Spatial arrangement and macrodomain organization of bacterial chromosomes

Recent developments in fluorescence microscopy have shown that bacterial chromosomes have a defined spatial arrangement that preserves the linear order of genes on the genetic map. These approaches also revealed that large portions of the chromosome in Escherichia coli or Bacillus subtilis are concentrated in the same cellular space, suggesting an organization as large regions defined as macrodomains. In E. coli, two macrodomains of 1 Mb containing the replication origin (Ori) and the replication terminus (Ter) have been shown to relocalize at specific steps of the cell cycle. A genetic analysis of the collision probability between distant DNA sites in E. coli has confirmed the presence of macrodomains by revealing the existence of large regions that do not collide with each other. Two macrodomains defined by the genetic approach coincide with the Ori and Ter macrodomains, and two new macrodomains flanking the Ter macrodomain have been identified. Altogether, these results indicate that the E. coli chromosome has a ring organization with four structured and two less-structured regions. Implications for chromosome dynamics during the cell cycle and future prospects for the characterization and understanding of macrodomain organization are discussed.     

Satellite DNA and evolution of sex chromosomes

The satellite DNA (satellite III) which is mainly represented in the female of Elaphe radiata (Ophidia, Colubridae) has been isolated and its buoyant density has been determined (=1.700 g cm^–3). In situ hybridisation of radioactive complementary RNA of this satellite DNA with the chromosomes of different species has revealed that it is mainly concentrated on the W sex chromosome and its sequences are conserved throughout the sub-order Ophidia. From hybridisation studies these sequences are absent from the primitive family Boidae which represents a primitive state of differentiation of sex chromosomes. Chromosome analysis and C-banding have also revealed the absence of heteromorphism and of an entirely heterochromatic chromosome in the species belonging to the primitive family and their presence in the species of highly evolved families. It is suggested that the origin of satellite DNA (satellite III) in the W chromosome is the first step in differentiation of W from the Z in snakes by generating asynchrony in the DNA replication pattern of Z and W chromosomes and thus conceivably reducing the frequency of crossing-over between them which is the prerequisite of differentiation of sex chromosomes. Presence of similar sex chromosome associated satellite DNA in domestic chicken suggests its existence in a wider range of vertebrates than just the snakes.     

Analysis of replication patterns in chromosomes of normal Chinese hamster and its cell lines

Replication patterns of the normal male Chinese hamster chromosomes and the three cell lines CHW, 1102 and 1103, were determined using fluorescent, plus Giemsa or acridine orange, techniques. The individual chromosomes or chromosomal segments were consistent in the replication patterns of normal Chinese hamster chromosomes and all the transformed cell lines. Late DNA replication was regularly identified in the long arm of the X chromosome, the entire Y chromosome, the short arms of chromosomes 6 and 7, and the paracentromeric regions of chromosomes 8, 9 and 10. A similar consistency was demonstrated in the large late replicating areas of chromosomes X and Y. Each cell line had specific marker chromosomes by which the cell line was identified and their replication patterns have been described. The chromosome analysis in cell line 1103 indicated that chromosomes 2, 3, 8 and 9 were more stable than others, of which chromosome 2 was extremely stable. The markers M4 and M5 in cell line 1103 are very interesting. The cytogenetic behaviour of marker M4 indicated a new phenomenon of translocation by simple association. The marker chromosome M5 indicated that inactivation spread to the early replicating distal region. These cell lines are very useful tools for studying replication patterns and providing a basic understanding of mammalian cytogenetics.     

DNA hypomethylation causes an increase in DNase-I sensitivity and an advance in the time of replication of the entire inactive X chromosome

Summary We have examined the effect of 5-azacytidine (5-aza-C) induced hypomethylation of DNA on the time of replication and DNase I sensitivity of the X chromosomes of female Gerbillus gerbillus (rodent) lung fibroblast cells. Using in situ nick translation to visualise the potential state of activity of large regions of metaphase chromosomes we show that 5-aza-C causes a dramatic increase in the DNase-I sensitivity of the entire inactive X chromosome of female G. gerbillus cells and this increase in nuclease sensitivity correlates with a large shift in the time of replication of the inactive X chromosome from late S phase to early S phase. These effects of 5-aza-C on the inactive X chromosome are associated with a 15% decrease in DNA methylation. Our results indicate that DNA methylation concomitantly affects both the time of replication and the chromatin conformation of the inactive X chromosome.     

