Electron microscopy of the parameres formed by the centromeric heterochromatin of human chromosome 9 at pachytene

The structure and arrangement of the parameres, which are small bodies representing part of the heterochromatin of human chromosome 9 at pachytene, were studied using transmission and scanning electron microscopy. Parameres appear to be denser than other parts of the chromosomes but have a similar fibrous substructure. The most common arrangement is clusters on the axis of the bivalent, consisting of varying numbers of parameres of variable size. The parameres are joined to each other and to the rest of the chromosome by interconnecting fibres. No evidence was obtained for the organisation of parameres into paired lateral loops, as proposed by previous workers using light microscopy. The combination of osmium impregnation of pachytene chromosomes with a backscattered electron detector in the scanning electron microscope produced very clear images of the pattern of chromomeres. This procedure may prove valuable for pachytene mapping of chromosomes because of the greatly improved resolution compared with light microscopy.     

Chromonema and chromomere

A study of ultrathin sections of normal Chinese hamster cells and cells treated with decreasing concentrations of bivalent cations (Ca²⁺ and Mg²⁺) in situ revealed several discrete levels of compaction of DNA-nucleoprotein (DNP) fibrils in mitotic chromosomes and the chromatin of interphase nuclei. At concentrations ranging from 3 mM CaCl₂ and 1 mM MgCl₂ to ten times less, the chromosomes are found to contain fibrous elements (chromonemata) about 100 nm in diameter. As Ca²⁺ concentration is gradually decreased to 0.2–0.1 mM, the chromosomes decondense into a number of discrete chromatin structures, the chromomeres. As decondensation proceeds, these chromomeres acquire a rosettelike structure with DNP fibrils radiating from an electron-dense core. Upon complete decondensation of chromosomes, individual chromomeres persist only in the centromeric regions. The following levels of DNP compaction in mitotic chromosomes are suggested: a 10-nm nucleosomal fibril, a 25-nm nucleomeric fibril, and the chromonema, a fibrous structure, about 100 nm in diameter, composed of chromomeres. Interphase nuclei also contain structures which are morphologically similar to the chromomeres of mitotic chromosomes.     

FINE STRUCTURE OF CHROMOSOMES

Electron micrographs of staminate hair cells of Tradescantia reflexa indicate that early prophase chromosomes are composed of a number of helically arranged chromonemata. Favorable preparations reveal as many as 64 identifiable subsidiary strands, assumedly arranged as intertwined pairs to form a hierarchy of pairs of pairs. The helices of the smallest discernible units have a diameter of about 125 A, with highly electron-scattering material disposed peripherally around a less dense "core." The wall of this peripheral ring has a thickness of about 40 A, and apparently represents another pair of coiled threads surrounding a 40 A central axis. The implications of the findings are discussed briefly.     

THE STRANDEDNESS OF MEIOTIC CHROMOSOMES FROM ONCOPELTUS

Meiotic chromosomes were isolated from male Oncopeltus fasciatus by dissecting the testes under insect Ringer's solution and spreading the living cells on the Langmuir trough. After being dried by the critical point method, preparations were examined under the electron microscope. Chromosomes at all stages of prophase prove to be multistranded. A significant increase in the number of parallel 250 A fibers in the chromosomes occurs between zygotene and diakinesis. Parallel folding, rather than true multistrandedness, is interpreted as the mechanism responsible for this observed increase in multistrandedness. It has not been possible to determine whether the multistrandedness observed at leptotene represents true multistrandedness or is the result of parallel folding. Apparent multistrandedness is lost at metaphase when the 250 A fibers of the chromosomes become coiled more tightly. In preparations isolated by these methods, no structures other than the 250 A chromosome fibers are visible in the chromomeres, which appear as regionally coiled or folded areas of the fibers along the arm of the chromosome.     

Features of structural organization of mouse centrometric heterochromatin, detected during differential decondensation of chromosomes

The centromeric heterochromatin (CH) of mouse metaphase and interphase chromosomes has been shown to be practically devoid of the chromonemal and chromomeric levels of DNP organization. CH decondensation into DNP-fibrils caused by decreasing Ca2+-ions concentration is accomplished without formation of chromonemata and chromomeres. The peripheral regions of CH, immediately contacting the inner surface of kinetochores, display the highest stability towards the factors inducing the artificial decondensation.     

Mechanisms of chromosome banding : VI. Whole mount electron microscopy of banded metaphase chromosomes and a comparison with pachytene chromosomes

Chinese hamster chromosomes, banded by exposure to actinomycin D during the G 2 period, were examined by whole mount electron microscopy. Bands of condensed chromatin were present in unstained preparations that were not fixed with methanol-acetic acid indicating that the differential condensation of chromatin plays a role in banding by this technique. There was a tendency for interdigitation of the chromatin of the homologous bands on sister chromatids. Since previous studies had shown that the bands of mitotic chromosomes matched the chromomeres of meiotic chromosomes, whole mount electron microscope preparations of pachytene chromosomes were also examined. These suggest that in addition to condensation the chromatin of the chromomeres may also have a higher density of attachment sites to the lateral element of the synaptonemal complex, and probably to the nuclear membrane in interphase cells.     

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.     

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.     

Isolated chromosomes

Nucleoprotein threads isolated from mammalian tissues are interphase chromosomes rather than random fragments of stretched nuclei. Structures similar to the isolated threads are visible in intact nuclei. The isolated threads are often clearly microscopically double, consist of more or less tightly coiled chromonemata and show individuality in longitudinal differentiation. A nucleolus organizing chromosome with trabant and secondary constriction carrying the nucleolus can be recognized and is of identical structure in preparations from beef liver and pancreas.     

