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.     

Assembly of chromatin fibers into metaphase chromosomes analyzed by transmission electron microscopy and scanning electron microscopy.

The higher-order assembly of the approximately 30 nm chromatin fibers into the characteristic morphology of HeLa mitotic chromosomes was investigated by electron microscopy. Transmission electron microscopy (TEM) of serial sections was applied to view the distribution of the DNA-histone-nonhistone fibers through the chromatid arms. Scanning electron microscopy (SEM) provided a complementary technique allowing the surface arrangement of the fibers to be observed. The approach with both procedures was to swell the chromosomes slightly, without extracting proteins, so that the densely-packed chromatin fibers were separated. The degree of expansion of the chromosomes was controlled by adjusting the concentration of divalent cations (Mg2+). With TEM, individual fibers could be resolved by decreasing the Mg2+ concentration to 1.0-1.5 mM. The predominant mode of fiber organization was seen to be radial for both longitudinal and transverse sections. Using SEM, surface protuberances with an average diameter of 69 nm became visible after the Mg2+ concentration was reduced to 1.5 mM. The knobby surface appearance was a variable feature, because the average diameter decreased when the divalent cation concentration was further reduced. The surface projections appear to represent the peripheral tips of radial chromatin loops. These TEM and SEM observations support a "radial loop" model for the organization of the chromatin fibers in metaphase chromosomes.     

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.     

Attachment of human chromatin fibers to the nuclear membrane,as seen by electron microscopy

Summary Whole-mount preparations and thin sections of human interphase cells and metaphase chromosomes were examined by electron microscopy. Irregularly folded, 250 Å thick fibers, which is the basic substructure of inactive chromatin and mitotic chromosomes, were found to be firmly attached to the annuli of the inner nuclear membrane. At metaphase, fragments of the nuclear membrane were seen to adhere to the chromatids. Single fibers stretching out from the telomeres were observed connecting chromatids of nonhomologous chromosomes. A possible model of DNA replication at the nuclear pore complex is presented.

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Zusammenfassung Totalpräparate und Dünnschnitte menschlicher Interphase-Zellen und Metaphase-Chromosomen wurden mit dem Elektronenmikroskop untersucht. Unregelmäßig gefaltete, 250 Å dicke Fäden bilden die Grundstruktur des inaktiven Chromatins und der Mitose-Chromosomen. Diese Fäden hängen in der Interphase an vielen Stellen fest an der inneren Kernmembran an den annuli der Kernporen. In der Metaphase sind häufig noch Reste der Kernmembran durch Fäden mit den Chromatiden verbunden. Einzelne, jeweill vom Telomer ausgehende Fäden verknüpfen Chromatide nichthomologer Chromosomen. Das Modell einer möglichen DNA-Replikation an den Poren der Kernmembran wird diskutiert.

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Supported by a grant (La 185/3) of the Deutsche Forschungsgemeinschaft.     

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.     

Studies on the mitotic chromosome scaffold of Allium sativum

An argentophilic structure is present in the metaphase chromosomes of garlic(Allium sativum),Cytochemical studies indicate that the main component of the structure is non-histone proteins(NHPs).The results of light and electron microscopic observations reveal that the chromosme NHP scaffold is a network which is composed of fibres and granules and distributed throughout the chromosomes.In the NHP network,there are many condensed regions that are connected by redlatively looser regions.The distribution of the condensed regions varies in individual chromosomes.In some of the chromosomes the condensed regions are lognitudinally situsted in the central part of a chromatid while in others these regions appear as coillike transverse bands.At early metaphase.scaffolds of the sister chromatids of a chromosome are linked to each other in the centromeric region,meanwhile,they are connected by scafold materials along the whole length of the chromosome.At late metaphase,however,the connective scaffold materials between the two sister chromatids disappear gradually and the chromatids begin to separate from one another at their ends.but the chromatids are linked together in the centromeric region until anaphase.This connection seems to be related to the special structure of the NHP scaffold formed in the centromeric region.The morphological features and dynamic changes of the chromosome scaffold are discussed.     

