Structure and mode of formation of the nucleolus in meristematic cells of Vicia faba and Allium cepa

Interphase nucleoli from Vicia faba and Allium cepa meristematic cells are roughly classified into two categories: (a) those that commonly show a rather homogeneous texture (except for small light spaces of various sizes) and frequently contain dense particles 140 A in diameter; (b) those found more frequently in Vicia characterized by a very sharp boundary between a dense outer cortex and a much lighter central core. The dense particles are not found in such nucleoli. In Allium the boundary is more irregular and dense particles are sometimes observed in the outer layer. Many nucleoli show a structure intermediate between these two types. They are characterized by a gradient of increasing density from the center to the periphery and occasionally contain dense 140 A granules. During interphase, certain nucleoli are closely associated with segments of chromatin strands which undoubtedly represent nucleolar organizing regions. The dense 140 A granules are followed during the mitotic cycle. In Allium, they are first seen in loose clusters between arms of late anaphase chromosomes where they become more concentrated in early telophase. The substance within which they are scattered slowly increases in density during that time until finally, the particles are limited to small bodies of distinctive character. Evidence is presented suggesting that these small prenucleolar bodies fuse during telophase to give rise to the mature interphase nucleoli. Similar events are described in Vicia material except that a coating of dense substance appears around telophase chromosomes before the formation of prenucleolar bodies.     

A search for protein cores in chromosomes: Is the scaffold an artifact?

A protein chromosome scaffold structure has been proposed that acts as a structural framework for attachment of chromosomal DNA. There are several troubling aspects of this concept: (1) such structures have not been seen in many previous thin-section and whole-mount electron microscopy studies of metaphase chromosomes, while they are readily seen in leptotene and zygotene chromosomes; (2) such a structure poses problems for sister chromatid exchanges; and (3) the published photographs show a marked variation in the amount of scaffold in different whole-mount preparations. An alternative explanation is that the scaffold in whole-mount preparations represents incomplete dispersion of the high concentration of chromatin in the center of chromosomes, and when the histones are removed and the DNA dispersed, the remaining nonhistone proteins (NHPs) aggregate to form a chromosome-shaped structure. Two studies were done to determine if the scaffold is real or an artifact: (1) Chinese hamster mitotic cells and isolated chromosomes were examined using two protein stains -EDTA-regressive staining and phosphotungstic acid (PTA) stain. The EDTA-regressive stain showed ribonucleoprotein particles at the periphery of the chromosomes but nothing at the center of the chromosomes. The PTA stain showed the kinetochore plates but no central structures; and (2) isolated chromosomes were partially dispersed to decrease the high concentration of chromatin in the center of the chromosome, then treated with 4 M ammonium acetate or 2 M NaCl to dehistonize them and disperse the DNA. Under these circumstances, no chromosome scaffold was seen. We conclude that the scaffold structure is an artifact resulting from incomplete dispersion of central chromatin and aggregation of NHPs in dehistonized chromosomes.     

Small marker X chromosomes lack the X inactivation center: implications for karyotype/phenotype correlations.

The abnormal phenotype and/or mental retardation seen in persons with small marker X (mar(X)) chromosomes has been hypothesized to be due to the loss of the X inactivation center (XIC) at Xq13.2, resulting in two active copies of genes in the pericentromeric region. In order to define precisely the DNA content of mar(X) chromosomes and to correlate phenotype with karyotype, we studied small mar(X) chromosomes, using FISH with probes in the juxtacentromeric region. One of the probes was a 40-kb genomic cosmid for the XIST gene, which maps to the smallest interval known to contain the XIC and is thought to be involved in X inactivation. Our findings reveal that small mar(X) chromosomes do not include the XIC and therefore cannot be subject to X inactivation, supporting the premise that abnormal dosage of expressed genes in the pericentromeric region of the X generates the aberrant phenotype seen in patients with small mar(X) chromosomes.     

Flow cytometric determination of radiation-induced chromosome damage and its correlation with cell survival

Chinese hamster M3-1 cells were irradiated with several doses of X rays or alpha particles from 238Pu. Propidium iodide-stained chromosome suspensions were prepared at different times after irradiation; cells were also assayed for survival. The DNA histograms of these chromosomes showed increased background counts with increased doses of radiation. This increase in background was cell-cycle dependent and was correlated with cell survival. The correlation between radiation-induced chromosome damage and cell survival was the same for X rays and alpha particles. Data are presented which indicate that flow cytometric analysis of chromosomes of irradiated cell populations can be a useful adjunct to classical cytogenic analysis of irradiation-induced chromosomal damage by virtue of its ability to express and measure chromosomal damage not seen by classical cytogenic methods.     