Correlation between isolated lampbrush chromosomes and nuclear structures of Pleurodeles waltl oocytes: An electron microscopic study

The organization of the lampbrush chromosomes of Pleurodeles waltl was studied by fixation and embedding of oocytes in toto and correlated with that observed in end-embedded preparations of isolated chromosomes. Particular attention was focused on marker loops, like the granular and globular loops, and atypical structures known as spheres (S) and M. In both types of preparations, the majority of the loops, the so-called normal loops, and the granular loops appeared to share a common basic organization, with ribonucleoprotein (RNP) fibrils appearing as strings of 30 nm particles, as described by earlier authors. Some new types of loop organization were observed: (i) P loops with 45 nm RNP particles; (ii) dense granular loops; (iii) loops with a cylindrical organization. RNP fibrils formed by 60 nm particles were found to occur in association with the globular loops. EDTA staining suggested the presence of large amounts of RNP in the sphere but very little in M. Three morphologically different types of RNP granules could be observed free in the nucleoplasm.     

Cytogenetic maps of lampbrush chromosomes of newts of the genus Pleurodeles: an algorithm of lampbrush chromosome identification in Pleurodeles waltl by immunocytochemical marker-loop staining with polyclonal anti-Ro52 antisera

Our work was aimed at developing a simple and effective method of identification of most or all chromosomes of Pleurodeles newts. To this end, we used DAPI staining of the chromomeres of newt lampbrush chromosomes and immunochemical reactions between the ribonucleoprotein (RNP) marker loops and polyclonal antibodies against human zinc-finger protein Ro52 (52-kDa Ro/SS-A). A method has been developed to obtain newt lampbrush chromosome preparations. Cytological maps of P. waltl chromosomes (Spanish population/subspecies) showing distributions of chromomeres and marker loops along the chromosome length were constructed.     

Differences in the structural organization of the G- and R-bands detectable during the differential decondensation of chromosomes

The ultrastructure of G- and R-bands in differentially decondensed chromosomes of Chinese hamster was studied with a gradual decrease in CaCl2 concentration in the medium. The gradual reduction of CaCl2 concentration leads to the decondensation of compact G-bands into chromonemes, chromomeres and further into DNP-fibrils. In the complete local decondensation zones (R-bands), the DNP-fibril orientation is parallel to the chromosome longitudinal axis. These zones have no lateral loops or chromomeres. Thus, different chromosome regions corresponding to G- and R-bands possess different sensibility to the decondensing action. Following the complete decondensation in the calcium-free medium chromosomes can be "reconstructed" by adding Ca2+. The data obtained permit to suggest a "fastener" model of the mitotic chromosome organization in which the chromosome represents an hierarchy of discrete structures--G-bands, chromomeres, nucleomeres (superbeads) and nucleosomes. The structural integrity of these levels is supported by specific protein "fasteners".     

The Relation between the Axial Complex of Meiotic Prophase Chromosomes and Chromosome Pairing in a Salamander (Plethodon cinereus)

An investigation of the structure of meiotic chromosomes from primary spermatocytes of two salamanders, Plethodon cinereus and Desmognathus fusca, has been made using correlated light and electron microscopy. Feulgen squashes were compared with stained sections and these related to adjacent thin sections in the electron microscope. A transition from the familiar cytological preparation to the electron image was thus effected. A linear complex consisting of three parallel strands has been observed with the electron microscope, passing along the central axis of primary spermatocyte chromosomes. The complex is similar to that found in comparable chromosomes from at least a dozen animal species. The structure in Plethodon is described in detail. Synapsis has been positively identified as the stage of meiotic prophase at which the complex occurs. Thus the complex is a part of bivalent chromosomes. It has not been seen in other stages or other divisions and is thus thought to be exclusively of synaptic occurrence. The term synaptinemal complex is suggested for the entire structure. By virtue of the material condensed around it, the complex is also seen in the light microscope where it appears as a fine, densely Feulgen-positive central core along the chromosome. The complex is thus closely associated with DNA, if not at least in part, composed of it. In the stages studied, homologous chromosomes are not always completely paired. The lateral elements of the complex separate and follow the single chromosome axes at these points. The central element disappears and thus may be a phenomenon of pairing. It is concluded that the lateral elements of the synaptinemal complex may more correctly be a "core" of the single meiotic prophase chromosome, possibly being concerned with its linear organization.     

Electron microscopy of surface spread polytene chromosomes of Drosophila and Stylonychia

The ultrastructure of polytene chromosomes of Drosophila and Stylonychia were compared in whole-mount spread preparations. In Drosophila the chromomeres appear as dense, unresolvable structures interconnected by 10-nm interband fibers. In contrast, chromomeres of Stylonychia polytene chromosomes are formed by aggregates of 30-nm loops laterally attached to 10-nm interband fibers. It is suggested that the polytene chromosomes in these two species are analogous rather than homologous structures.     

Cytogenetic Maps of Lampbrush Chromosomes of Newts of the Genus Pleurodeles: An Algorithm of Lampbrush Chromosome Identification inPleurodeles waltl by Immunocytochemical Staining of Landmark Loops with Polyclonal Anti-Ro52 Antisera

Our work was aimed at developing a simple and effective method of identification of most or all chromosomes of Pleurodelesnewts. To this end, we used DAPI staining of the chromomeres of newt lampbrush chromosomes and immunochemical reactions between the ribonucleoproteins of landmark lateral loops and polyclonal antibodies against human zinc-finger protein Ro52 (52-kDa Ro/SS-A). A method has been developed to obtain lampbrush chromosome preparations in newts of the genes Pleurodeles. Cytological maps of P. waltl chromosomes (Spanish population/subspecies) showing distributions of chromomeres and marker landmark loops along the chromosome length were constructed.