Scaffold attachment of DNA loops in metaphase chromosomes

We have examined the higher-order loop organization of DNA in interphase nuclei and metaphase chromosomes from Drosophila Kc cells, and we detect no changes in the distribution of scaffold-attached regions (SARs) between these two phases of the cell cycle. The SARs, previously defined from experiments with interphase nuclei, not only are bound to the metaphase scaffold when endogenous DNA is probed but also rebind specifically to metaphase scaffolds when added exogenously as cloned, end-labeled fragments. Since metaphase scaffolds have a simpler protein pattern than interphase nuclear scaffolds, and both have a similar binding capacity, it appears that the population of proteins required for the specific scaffold-DNA interaction is limited to those found in metaphase scaffolds. Surprisingly, metaphase scaffolds isolated from Drosophila Kc cells contain both the lamin protein and a pore-complex protein, glycoprotein (gp) 188. To study whether lamin contributes to the SAR-scaffold interaction, we have carried out comparative binding studies with scaffolds from HeLa metaphase chromosomes, which are free of lamina, and from HeLa interphase nuclei. All Drosophila SAR fragments tested bind with excellent specificity to HeLa interphase scaffolds, whereas a subset of them bind to HeLa metaphase scaffolds. The maintenance of the scaffold-DNA interaction in metaphase indicates that lamin proteins are not involved in the attachment site for at least a subset of Drosophila SARs. This evolutionary and cell-cycle conservation of scaffold binding sites is consistent with a fundamental role for these fragments in the organization of the genome into looped domains.     

Ultrastructure of the mitotic chromosomes in pig embryonic kidney cells during their reversible artificial decondensation in vivo

Using methods of in vivo observation and ultrathin sectioning, it is shown that chromosomes of metaphase PE cells, previously treated with diluted Henk's solutions (70, 30 and 15%), undergo some structural transitions resulting in the formation of micronuclei. At the early stages of hypotonic treatment chromosomes are seen considerably swollen and losing the higher levels of organization, including the chromonema and chromomeres. The chromosomal bodies are formed by DNP fibers 10-25 nm in diameter making loops radiating from the central part of the chromatids. Chromosomes are capable of recondensing from this state by consecutive reconstitution of G-bands, chromomeres and the chromonema. The subsequent secondary decondensation of chromosomes is analogous to telophase decondensation at the normal mitosis, but it results in the formation of a great number of small nuclei (micronuclei). The chromatin structure in micronuclei as well as their ability to synthesize RNA and to replicate DNA show these effects to be reversible. It has been suggested that the loop organization of DNP may be essential for sustaining the structural integrity of the mitotic chromosome.     

Visualization of early chromosome condensation: a hierarchical folding, axial glue model of chromosome structure

Current models of mitotic chromosome structure are based largely on the examination of maximally condensed metaphase chromosomes. Here, we test these models by correlating the distribution of two scaffold components with the appearance of prophase chromosome folding intermediates. We confirm an axial distribution of topoisomerase IIalpha and the condensin subunit, structural maintenance of chromosomes 2 (SMC2), in unextracted metaphase chromosomes, with SMC2 localizing to a 150-200-nm-diameter central core. In contrast to predictions of radial loop/scaffold models, this axial distribution does not appear until late prophase, after formation of uniformly condensed middle prophase chromosomes. Instead, SMC2 associates throughout early and middle prophase chromatids, frequently forming foci over the chromosome exterior. Early prophase condensation occurs through folding of large-scale chromatin fibers into condensed masses. These resolve into linear, 200-300-nm-diameter middle prophase chromatids that double in diameter by late prophase. We propose a unified model of chromosome structure in which hierarchical levels of chromatin folding are stabilized late in mitosis by an axial "glue."     