Perturbation of mammalian cell division. II. Studies on the isolation and characterization of human mini segregant cells.

A method is described for the isolation, according to size, of mini segregants produced by the abnormal cleavage of reversibly arrested mitotic HeLa cells. Many of these mini segregants contain small amounts of DNA, as judged by Feulgen staining and chromosome analysis. After fusion with mitotic HeLa cells, the interphase chromosomes of the mini segregants are seen as either monovalent or bivalent prematurely condensed chromosomes (PCC), some of which are damaged. A proportion of isolated mini segregants synthesize DNA, RNA and protein. Fusion of mini segregants with interphase HeLa cells gives rise to cells with 'hybrid' karyotypes.     

Description of a chromosome replication unit in individual prematurely condensed human S-phase chromosomes

Mammalian chromosome replication was studied by the aid of premature chromosome condensation (PCC). After induction of PCC the sites of DNA replication appear as “gaps” between condensed chromosomal regions. These condensed particles are unineme before and bineme after DNA replication. The two phases are due mainly to the unineme or bineme nature of the particles. During early S-phase almost all particles are unineme, during late S-phase they are bineme and there is only one transitory stage between these two main stages. Premature chromosome condensation was studied in detail on a specific human chromosome 22 which is marked by its heterochromatin constitution. This led to easy identification of these elements in S-phase PCC (S-PCC) preparations. For each stage of the S-phase there was a reproducible pattern of condensed chromosomal particles making up the whole chromosome. The number of these particles was rather limited and a complementary pattern was found in early versus late S-phase. The pattern of early S-PCC corresponded to the banding pattern of G-banded prometaphase chromosomes; the pattern of late S-PCC, to R-banded prometaphase chromosomes. Thus, “gaps” and condensed particles as observed after PCC induction are obviously homologous to chromosome replication units. Replication of constitutive heterochromatin occurred during the very late S-phase. During this stage PCC induction led to condensation of the heterochromatin into several small, highly fluorescent particles.     

Die Speicheldrüsenchromosomen der StechmückeCulex pipiens

The salivary gland chromosomes of an autogenous strain ofCulex p. pipiens are described and mapped. The regions of the centromeres are the only large morphological landmarks and can be used for a quick and exact identification of the chromosomes. Asynaptic parts cannot be constantly observed. Balbianirings are not seen. The puffs being small and only visible for a short time, cannot be used as landmarks. Therefore the single arms of the chromosomes can only be recognized by their very clear and distinct pattern.     

Properties of a membrane-attached form of the folded chromosome of Escherichia coli

Two types of DNA-containing particles are released from lysozyme-produced Escherichia coli spheroplasts after gentle lysis with non-ionic detergents in 1.-0 m-NaCl. Lysis at 25 °C releases the folded chromosomes (1300 S to 2200 S particles). Lysis at 10 °C results in faster sedimenting structures (3000 S to 4000 S). Both types of particles coexist in extracts of cells lysed at intermediate temperatures, i.e. 15 °C.The 3000 S to 4000 S particles are folded chromosomes attached to membrane fragments; they contain membrane proteins and phospholipids in addition to the folded DNA and nascent RNA chains. Incubation of the membrane-attached chromosomes with 1% Sarkosyl releases the folded chromosomes; this Sarkosyl treatment removes the membrane proteins and phospholipids, and halves the sedimentation velocity of the particles, but has no effect on the folded DNA and nascent RNA chains.Membrane-attached chromosomes cannot be isolated from amino acid-starved cells which have completed their rounds of DNA replication; all of the DNA then appears as released folded chromosomes. After resumption of protein synthesis, chromosome attachment to the membrane precedes the initiation of DNA replication. Controls strongly suggest that the changes observed, i.e. the attachment and release from the membrane of the folded chromosome, are related to the act of DNA replication itself.     

