Nucleosomelike structures associated with chromosomes of the archaebacterium Halobacterium salinarium.

Chromosomes of the halophilic archaebacterium Halobacterium salinarium were examined by electron microscopy after being spread onto water. The major part of the chromosomal DNA was associated with protein particles with diameter of 9.4 nm, arranged tandemly along the DNA fibers. Thus, the primary structure of the chromosome resembles that of eucaryote chromosomes.     

Intermediate structure between chromatin fibers and chromosome revealed by mechanical stretching and SPM measurement

The morphology of chromosomes (certain rod-shaped structures) is highly reproducible despite the high condensation of chromatin fibers (∼1 mm) into chromosomes (∼1 μm). However, the mechanism underlying the condensation of chromatin fibers into chromosomes is unclear. We assume that investigation of the internal structure of chromosomes will aid in elucidating the condensation process. In order to observe the detailed structure of a chromosome, we stretched a human chromosome by using a micromanipulator and observed its morphology along the stretched region by scanning probe microscopy (SPM). We found that the chromosome consisted of some fibers that were thicker than chromatin fibers. The found fiber was composed of approximately 90-nm-wide beads that were linked linearly. To explore the components of the fiber, we performed immunofluorescence staining of the stretched chromosome. Fluorescence signals of topoisomerase (Topo) IIα, which is known to interact with and support chromatin fibers, and DNA were detected both on the found fiber and beads. Furthermore, after micrococcal nuclease and trypsin treatments, the fibers were found to be mechanically supported by proteins. These results suggest that chromosome comprises an intermediate structure between chromatin fibers and chromosomes.     

Direct visualization of the genomic distribution and organization of two cervid centromeric satellite DNA families

Several repetitive DNA fragments were generated from PCR amplifications of caribou DNA using primer sequences derived from the white-tailed deer satellite II DNA clone OvDII. Two fragments, designated Rt-0.5 and Rt-0.7, were sequenced and found to have 96% sequence similarity. These caribou clones also had 85% sequence similarity with OvDII. Multiple-colored fluorescence in situ hybridization (FISH) studies with satellite I and satellite II DNA probes to caribou metaphase chromosomes and extended chromatin fibers provided direct visualization of the genomic organization of these two satellite DNA families, with the following findings: (1) Cervid satellite I DNA is confined to the centromeric regions of the acrocentric autosomes, whereas satellite II DNA is found at the centromeric regions of all chromosomes except for the Y. (2) For most acrocentric chromosomes, the satellite I signal appeared to be medially located at the primary constriction, in contrast to that of satellite II, which appeared to be oriented toward the lateral sides as two separate fluorescent dots. (3) The satellite II clone Rt-0.7 appeared to be enriched in the centromeric region of the caribou X chromosome, a pair of biarmed autosomes, and a number of other acrocentric autosomes. (4) Fiber-FISH demonstrated that the satellite I and satellite II arrays were juxtaposed. On highly extended chromatin fibers, the total length of the hybridization signals for the two satellite DNA arrays often reached 300-400 microm. The length of a given satellite II array usually reached 200 microm, corresponding to 2 x 10(3) kb of DNA in a given centromere.     

Ultrastructural analysis of chromatin in meiosis I + II of rye (Secale cereale L.)

Scanning electron microscopy (SEM) proves to be an appropriate technique for imaging chromatin organization in meiosis I and II of rye (Secale cereale) down to a resolution of a few nanometers. It could be shown for the first time that organization of basic structural elements (coiled and parallel fibers, chromomeres) changes dramatically during the progression to metaphase I and II. Controlled loosening with proteinase K (after fixation with glutaraldehyde) provides an enhanced insight into chromosome architecture even of highly condensed stages of meiosis. By selective staining with platinum blue, DNA content and distribution can be visualized within compact chromosomes as well as in a complex arrangement of fibers. Chromatin interconnecting threads, which are typically observed in prophase I between homologous and non-homologous chromosomes, stain clearly for DNA. In zygotene transversion of chromatid strands to their homologous counterparts becomes evident. In pachytene segments of synapsed and non-synapsed homologs alternate. At synapsed regions pairing is so intimate that homologous chromosomes form one filament of structural entity. Chiasmata are characterized by chromatid strands which traverse from one homolog to its counterpart. Bivalents are characteristically fused at their telomeric regions. In metaphase I and II there is no structural evidence for primary and secondary constrictions.     

