes

In a previous work we observed multilayered plate-like structures surrounding partially denatured HeLa chromosomes at metaphase ionic conditions. This unexpected finding has led us to carry out an extensive investigation of these structures. Our results show that plates can also be found in metaphase chromosomes from chicken lymphocytes. We have used atomic force microscopy (AFM) to image and investigate the mechanical properties of plates in aqueous solution. Plates are thin (~6.5 nm each layer) but compact and resistant to penetration by the AFM tip: their Young’s modulus is ~0.2 GPa and the stress required for surface penetration is ~0.03 GPa in the presence of Mg²⁺ (5–20 mM). Low-ionic strength conditions produce emanation of chromatin fibers from the edges of uncrosslinked plates. These observations and AFM results obtained applying high forces indicate that the chromatin filament is tightly tethered inside the plates. Images of metal-shadowed plates and cryo-electron microscopy images of frozen-hydrated plates suggest that nucleosomes are tilted with respect to the plate surface to allow an interdigitation between the successive layers and a thickness reduction compatible with the observed plate height. The similarities between denatured plates from chicken chromosomes and aggregates of purified chromatin from chicken erythrocytes suggest that chromatin has intrinsic structural properties leading to plate formation. Scanning electron micrographs and images obtained with the 200-kV transmission microscope show that plates are the dominant component of compact chromatids. We propose that metaphase chromosomes are formed by many stacked plates perpendicular to the chromatid axis.     

Nucleosomes in metaphase chromosomes.

Previous studies of the structure of metaphase chromosomes have relied heavily on electron micrography and have revealed the existence of a 10-nm unit fiber that is thought to generate the native 23-30-nm fiber by higher order folding. The structural relationship of these metaphase fibers to the interphase fiber remains obscure. Recent studies on the digestion of interphase chromatin have revealed the existence of a regularly repeating subunit of DNA and histone, the nucleosome that generates the appearance of 10-nm beads connected by a short fiber of DNA seen on electron micrographs. It was therefore of interest to probe the structure of the metaphase chromosome for the presence of nucleosomal subunits. To this end metaphase chromosomes were prepared from colchicine-arrested cultures of mouse L-cells and were subjected to digestion with stayphylococcal nuclease. Comparison of the early and limit digestion products of metaphase chromosomes with those obtained from interphase nuclei indicates that although significant morphologic changes occur within the chromatin fiber during mitosis, the basic subunit structure of the chromatin fiber is retained by the mitotic chromosome.     

Diffuse kinetochores and holokinetic anaphase chromatin movement during mitosis in the hemipteran Agallia constricta (leafhopper) cell line AC-20

Mitosis in the hemipteran Agallia constricta (leafhopper) cell line AC-20 was examined by light microscopy of living and fixed cells. During early prometaphase the numerous small (0.30-3.0-microns) chromosomes appear as discrete units that lack a primary constriction. However, by late prometaphase the chromosomes are tightly packed at the spindle equator and are no longer clearly resolvable as individuals. When viewed from the side the metaphase chromatin appears as a 2-3-microns wide band that spans the width of the spindle; when viewed from the pole it appears as a fenestrated disk. The metaphase chromatin splits at anaphase into two sister chromatin plates, each of which exhibits holokinetic poleward movement, i.e., all parts of each plate move as a single unit with the same velocity. In many early-to-mild anaphase cells the separating sister plates are connected by chromatin-containing bridges that break as anaphase progresses. Ultrastructural analyses of serial thick and thin sections from cells fixed by conventional, OsO4/KFeCN, or high pressure rapid freezing methods, reveal that by metaphase all of the chromosomes are interconnected to form a large, irregularly shaped fenestrated disk of chromatin. Similar analyses reveal that adjacent chromatids remain interconnected throughout anaphase. Each disk of metaphase and anaphase chromatin contains numerous kinetochores recessed within its pole-facing surface. Kinetochores consist of a fine, faintly staining fibrillar material arranged along the chromatin surface as thin (0.1-0.3 micron dia.) rods varying considerably (0.15-2.3 microns) in length. From these observations we conclude that the polycentric metaphase chromatin of A. constricta, and its holokinetic behavior during anaphase, arises from the aggregation or cohesion of smaller prometaphase chromosomes, each of which contains a single, diffuse kinetochore.     