Compound kinetochores of the Indian muntjac

The chromosomes of the Indian muntjac (Muntiacus muntjak vaginalis) are unique among mammals due to their low diploid number (2N=6, 7) and large size. It has been proposed that the karyotype of this small Asiatic deer evolved from a related deer the Chinese muntjac (Muntiacus reevesi) with a diploid chromosome number of 2n= 46 consisting of small telocentric chromosomes. In this study we utilized a kinetochore-specific antiserum derived from human patients with the autoimmune disease scleroderma CREST as an immunofluorescent probe to examine kinetochores of the two muntjac species. Since CREST antiserum binds to kinetochores of mitotic chromosomes as well as prekinetochores in interphase nuclei, it was possible to identify and compare kinetochore morphology throughout the cell cycle. Our observations indicated that the kinetochores of the Indian muntjac are composed of a linear beadlike array of smaller subunits that become revealed during interphase. The kinetochores of the Chinese muntjac consisted of minute fluorescent dots located at the tips of the 46 telocentric chromosomes. During interphase, however, the kinetochores of the Chinese muntjac clustered into small aggregates reminiscent of the beadlike arrays seen in the Indian muntjac. Morphometric measurements of fluorescence indicated an equivalent amount of stained material in the two species. Our observations indicate that the kinetochores of the Indian muntjac are compound structures composed of linear arrays of smaller units the size of the individual kinetochores seen on metaphase chromosomes of the Chinese muntjac. Our study supports the notion that the kinetochores of the Indian muntjac evolved by linear fusion of unit kinetochores of the Chinese muntjac. Moreover, it is concluded that the evolution of compound kinetochores may have been facilitated by the nonrandom aggregation of interphase kinetochores in the nuclei of the ancestral species.     

Polyteny and endomitosis in supergiant trophoblast cells of the gray vole Microtus subarvalis

A cytomorphological study was made of peculiarly structured polytene chromosomes in supergiant trophoblast cells of Microtus subarvalis. The polyteny level was extremely high (over 1024C). The polytene chromosomes are characterized by a rather high degree of condensation of single chromosomes, and, as a consequence, close chromosome junctions and the typical disk pattern are lacking. The presence of complex nucleoli in the nuclei of these cells also testifies to a great detachment of chromonemes in polytene chromosomes of the studied supergiant trophoblast cells. Compared to other rodent species, a lower degree of chromoneme junction in the vole polytene chromosomes may cause their easy dissociation into single chromonemata, whose further condensation results in endomitotic chromosome formation. The chromosome depolytenization, earlier suggested from the analysis of interphase nucleus markers, has been traced here in detail. The process of polytene chromosome splitting was most obvious in the nucleolus-organizing chromosomes. A hony-combed nucleolus splits into numerous micronucleoli. The nucleus pattern becomes altered. Once in the polytene nucleus, chromosome bundles were located below the nuclear membrane and the central zone of the karyoplasm was not completely filled up. However, after dissociation of polytene chromosomes the whole karyoplasm was filled up with small nucleoli, and a thin layer of endomitotic chromosomes was seen beneath the nuclear membrane. The correlation between endomitosis and polyteny is discussed in terms of the dissociation of polytene chromosomes and formation of endomitotic chromosomes.     

Congenital anomalies and developmental delay in a boy with double chromosome 6 derived supernumerary marker

The frequency of small supernumerary marker chromosomes has been estimated to approximately 0.45 per 1000 newborns. They are usually seen as single marker chromosomes in a mosaic state. Two cytogenetically identical markers have been observed only occasionally. We report on a boy, with congenital heart defect, neonatal hypotonia, hypogenitalism, delayed psychomotor development and mild dysmorphic facial features. The GTG karyotype performed on peripheral blood lymphocytes revealed a mosaic male karyotype with three cell lines. One cell line had a normal karyotype. In the other two either single or double chromosome 6 derived supernumerary markers were present, leading to partial trisomy or partial tetrasomy of chromosome 6, respectively.     

Detection of quantitative trait loci causing abnormal spermatogenesis and reduced testis weight in the small testis (Smt) mutant mouse.

The small testis (Smt) mutant mouse is characterized by a small testis of one third to one half the size of a normal testis, and its spermatogenesis is mostly arrested at early stages of meiosis, although a small number of spermatocytes at the late prophase of meiosis and a few spermatids can sometimes be seen. We performed quantitative trait locus (QTL) analysis of these spermatogenic traits and testis weight using 221 F2 males obtained from a cross between Smt and MOM (Mus musculus molossinus) mice. At the genome-wide 5% level, we detected two QTLs affecting meiosis on chromosomes 4 and 13, and two QTLs for paired testis weight as a percentage of body weight on chromosomes 4 and X. In addition, we found several QTLs for degenerated germ cells and multinuclear giant cells on chromosomes 4, 7 and 13. Interestingly, for cell degeneration, the QTL on chromosome 13 interacted epistatically with the QTL on chromosome 4. These results reveal polygenic participation in the abnormal spermatogenesis and small testis size in the Smt mutant.     

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.     