Human Wapl is a cohesin-binding protein that promotes sister-chromatid resolution in mitotic prophase

BACKGROUND: The linkage between duplicated chromosomes (sister chromatids) is established during S phase by the action of cohesin, a multisubunit complex conserved from yeast to humans. Most cohesin dissociates from chromosome arms when the cell enters mitotic prophase, leading to the formation of metaphase chromosomes with two cytologically discernible chromatids. This process is known as sister-chromatid resolution. Although two mitotic kinases have been implicated in this process, it remains unknown exactly how the cohesin-mediated linkage is destabilized at a mechanistic level. RESULTS: The wings apart-like (Wapl) protein was originally identified as a gene product that potentially regulates heterochromatin organization in Drosophila melanogaster. We show that the human ortholog of Wapl is a cohesin-binding protein that facilitates cohesin's timely release from chromosome arms during prophase. Depletion of Wapl from HeLa cells causes transient accumulation of prometaphase-like cells with chromosomes that display poorly resolved sister chromatids with a high level of cohesin. Reduction of cohesin relieves the Wapl-depletion phenotype, and depletion of Wapl rescues premature sister separation observed in Sgo1-depleted or Esco2-depleted cells. Conversely, overexpression of Wapl causes premature separation of sister chromatids. Wapl physically associates with cohesin in HeLa-cell nuclear extracts. Remarkably, in vitro reconstitution experiments demonstrate that Wapl forms a stoichiometric, ternary complex with two regulatory subunits of cohesin, implicating its noncatalytic function in inactivating cohesin's ability to interact with chromatin. CONCLUSIONS: Wapl is a new regulator of sister chromatid resolution and promotes release of cohesin from chromosomes by directly interacting with its regulatory subunits.     

Superstructures of wet inactive chromatin and the chromosome surface

Superpacking of chromatin and the surface features of metaphase chromosomes have been studied by SiO replication of wet, unstained, and unfixed specimens in an exceedingly thin (≤ 1 nm) aqueous layer, keeping them wet. Hydrophilic Formvar substrates allow controlled thinning of the aqueous layer covering the wet specimens. Whole mounts of chromatin and chromosomes were prepared by applying a microsurface spreading method to swollen nuclei and mitotic cells at metaphase. The highest level of nucleosome folding of the inactive chromatin in chicken erythrocytes and rat liver nuclei is basically a second-order superhelical organization (width 150–200 nm, pitch distance 50–150 nm) of the elementary nucleosome filament. In unfavorable environments (as determined by ionic agents, fixative, and dehydrating agents) this superstructure collapses into chains of superbeads and beads. Formalin (10%) apparently attacks at discrete sites of chromatin, which are then separated into superbeads. The latter consist of 4–6 nucleosomes and seemingly correspond to successive turns of an original solenoidal coil (width 30–35 nm), which forms the superhelical organization. When this organization is unfolded, eg, in 1–2 mM EDTA, DNAse-sensitive filaments (diameter 1.7 nm) are seen to be wrapped around the nucleosomes. The wet chromosomes in each metaphase spread are held to each other by smooth microtubular fibers, 20–30 nm in diameter. Before they enter into a chromsome, these fibers branch into 9–13 protofilaments, each 5 nm wide. The chromosome surface contains a dense distribution of subunits about 10–25 nm in diameter. This size distribution corresponds to that of nucleosomes and their superbeads. Distinct from this beaded chromosome surface are several smooth, 23–30-nm-diameter fibers, which are longitudinal at the centromere and seem to continue into the chromatid structure. The surface replicas of dried chromosomes do not show these features, which are revealed only in wet chromosomes.     

Low angle x-ray diffraction studies of HeLa metaphase chromosomes: effects of histone phosphorylation and chromosome isolation procedure

To test whether gross changes in chromatin structure occur during the cell cycle, we compared HeLa mitotic metaphase chromosomes and interphase nuclei by low angle x-ray diffraction. Interphase nuclei and metaphase chromosomes differ only in the 30-40-nm packing reflection, but not in the higher angle part of the x-ray diffraction pattern. Our interpretation of these results is that the transition to metaphase affects only the packing of chromatin fibers and not, to the resolution of our method, the internal structure of nucleosomes or the pattern of nucleosome packing within chromatin fibers. In particular, phosphorylation of histones H1 and H3 at mitosis does not affect chromatin fiber structure, since the same x-ray results are obtained whether or not histone dephosphorylation is prevented by isolating metaphase chromosomes in the presence of 5,5'-dithiobis(2- nitrobenzoate) or low concentrations of p-chloromercuriphenylsulfonate (ClHgPhSO3). We also compared metaphase chromosomes isolated by several different published procedures, and found that the isolation procedure can significantly affect the x-ray diffraction pattern. High concentrations of ClHgPhSO3 can also profoundly affect the pattern.     