The location of repeated DNA sequences in the chromosomes of Chironomus tentans

Polytene chromosomes of Chironomus tentans were hybridized in situ with in vivo labelled nuclear and chromosomal RNA. Nuclear RNA formed hybrids preferentially in five distinct regions considered to contain clustered, repeated DNA sequences. These are the two nucleolar organizer regions, Balbiani ring 1 and 2, and the 5 S RNA genes in region 2A of chromosome II, which together comprised almost 70% of the total number of grains over the complement. The remaining grains were diffusely distributed over the chromosomes. There was a significant difference in the distribution of grains when RNA from different chromosomes was used for hybridization. Chromosome I RNA hybridized preferentially with chromosome I, and chromosome II+III RNA preferentially with chromosome II+III. Some regions within the chromosomes hybridized significantly more chromosomal RNA than other regions. A considerable cross-hybridization of RNA from one particular type of chromosome with the other chromosomes was also found. It is concluded that repeated DNA sequences which hybridize with heterogeneous chromosomal RNA in C. tentans are widely dispersed in the genome. Some of these sequences have a delimited localization, others are dispersed, and some sequences which are transcribed in one particular chromosome are present also in the other chromosomes.     

Formation of a centromere-specific chromatin structure

The kinetochore is formed on centromeric DNA as a key interface with microtubules from the mitotic spindle to achieve accurate chromosome segregation during mitosis. However, in contrast to other regions of the chromosome, the position of the kinetochore is specified by sequence-independent epigenetic mechanisms. Most recent work on kinetochore specification has focused on the centromere-specific histone H3-variant CENP-A. Whereas CENP-A is an important epigenetic marker for the kinetochore specification, it is unclear how centromeric chromatin structure is organized. To understand centromeric chromatin structure, we focused on additional centromere proteins that have an intrinsic DNA binding activity and identified the DNA binding CENP-T-W-S-X complex. Tetramer formation of CENP-T-W-S-X is essential for functional kinetochore assembly in vertebrate cells. Our structural and biochemical analysis reveals that the CENP-T-W-S-X complex is composed of four histone-fold domains with structural similarity to nucleosomes and displays DNA supercoiling activity. These results suggest that the CENP-T-W-S-X complex forms a unique nucleosome-like structure at centromeric chromatin. In addition, CENP-S and CENP-X function at non-centromeric sites. The intriguing histone-like properties of these proteins suggest that they may form nucleosome-like structures at various genome loci, extending the chromatin code beyond classical histone variants.     

The three-dimensional fine structure of chromosomes in a prophaseDrosophila nucleus

It has been possible to identify the chromosomes in electron micrographs of a prophase neuroblast nucleus inDrosophila melanogaster by using stereophotographs of stacked transparencies made from serial sections. Depth was determined by increasing or decreasing the stereo angle. Identification was facilitated by the use of a stock carrying chromosomal rearrangements. In this stock only chromosome 2 is metacentric. Compound chromosomes [symbolized C(3L)RM and C(3R)RM] were formed from the left and from the right arms of chromosome 3, and the X chromosome was intercalated in an inverted position between the two arms of the Y (Y^SX·Y^L).—Three-dimensional aspects of the ultrastructure of these chromosomes were observed as follows. The compacted centric regions are composed of fibers coiled in irregular gyres. In the extended regions, the fibers subdivide and appear uncoiled except for regions of compaction—“chromomeres”—which are seen in both homologues. Each homologue appears to be composed of four fibers of 130 Å diameter, a total of eight for the prophase chromosome. Since the larger neuroblast cells are 8C in the G2 phase, it would seem that the 130 Å fiber is equivalent to the cytological chromatid.     