Spectral karyotyping, a 24-colour FISH technique for the identification of chromosomal rearrangements

 Spectral karyotyping (SKY) is a new fluorescence in situ hybridisation (FISH) technique that refers to the molecular cytogenetic analysis of metaphase preparations by means of spectral microscopy. For SKY of human metaphase chromosomes, 24 chromosome-specific painting probes are used in just one FISH experiment. The probes are labelled by degenerate oligonucleotide-primed PCR using three fluorochromes and two haptens. Each probe is differentially labelled with one, two, three or four fluorescent dyes, resulting in a unique spectral signature for every chromosome. After in situ hybridisation and immunodetection, a spectral image is acquired using a conventional fluorescence light microscope equipped with a custom-designed triple-bandpass filter and the SpectraCube, which is able to retrieve spectral information for every pixel in a digital CCD image. The 24-colour display and chromosome classification are based on the unique emission spectra of the chromosomes. Together with chromosome banding information from an inverted DAPI or a G-banded metaphase, a comprehensive overview of chromosomal aberrations is presented. Accepted: 3 July 1997     

Periodicity of DNA folding in higher order chromatin structures.

Each level of DNA folding in cells corresponds to a distinct chromatin structure. The basic chromatin units, nucleosomes, are arranged into solenoids which form chromatin loops. To characterize better the loop organization of chromatin we have assumed that the accessibility of DNA inside these structures is lower than on the outside and examined the size distribution of high mol. wt DNA fragments obtained from cells and isolated nuclei after digestion with endogenous nuclease or topoisomerase II. The largest discrete fragments obtained contain 300 kbp of DNA. Their further degradation proceeds through another discrete size step of 50 kbp. This suggests that chromatin loops contain approximately 50 kbp of DNA and that they are grouped into hexameric rosettes at the next higher level of chromatin structure. Based upon these observations a model by which the 30 nm chromatin fibre can be folded up into compact metaphase chromosomes is also described.     

Highly compact folding of chromatin induced by cellular cation concentrations. Evidence from atomic force microscopy studies in aqueous solution

We have performed a very extensive investigation of chromatin folding in different buffers over a wide range of ionic conditions similar to those found in eukaryotic cells. Our results show that in the presence of physiological concentrations of monovalent cations and/or low concentrations of divalent cations, small chicken erythrocyte chromatin fragments and chromatin from HeLa cells observed by transmission electron microscopy (TEM) show a compact folding, forming circular bodies of approximately 35 nm in diameter that were found previously in our laboratory in studies performed under very limited conditions. Since TEM images are obtained with dehydrated samples, we have performed atomic force microscopy (AFM) experiments to analyze chromatin structure in the presence of solutions containing different cation concentrations. The highly compact circular structures (in which individual nucleosomes are not visible as separated units) produced by small chromatin fragments in interphase ionic conditions observed by AFM are equivalent to the structures observed by TEM with chromatin samples prepared under the same ionic conditions. We have also carried out experiments of sedimentation and trypsin digestion of chromatin fragments; the results obtained confirm our AFM observations. Our results suggest that the compaction of bulk interphase chromatin in solution at room temperature is considerably higher than that generally considered in current literature. The dense chromatin folding observed in this study is consistent with the requirement of compact chromatin structures as starting elements for the building of metaphase chromosomes, but poses a difficult physical problem for gene expression during interphase.     

Selective digestion of mouse chromosomes with restriction endonucleases. I. Scaffold-like structures and bands by electron microscopy

Mouse chromosomes from the L929 cell line have been digested with the restriction endonuclease HaeIII and analyzed by electron microscopy. Results show a different effect of the enzyme depending on the conditions of the digestion. Thus, while chromosomes digested in suspended cells show a double scaffold-like structure per chromatid, a similar banding to that found in chromosomes treated for light microscopy is obtained when chromosomes are digested on grids. Some aspects concerning the capacity of the cleaved DNA to be removed from the chromatin are discussed.     

Cell-cycle-dependent dissociation of histone H1 from chromatin in nuclei of P. polycephalum.