Late replicating bands of human chromosomes demonstrated by fluorochrome and Giemsa staining.

The addition of thymidine (TdR) to cells growing in a medium containing 5-bromodeoxyuridine (BUdR) at the end of the first replication cycle results in the incorporation of TdR into the late replicating DNA regions. These sites can be visualized by staining the metaphase chromosomes with the fluorescent dye "33258 Hoechst" or a "33258 Hoechst" Giemsa procedure. A sequence of late replication patterns has been established in metaphase chromosomes of cultured human peripheral lymphocytes. The patterns are in agreement with those obtained by the standard autoradiographic procedures, but are more accurate. As is known from autoradiography, late replicating bands are in the position of G or Q bands. The "33258 Hoechst" Giemsa staining procedure of chromosomes which have replicated in the presence of BUdR first and in TdR for the last 2 hrs of the S phase is preferable to the currently used Giemsa banding techniques: the method yields very well banded metaphases in all preparations examined, as the chromosome structure is not disrupted by the pretreatment. The bands are very distinct, even in the "difficult" chromosomes (e.g. No. 4, 5, 8 and X). In female cells the late replicating X chromosome can be identified by its size and staining pattern. In addition to the replication asynchrony, the sequence of replication within both X chromosomes in female cells is not absolutely identical. The phenomenon of a phase difference in replication between the homologues is not a peculiarity of the X chromosome, but can be found in all autosomes as well as in homologous positions on the chromatids of individual chromosomes.     

The role of DNA replication in chromosome condensation

At metaphase, DNA in a human chromosome is estimated to be compacted at least 10,000 fold in length. However, the higher order mechanisms by which the chromosomes are organized in interphase and subsequently further condensed in mitosis have largely remained elusive. One generally overlooked participant in chromosome condensation is DNA replication. Many early studies of eukaryotic chromosome organization and cell fusions have suggested that DNA replication plays a role in chromosome compaction. Recent phenotypic analysis of Drosophila DNA replication mutants has revitalized this old idea. In this review, the role of DNA replication in chromosome condensation will be examined.     

Asynchronous Replication,Mono-Allelic Expression,and Long Range Cis-Effects of ASAR6

Mammalian chromosomes initiate DNA replication at multiple sites along their length during each S phase following a temporal replication program. The majority of genes on homologous chromosomes replicate synchronously. However, mono-allelically expressed genes such as imprinted genes, allelically excluded genes, and genes on female X chromosomes replicate asynchronously. We have identified a cis-acting locus on human chromosome 6 that controls this replication-timing program. This locus encodes a large intergenic non-coding RNA gene named Asynchronous replication and Autosomal RNA on chromosome 6, or ASAR6. Disruption of ASAR6 results in delayed replication, delayed mitotic chromosome condensation, and activation of the previously silent alleles of mono-allelic genes on chromosome 6. The ASAR6 gene resides within an ∼1.2 megabase domain of asynchronously replicating DNA that is coordinated with other random asynchronously replicating loci along chromosome 6. In contrast to other nearby mono-allelic genes, ASAR6 RNA is expressed from the later-replicating allele. ASAR6 RNA is synthesized by RNA Polymerase II, is not polyadenlyated, is restricted to the nucleus, and is subject to random mono-allelic expression. Disruption of ASAR6 leads to the formation of bridged chromosomes, micronuclei, and structural instability of chromosome 6. Finally, ectopic integration of cloned genomic DNA containing ASAR6 causes delayed replication of entire mouse chromosomes.     

Addition of telomere-associated HeT DNA sequences "heals" broken chromosome ends in Drosophila

Stocks of D. melanogaster X chromosomes carrying terminal deletions (RT chromosomes) have been maintained for several years. Some of the chromosomes are slowly losing DNA from the broken ends (as expected if replication is incomplete) and show no telomere-associated DNA added to the receding ends. Two stocks carry chromosomes that have become "healed" and are no longer losing DNA. In both stocks the broken chromosome end has acquired a segment of HeT DNA, a family of complex repeats found only at telomeres and in pericentric heterochromatin. Although the HeT family is complex, the HeT sequence joined to the broken chromosome end is the same in both stocks. In contrast, the two chromosomes are broken in different places and have no detectable sequence similarity at the junction with the new DNA. Sequence analysis suggests that the new telomere sequences have been added by a specific mechanism that does not involve homologous recombination.     