Direct visualization of the sites of DNA methylation in human,and mosquito chromosomes

Human and mosquito fixed chromosomes were digested with restriction endonucleases that are inhibited by the presence of 5-methylcytosine in their restriction sites (Hha I, Hin PI, Hpa II), and with endonucleases for which cleavage is less dependent on the state of methylation (Taq I, Msp I). Methylation-dependent enzymes extracted low DNA amounts from human chromosomes, while methylation-independent enzymes extracted moderate to high amounts of DNA. After DNA demethylation with 5-azacytidine the isoschizomers Hpa II (methylation-dependent) and Msp I (methylation-independent) extracted 12-fold and 1.4-fold amounts of DNA from human chromosomes, respectively. These findings indicate that human DNA has a high concentration of Hpa II and Msp I restriction sites (CCGG), and that the internal C of this sequence is methylated in most cases, while the external cytosine is methylated less often. All the enzymes tested released moderate amounts of DNA from mosquito chromosomes whether or not the DNA was demethylated with 5-azacytidine. Hpa II induced banding in the centromere chromosome regions. After demethylation with 5-azacytidine this banding disappeared. Mosquito DNA has therefore, moderate to high frequencies of nonmethylated CpG duplets. The only exception is the centromeric DNA, in which the high levels of C methylation present produce cleavage by Hpa II and the appearance of banding. Centromere regions of human chromosomes 1 have a moderately low concentration of Hpa II-Msp I restriction sites.     

Structural organization of rat hepatocyte chromatin as visualized in thin frozen sections selectively stained for DNA

We studied the structure of rat hepatocyte chromatin in situ using thin frozen sections selectively stained for DNA after aldehyde fixation. Our results indicate that intranucleolar chromatin is arranged into three different organization levels, confirming the observations on Epon-embedded chromatin. These are: completely extended DNA filaments, with a thickness of approximately 3 nm, clustered in loose, roundish agglomerates, very long fibers with a thickness ranging from 15 to 35 nm and compact chromatin clumps. Both the fibers and the chromatin clumps frequently appeared to be composed of nucleosome-like particles. In the extranucleolar chromatin, agglomerates of extended DNA filaments and long fibers were never visualized. In contrast to data from Epon-embedded chromatin, we noticed that in frozen sections neither the nucleolar nor the extranucleolar compact chromatin appear to be organized into discrete, 20 to 30 nm superordered fibers.     

Homologous pairing between nucleosome cores on a linear duplex DNA and nucleoprotein filaments of RecA protein-single stranded DNA.

The ability of E coli recA protein to promote homologous pairing with linear duplex DNA bound to HU protein (Nucleosome cores) was found to be differentially affected. The formation of paranemic joint molecules was not affected whereas the formation of plectomic joint molecules was inhibited from the start of the reaction. The formation of paranemic joint molecules between nucleoprotein filaments of recA protein-circular single stranded DNA and closed circular duplex DNA is believed to generate positive supercoiling in the duplex DNA. We found that the positively superhelical duplex DNA was inert in the formation of joint molecules but could be converted into an active substrate, in situ, by the action of wheat germ topoisomerase I. These observations initiate an understanding of the structural features of E coli chromosome such as DNA supercoiling and nucleosome-like structures in homologous recombination.     

Teniposide, a topoisomerase II inhibitor, prevents chromosome condensation and separation but not decondensation in fertilized surf clam (Spisula solidissima) oocytes