The dissociation curves of histone H1 from chromatin in interphase and metaphase nuclei from Physarum polycephalum have been determined using CaCl2 as dissociating agent. H1 is less strongly bound to metaphase chromosomes than to interphase chromatin. However, no differences could be detected in the binding of Hl to early S, late S or G2 phase chromatin. The number of CaCl2 molecules involved in binding one H1 molecule to chromatin was reduced from 5 in interphase to 4 in metaphase. The non-electrostatic contribution to the free-energy of binding was small in both cases. A comparison of the binding properties of H1 to sheared chromatin, native chromatin and metaphase chromosomes suggests that the electrostatic binding functions of H1 are completely satisfied within the nucleosome and that further electrostatic interactions are not involved in folding the nucleosomal fibre into the 300 A "solenoid" or the more tightly folded metaphase chromosome.     

A scanning electron microscopy study of double minutes from a human tumour cell line

Double minutes from a human tumour cell line were examined in intact metaphase spreads using scanning electron microscopy. They were discrete, acentromeric, compact spheres of chromatin fibres similar to the chromatin of the metaphase chromosomes within the same cells. They were closely associated with the telomeres and chromatids of the metaphase chromosomes.     

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.     

Stabilization of chromonema--one of the highest compactization levels--by visible light in the presence of ethidium bromide

This paper deals with the ultrastructure and behavior of interphase chromatin and metaphase chromosomes of L-197 culture cells under experimental conditions, which help to reveal the chromonemal level of chromosomal structure after the treatment of living cells with 0.1% Triton X-100 and 3 mM CaCl2. In these conditions, the chromonemata can be seen as dense chromatin fibers with thickness about 100 nm. Such chromosomes, whose chromonemal substructure after the treatment with hypotonic solution (10 mM Tris-HCl), look like loose chromosomal bodies composed of elementary 30 nm DNP fibrils. On the other hand, if chromosomes, in which chromonemal levels were revealed by 3 mM CaCl2, were treated with etidium bromide and then illuminated by light with length wave about 460 nm, no chromosomal decondensation in hypotonic conditions is observed. Chromonemata in chromosomes stabilized by light retain their density and dimensions. It is very important that chromonemata in stabilizated chromatin of metaphase chromosome keep specific connections between themselves and also general trend in their composition inside the chromosome. Thus, we have found conditions for observation of chromonemal elements in metaphase chromosome, providing the possibility for future three-dimensional investigation of chromonema packing in mitotic chromosomes.     

The ultrastructure of G- and C-banded chromosomes

A method of visualizing chromosome bands by electron microscopy has been used to investigate the fine structural organization of G- and C-banded chromosomes. The following information has been obtained:

1. 1. G-bands, produced by trypsinization, were electron dense regions of highly packed chromatin fibres separated by regions in which the chromatin fibres were much less densely packed (interbands).

2. 2. Several degrees of chromatin dispersion were apparent in trypsinized chromosomes. Such dispersion was not a prerequisite for the initial visualization of G-bands, however the progressive pattern of dispersion indicated that the bands were relatively more resistant to dispersion than the interbands.

3. 3. After fixation and trypsinization, individual chromatin fibres measured 250 Å in diameter and appeared morphologically similar to control chromatin fibres seen by whole mount electron microscopy.

4. 4. In trypsinized chromosome complements, the chromosomes often appeared to be interconnected to one another by chromatin fibres. The evidence indicates that these interchromosomal fibres are artefacts produced by the overlapping of dispersed chromatin fibres.

5. 5. When the same metaphase chromosome was observed by both light and electron microscopy, some of the light microscopic G-bands were represented by two or more ultrastructural bands. The number of bands seen in metaphase chromosomes by electron microscopy appears to approach the increased number of bands generally seen in prometaphase chromosomes by light microscopy.

6. 6. C-banding methods (NaOH treatment or overtrypsinization) resulted in the extraction of variable amounts of chromatin from the non C-band regions of the chromosomes, however the constitutive heterochromatin remained highly condensed and resistant to extraction. This result supports the hypothesis that the mechanism of C-banding involves the selective loss of non C-band chromatin.

     

Coiled Supercoiled DNA in Critical Point Dried and Thin Sectioned Human Chromosome Fibres

SUPERCOILING of the DNA double helix in the deoxynucleo-histone fibril (100 Â in diameter with a pitch of 120 Â) has been well documented by X-ray diffraction^1–3. The main structural element of eukaryotic metaphase chromosomes and inactive interphase chromatin, however, is a long, irregularly folded fibre, 200 to 300 Â in diameter, as electron microscopy has shown^4–10. The arrangement of DNA within this fibre has not yet been established clearly. I wish to present electron micrographs of critical point dried and thin sectioned fibres of human metaphase chromosomes, which demonstrate more or less regularly distributed electron densities which could be explained by supercoiling of the 100 Â deoxynucleohistone fibril.     