Enhanced Hoechst 33258 fluorescence in plants.

The topological features of isolated Chinese hamster ovary metaphase chromosomes were studied with high resolution scanning electron microscopy (SEM) using the techniques of direct current sputtering for the deposition of metal on the specimens. Metaphase chromosome surfaces consist of numerous compact microconvules of an average diameter of 520 ± 78 Å when corrected for the thickness of the gold-palladium coating (80 ± 2 Å). These microconvules contain several orders of supercoiling. The superhelical structures were detected also in water-spread preparations. Most of the isolated chromosomes had membrane-like structures attached at the distal portions of the chromatids forming a terminal “plate”. Limited tryptic digests of such isolated chromosomes resulted in considerable stretching of the chromatids and revealed a series of interchromatidal fibers with diameters of 203 ± 38 Å (corrected for gold coating). Treatment of these chromosomes with EDTA revealed a longitudinal array of fibers within the chromatids. The diameters of these fibers decreased as the concentration of EDTA was increased. The technique of direct current sputtering for the preparation of chromosomes for scanning microscopy is satisfactory for detailed topological ultrastructural studies in the 70 Å range.     

High resolution detection of uncoated metaphase chromosomes by means of field emission scanning electron microscopy

HeLa metaphase chromosomes were exammed by means of in lens field emission scanning electron microscopy, which permits high resolution detection of uncoated biological samples. By using uncoated chromosomes as a model for comparison we report evidence of how traditional scanning electron microscopy techniques such as metal coating and conductive methods can generate errors in chromosome structure evaluation, since both give rise to morphological artifacts. By comparing the morphology of uncoated chromosomes obtained by two different isolation procedures, such as that utilized in standard cytogenetics and the polyamine method, we have drawn the following conclusions: (a) the standard cytogenetic method gives rise to a chromosome structure consisting of a flattened network of 10 nm fibers, in which higher order chromatin organization is absent. (b) Chromosomes obtained by the polyamine method show both three-dimensional profile and higher level folding of chromatin fibers, supporting the loop chromosome organization previously suggested by scanning electron microscopy observation of hexylene glycol isolated chromosomes.     

A new chromosome model

We present a new model of the three-dimensional structure of chromosomes. With DNA and protein staining it could be shown by high-resolution scanning electron microscopy that metaphase chromosomes are mainly composed of DNA packed in "chromomeres" (coiled solenoides) and a dynamic matrix formed of parallel protein fibers. In the centromeric region, the chromomeres are less densely packed, giving insight into the matrix fibers. We postulate that chromosome condensation is achieved by the binding of solenoids to matrix fibers which have contact sites to one another and move antiparallel to each other. As condensation progresses, loops of solenoids accumulate to form additional chromomeres, causing chromosomes to become successively shorter and thicker as more chromomeres are formed. For sterical reasons, a tension vertical to the axial direction forces the chromatids apart. The model can simply explain the enormous variety of chromosome morphology in plant and animal systems by varying only a few cytological parameters. Primary and secondary constrictions and deletions are defined as regions devoid of chromomeres. Even in the highly condensed metaphase, all genes would be easily accessible.     

Chromatid distribution at mitosis in cultured Wallabia bicolor cells

An analysis of labelled centromere regions of chromosomes in metaphase cells of the Swamp Wallaby (Wallabia bicolor) demonstrates conclusively that chromatids do not co-segregate in sets which contain DNA template strands of identical age. Also, there is no tendency for chromatids of homologous chromosome pairs to distribute non-randomly. The data are consistent with the assumption of random distribution of chromatids at mitosis.     