Use of fluorescence genomic in situ hybridization (GISH) to detect the presence of alien chromatin in wheat lines differing in nuclear DNA content

BACKGROUND: Many times small differences in genome size are reported between or within plant species in which no cytologic confirmation is made. Attempts to repeat these studies have met with limited success. The controversy then becomes whether or not these small differences that were not confirmed cytologically are real. The present study was undertaken to determine if the approximately 1% nuclear variation seen by flow cytometry among wheat lines selected for aluminum response was due to actual chromatin differences. METHODS: The three parental wheat cultivars used in the aluminum selection along with the isolines resulting from the selection were analyzed. One parental line had previously been reported to have alien chromatin substituted for the corresponding wheat homologous chromatin. Genomic in situ hybridization was used to determine the presence or absence of rye chromatin in three cultivars and six near-isolines of wheat. RESULTS: Upon observing metaphase chromosomes of the Century parent and its isolines, two of the chromosomes were observed to be one-half yellow-orange, indicating rye chromatin with the remaining portion of the chromosomes and the other 40 wheat chromosomes having no label indicating wheat chromatin. In the Chisholm parent and its isolines, none of the chromosomes were labeled, indicating the absence of rye chromatin. In addition, none of the third parents' chromosomes had the rye yellow-orange signal. CONCLUSIONS: The wheat lines with the larger DNA contents were observed to have alien DNA present. DNA differences between the normal wheat chromosomes and the substituting alien chromatin were calculated based on total chromosome length. The increase in genome size of the wheat lines containing the alien chromatin appears to be the result of the alien chromatin having approximately 43% more DNA than the wheat chromatin it is replacing. Thus, the small DNA difference previously reported by flow cytometry was demonstrated to be a real DNA variation due to the presence of small fragments of alien chromosomes added to the wheat genome.     

The nucleoli matrix proteins with molecular masses 40 and 27 kDa are transported as peripheral chromosomal material

Using immunofluoresence method, sera M-311 and K-30 obtained from patients with autoimmune disease were shown to stain interphase nuclei and the periphery of chromosomes. Western blotting revealed a polypeptide with mol. mass 27 kDa in serum K-30. Both proteins were localized in the karyoplasm. One of them (27 kDa) has a diffuse form and contains small granules, while the other (40 kDa) is in the form of small clearly outlined granules. Both proteins are also revealed around the nucleolar periphery, making a continental ring, while the main part of the nucleolus remains unstained. During pro- and metaphase, these proteins were associated with the chromosomal periphery: 27 kDa protein formed separate groups, and 40 kDa protein was seen over the whole chromosomal periphery. After nuclear and chromosomal decondensation, induced by hypotonic treatment (15% of culture medium solution), both antibodies stain diffusively interphase nuclei, but in mitotic cells they stained the surface of the swollen chromosomes. After chromatin recondensation in isotonic medium these proteins were localized similarly as in normal cells. Thus, both proteins maintained their association with the periphery of chromosomes. To reveal the nuclear protein matrix, cells were treated with 2M NaCl, DNAase and RNAase A. After this procedure, the antibodies stained only the nucleolar periphery, and no fluorescence in the karyoplasm was seen. It shows that of all the components of the nuclear protein matrix (lamina, internuclear network, residual nucleoli) only 27 and 40 kDa proteins are contained in the nucleolar rim. The data allow to suggest that the nucleolar matrix proteins may be transported to new cell nuclei as part of the peripheral chromosomal material likely as other nucleolar (fibrillarin, B-23, and others) or some non-nuclear components of the nuclear protein matrix are transported.     

Structural Maturation of the Transmissible Gastroenteritis Coronavirus

During the life cycle of the transmissible gastroenteritis coronavirus (TGEV), two types of virus-related particles are detected in infected swine testis cells: large annular viruses and small dense viruses. We have studied the relationships between these two types of particles. Immunoelectron microscopy showed that they are closely related, since both large and small particles reacted equally with polyclonal and monoclonal antibodies specific for TGEV proteins. Monensin, a drug that selectively affects the Golgi complex, caused an accumulation of large annular viral particles in perinuclear elements of the endoplasmic reticulum-Golgi intermediate compartment. A partial reversion of the monensin blockade was obtained in both the absence and presence of cycloheximide, a drug that prevented the formation of new viral particles. After removal of monensin, the Golgi complex recovered its perinuclear location, and a decrease in the number of perinuclear large viral particles was observed. The release of small dense viral particles into secretory vesicles and the extracellular medium was also observed, as was a partial recovery of infectivity in culture supernatants. Small viral particles started to be seen between the third and the fourth Golgi cisternae of normally infected cells. All of these data strongly indicate that the large annular particles are the immature precursors of the small dense viruses, which are the infectious TGEV virions. The immature viral particles need to reach a particular location at the trans side of the Golgi stack to complete their morphological maturation.