Electron microscopy of gold-labeled human and equine chromosomes

We present an immunochemical technique for the detection of 5-bromo-2'-deoxyuridine (BrdU) incorporated discontinuously into the chromosomal DNA. A monoclonal anti-BrdU antibody and a protein A-gold complex were used to produce chromosome banding of human and equine chromosomes, specific for electron microscopy (EM). Well-defined bands, symmetry of sister chromatids, concordance between homologues, and band patterns similar to those observed by light microscopy facilitate chromosome identification and karyotyping. From prophase to late metaphase, chromosomes condense and bands appear to fuse. The fusion appears to be owing to chromatin reorganization. Our results underline the value of using immunogold reagents, which are ideal probes for antigen localization on chromosomes.     

PTP-S2, a nuclear tyrosine phosphatase, is phosphorylated and excluded from condensed chromosomes during mitosis

PTP-S2 is a tyrosine specific protein phosphatase that binds to DNA and is localized to the nucleus in association with chromatin. It plays a role in the regulation of cell proliferation. Here we show that the subcellular distribution of this protein changes during cell division. While PTP-S2 was localized exclusively to the nucleus in interphase cells, during metaphase and anaphase it was distributed throughout the cytoplasm and excluded from condensed chromosomes. At telophase PTP-S2 began to associate with chromosomes and at cytokinesis it was associated with chromatin in the newly formed nucleus. It was hyperphosphorylated and showed retarded mobility in cells arrested in metaphase. In vitro experiments showed that it was phosphorylated by CK2 resulting in mobility shift. Using a deletion mutant we found that CK2 phosphorylated PTP-S2 in the C-terminal non-catalytic domain. A heparin sensitive kinase from mitotic cell extracts phosphorylated PTP-S2 resulting in mobility shift. These results are consistent with the suggestion that during metaphase PTP-S2 is phosphorylated (possibly by CK2 or a CK2-like enzyme), resulting in its dissociation from chromatin.     

Dynamics of chromosome compaction during mitosis

We have quantitatively studied the space-time dynamics of mitotic chromosome compaction in cultured amphibian cells. After collecting digital phase-contrast images we have done digital image analysis to study spatial correlations in density. We find a characteristic distance at which the strongest correlations occur, which provides a quantitative measure of the size of patches of dense chromatin during interphase and early prophase. Later in mitosis, this length corresponds to the thickness of prophase and metaphase chromosomes. We find that during interphase strong correlations exist at a few-micrometer length; during prophase this correlation length progressively drops as the chromosomes are compacted. Our data are explained by a model based on assembly of chromatin loops onto already fiberlike interphase chromosomes. To test this model we have microinjected cobalt hexamine trichloride into interphase nuclei and have observed the rapid condensation of the interphase chromatin into thick fibers with a spacing similar to the native-state interphase correlation length determined from our image analysis.     

Self-assembly of thin plates from micrococcal nuclease-digested chromatin of metaphase chromosomes

The three-dimensional organization of the enormously long DNA molecules packaged within metaphase chromosomes has been one of the most elusive problems in structural biology. Chromosomal DNA is associated with histones and different structural models consider that the resulting long chromatin fibers are folded forming loops or more irregular three-dimensional networks. Here, we report that fragments of chromatin fibers obtained from human metaphase chromosomes digested with micrococcal nuclease associate spontaneously forming multilaminar platelike structures. These self-assembled structures are identical to the thin plates found previously in partially denatured chromosomes. Under metaphase ionic conditions, the fragments that are initially folded forming the typical 30-nm chromatin fibers are untwisted and incorporated into growing plates. Large plates can be self-assembled from very short chromatin fragments, indicating that metaphase chromatin has a high tendency to generate plates even when there are many discontinuities in the DNA chain. Self-assembly at 37°C favors the formation of thick plates having many layers. All these results demonstrate conclusively that metaphase chromatin has the intrinsic capacity to self-organize as a multilayered planar structure. A chromosome structure consistent of many stacked layers of planar chromatin avoids random entanglement of DNA, and gives compactness and a high physical consistency to chromatids.