DNA topoisomerase II has been implicated in regulating chromosome interactions. We investigated the effects of the specific DNA topoisomerase II inhibitor, teniposide on nuclear events during oocyte maturation, fertilization, and early embryonic development of fertilized Spisula solidissima oocytes using DNA fluorescence. Teniposide treatment before fertilization not only inhibited chromosome separation during meiosis, but also blocked chromosome condensation during mitosis; however, sperm nuclear decondensation was unaffected. Chromosome separation was selectively blocked in oocytes treated with teniposide during either meiotic metaphase I or II indicating that topoisomerase II activity may be required during oocyte maturation. Teniposide treatment during meiosis also disrupted mitotic chromosome condensation. Chromosome separation during anaphase was unaffected in embryos treated with teniposide when the chromosomes were already condensed in metaphase of either first or second mitosis; however, chromosome condensation during the next mitosis was blocked. When interphase two- and four-cell embryos were exposed to topoisomerase II inhibitor, the subsequent mitosis proceeded normally in that the chromosomes condensed, separated, and decondensed; in contrast, chromosome condensation of the next mitosis was blocked. These observations suggest that in Spisula oocytes, topoisomerase II activity is required for chromosome separation during meiosis and condensation during mitosis, but is not involved in decondensation of the sperm nucleus, maternal chromosomes, and somatic chromatin.     

Tropomyosin is localized in the nuclear matrix and chromosome scaffold of physarum polycephalum

The nuclei and chromosomes were isolated from plasmodia of Physarum polycephalum.The nuclear matrix and chromosome scaffold were obtained after the DNA and most of the proteins were extracted with DNase I and 2 M NaCl.SD-PAGE analyses revealed that the nuclear matrix and chromosome scaffold contained a 37 kD polypeptide which is equivalent to tropomyosin in molecular weight.Immunofluorescence observations upon slide preparations labeled with anti-tropomyosin antibody showed that the nuclear matrix and chromosome scaffold emanated bright fluorescence,suggesting the presence of the antigen in them.Immunodotting results confirmed the presence of tropomyosin in the nuclear matrix and chromosome scaffold.Immunoelectron microscopic observations further demonstrated that tropomyosin was dispersively distributed in the interphase nuclei and metaphase chromosomes.     

Elementary structures in polytene chromosomes of Drosophila melanogaster

Whole-mounted polytene chromosomes were isolated from nuclei by microdissection in 60% acetic acid and analyzed by electron microscopy. Elementary chromosome fibers in the interchromomeric regions and individual chromomeres can be distinguished in polytene chromosomes at low levels of polyteny (2⁶–2⁷ chromatids). Elementary fibers in the interbands are oriented parallel to the axis of the polytene chromosome. Their number roughly corresponds to the expected level of polyteny. These fibers have an irregular beaded structure, 100–300 Å in diameter, and there is no apparent lateral association between them in the interchromomeric regions. Most bands, in contrast, form continuous structures crossing the entire width of the chromosome. Polytene chromosomes isolated in 2% or 10% acetic acid can be reversibly dispersed in a solution for chromatin spreading. The spread chromosomes consist of long uniform deoxyribonucleoprotein (DNP) fibers with a nucleosome structure. This supports the notion that continuous DNA molecules extend through the entire length of a polytene chromosome and that the nucleosome structure exists both in bands and interbands. Analysis of the band shape and of the fibrillar pattern in the interbands emphasizes that the polytene chromosome assumes a ribbonlike structure from which the more complex three-dimensional structure of the polytene chromosome at higher levels of polyteny develops.     

Studies on dinoflagellate chromosomal basic protein

Routine cytochemical methods proved useless in demonstrating basic protein in dinoflagellate chromosomes because when the DNA was removed, these chromosomes dissolved away just as eubacterial nucleoids. However, with ammoniacal silver technique or alkaline Biebrich scarlet, DNA could be kept intact, all the dinoflagellate chromosomes examined gave positive reaction. The acid-soluble proteins were extracted from methanol-fixed Amphidinium carterae and methanol-fixed isolated nuclei of Noctiluca miliaris, and subjected to urea polyacrylamide gel electrophoresis. Only one band of basic protein co-migrating with histone H4 was found. The chromosomes of Oxyrrhis marina can retain their original forms after the removal of DNA. Their chromosomal basic protein can be demonstrated by various cytochemical methods. This protein co-migrates with histone H4 in urea gel too. Its amino acid composition has been determined. This protein can combine with DNA fibril to form a nucleosome-like structure which seems to be corresponding to two of the archaebacterial nucleosome-like structures and may represent the primitive nucleosome.     