Kinetochore and microtubules in two members of Chlorophyceae,Cladophora fracta and Spirogyra majuscula

Evidence is presented for the existence of a localised kinetochore with stratified fine structure in Cladophora and in Spirogyra. In the latter, there is the possibility of two kinetochores on the longer chromosomes. There is no evidence for a diffuse kinetochore. The nucleolus persists during mitosis in Cladophora on the nucleolar organising chromosomes, the granular material being lost from it very largely during metaphase and anaphase but the fibrillar material remaining. The persistent nucleolar material at metaphase and anaphase in Spirogyra is not attached to the nucleolar organising chromosomes but accumulates around all the chromosomes and chromatids, the microtubules of the spindle at anaphase passing through and possibly attaching to this nucleolar material and possibly assisting in the movement of the chromatids which are embedded within it.     

Metaphase chromosome structure: evidence for a radial loop model.

Electron micrographs of thin sections of metaphase chromosomes isolated from HeLa cells provide new insight into the higher-order arrangement of the nucleoprotein fiber. Micrographs obtained from chromosomes swollen by chelation of the divalent cation are particularly revealing. Under these conditions, chromosomes swell in width by a factor of about 4 and the basic, thick nucleoprotein fiber (200–300 Å) relaxes to the thin fiber (100 Å), which is probably a linear array of nucleosomes. Cross sections show a central area from which the fibers emerge in a radial fashion, often forming loops which are 3–4 μm long. Chromosomes fixed in the presence of 1 mM MgCl₂ are more compact, having an average chromatid diameter of about 1 μm, and consist of the thick (200–300 Å) fiber. Radial loops of about 0.6 μm can be observed frequently in these chromosomes, although the loops are more difficult to visualize due to the compactness of the structure and the material contaminating the periphery. Chromosomes isolated with the help of hexylene glycol are extremely compact (diameter about 0.6 μm) but quite free of cytoplasmic material. They consist of a 500 Å fiber that forms rather regular projections at the periphery. These projections appear to be loops of the thick fiber (200–300 Å), possibly shortened by twisting into a short supercoil. The chromatin loops observed in the intact chromosomes are thought to be structurally related to the DNA loops observed previously in the histone-depleted chromosomes (Paulson and Laemmli, 1977). In this paper, we discuss a model in which the nucleoprotein fiber is folded into loops which are arranged in the chromatid in radial fashion, in such a way that their bases become the central axis of the chromatid.     

The chemical composition of nuclei and chromosomes isolated by the Langmuir trough technique

The pattern of staining for DNA, histone, and nonhistone protein has been studied in whole cells and in nuclei and chromosomes isolated by surface spreading. In whole interphase cells from bovine kidney tissue culture, nuclear staining for DNA and histones reveals numerous small, intensely stained clumps, surrounded by more diffusely stained material. Nuclei in whole cells stained for nonhistone proteins also contain intensely stained regions surrounded by diffuse stain. These intensely stained regions also stain for RNA, indicating that the regions contain nucleolar material. Electron microscopy of kidney cells confirms that multiple nucleoli are present. Kidney nuclei isolated by surface spreading show an even distribution of stain for DNA, histones, and nonhistone proteins, indicating that the surface forces disperse both condensed chromatin and nucleoli. DNA and protein staining was also studied in metaphase chromosomes from testes of the milkweed bug, Oncopeltus fasciatus. Staining for DNA and histones in metaphase chromosomes is essentially the same in sections of fixed and embedded testes as in preparations isolated by surface spreading. However, striking differences are noted in the distribution of nonhistone proteins. In sections, nonhistone stain is concentrated in extrachromosomal areas; metaphase chromosomes do not stain for nonhistone proteins. Chromosomes isolated by surface spreading, however, stain intensely for nonhistone proteins. This suggests that nonhistone proteins are bound to the chromosomes as a contaminant during the isolation procedure. The relationship of these findings to current work with chromosomes isolated for electron microscopy is discussed.