Structural paradox of polytene chromosomes

The observation of thick chromatin fibers in interbands of Dipteran polytene chromosomes suggests that there should be 5 to 10 times more mass and DNA in interbands than is commonly thought to be present. To resolve this paradox, the chromatin content of interbands was estimated, using whole-mounted polytene chromosomes from Drosophila melanogster. Densitometry of high voltage electron microscopic negatives provides an estimate of less than 4:1 for the average ratio of cross-sectional dry mass (or mass per unit chromosome length) of bands relative to interbands. This ratio, combined with an estimate of the length of chromosome composed of interbands, indicates that at least 26% of chromosome mass is contributed by interband chromatin. Since DNA comprises a similar proportion of chromatin mass in bands and interbands (Laird et al., 1980b), these data imply that DNA sequences in interbands represent at least 26% of the euchromatic genome of D. melanogaster. This result calls for reinterpretation of some of the genetic and molecular data from Diptera. The discrepancy between this higher estimate of interband mass and DNA, and previous estimates of 3-5%, is discussed. One possibility is that previous measurements were made on prominent interbands, which are proposed here to be in regions that are delayed in DNA replication. Such interbands would be reduced in polyteny and DNA content compared with the average interband region. The concept of local variations in polyteny is also used here to explain major differences in the cross-sectional mass of bands. This leads to a revised model of polytene chromosomes in which at least three levels of polyteny, rather than one or two levels, can be present within one euchromatic region.     

Relationship between relative dry mass and average band width in regions of polytene chromosomes of Drosophila

Whole-mounted polytene chromosomes from Drosophila melanogaster were prepared for high-voltage electron microscopy. Relative dry mass of chromosome regions was estimated by densitometry of electron microscopic negatives. Comparison of dry mass of regions of the male X chromosome with that of regions of associated autosomes established that dry mass values are proportional to DNA content. Relative dry mass values of regions of polytene chromosomes from salivary glands, fat body, and malpighian tubules were correlated with the average diameter of bands in these regions: as mass doubled, band width increased by a factor of approximately 2. To provide a standard for estimating absolute levels of polyteny, band widths were measured for chromosomes representing one major polytene class, 256n. These chromosomes were observed to have an average band width of 0.9 m — These observations provide limits to models of chromatin organization in bands. For each chromatid, this area can accommodate up to five chromatin fibers of 250 Å diameter. This value may represent the extent of folding of a chromatin fiber in an average band. Alternatively, a chromatin fiber of higher-order structure could have a maximum diameter of 560 Å in an average band.     

Nucleoid structure and partition in Methanococcus jannaschii: an archaeon with multiple copies of the chromosome.

We measured different cellular parameters in the methanogenic archaeon Methanococcus jannaschii. In exponential growth phase, the cells contained multiple chromosomes and displayed a broad variation in size and DNA content. In most cells, the nucleoids were organized into a thread-like network, although less complex structures also were observed. During entry into stationary phase, chromosome replication continued to termination while no new rounds were initiated: the cells ended up with one to five chromosomes per cell with no apparent preference for any given DNA content. Most cells in stationary phase contained more than one genome equivalent. Asymmetric divisions were detected in stationary phase, and the nucleoids were found to be significantly more compact than in exponential phase.     

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.     

The structure of a mesokaryote chromosome

Condensed and dispersed forms of the chromosomes of the dinoflagellate, Prorocentrum micans, deposited on grids by the microcentrifugation technique were studied by electron microscopy. In the normally condensed form, the chromosomes appear as banded rods surrounded by a peripheral cloud of partially dispersed fibers. Single fibers in these and in extensively dispersed preparations appear as smooth threads of uniform diameter (55–65 Å). The chromosome fibers are contrasted by positive-group-specific stains, indicating the presence of cationic moieties associated with the DNA. Occasionally Y-shaped chromosomes are seen; these may be replicating structures. These observations are in general agreement with studies of dinoflagellate chromosomes by other techniques, and provide support for the suggestion that these organisms possess a genome organization whose structure is typical of neither prokaryotes nor eukaryotes, and hence may be intermediate forms.