The chromosomes of CHO,an aneuploid Chinese hamster cell line: G-band,C-band,and autoradiographic analyses

Chinese hamster ovary cells (line CHO) have been used extensively for metabolic, genetic, and radiobiological studies with only a superficial appreciation for the degree of aneuploidy characteristic of the line. A thorough karyologic analysis of CHO chromosomes using autoradiographic replication patterns, as well as centromere band (C-band) and Giemsa band (G-band) analysis, is presented. Our results demonstrate that only 8 of the 21 CHO chromosomes are normal when compared with euploid Chinese hamster chromosomes. In the 13 altered chromosomes, we found evidence of translocations, deletions, and pericentric inversions. These altered chromosomes have been characterized with respect to both origin and destination of translocated material. With the exception of the X₂ chromosome, essentially all of the euploid chromatin is present in CHO cells. Autoradiographic replication patterns show that the normal sequence of chromosomal DNA synthesis is altered. Some sites which replicate late in euploid cells replicate early in CHO, and several late-replicating chromosomes in CHO cells replicate in early- or mid-S in euploid material. These studies may serve to elucidate the observed differences in mutagenic behavior between euploid fibroblasts and CHO cells.     

Smc5/6-mediated regulation of replication progression contributes to chromosome assembly during mitosis in human cells

The structural maintenance of chromosomes (SMC) proteins constitute the core of critical complexes involved in structural organization of chromosomes. In yeast, the Smc5/6 complex is known to mediate repair of DNA breaks and replication of repetitive genomic regions, including ribosomal DNA loci and telomeres. In mammalian cells, which have diverse genome structure and scale from yeast, the Smc5/6 complex has also been implicated in DNA damage response, but its further function in unchallenged conditions remains elusive. In this study, we addressed the behavior and function of Smc5/6 during the cell cycle. Chromatin fractionation, immunofluorescence, and live-cell imaging analyses indicated that Smc5/6 associates with chromatin during interphase but largely dissociates from chromosomes when they condense in mitosis. Depletion of Smc5 and Smc6 resulted in aberrant mitotic chromosome phenotypes that were accompanied by the abnormal distribution of topoisomerase IIα (topo IIα) and condensins and by chromosome segregation errors. Importantly, interphase chromatin structure indicated by the premature chromosome condensation assay suggested that Smc5/6 is required for the on-time progression of DNA replication and subsequent binding of topo IIα on replicated chromatids. These results indicate an essential role of the Smc5/6 complex in processing DNA replication, which becomes indispensable for proper sister chromatid assembly in mitosis.     

Is the MCM2-7 complex the eukaryotic DNA replication fork helicase?

The MCM2-7 complex is essential for both the initiation and elongation phases of eukaryotic chromosome replication. There is some evidence that MCM2-7 proteins may act as a DNA helicase; at the same time, a variety of other DNA helicases have also been implicated in the replication of eukaryotic chromosomes.     

Origin recognition and the chromosome cycle

Prior to the initiation of DNA replication, chromosomes must establish a biochemical mark that permits the recruitment in S phase of the DNA replication machinery that copies DNA. The process of chromosome replication in eukaryotes also must be coordinated with segregation of the duplicated chromosomes to daughter cells during mitosis. Protein complexes that utilize ATP coordinate events at origins of DNA replication and later they participate in the initiation of DNA replication. In eukaryotes, some of these proteins also play a part in later processes that ensure accurate inheritance of chromosomes in mitosis, including spindle attachment of chromosomes, accurate duplication of centrosomes and cytokinesis. A perspective of how ATP-dependent proteins accomplish this task in eukaryotes is discussed.     

Identification and characterization of the dif Site from Bacillus subtilis

Bacteria with circular chromosomes have evolved systems that ensure multimeric chromosomes, formed by homologous recombination between sister chromosomes during DNA replication, are resolved to monomers prior to cell division. The chromosome dimer resolution process in Escherichia coli is mediated by two tyrosine family site-specific recombinases, XerC and XerD, and requires septal localization of the division protein FtsK. The Xer recombinases act near the terminus of chromosome replication at a site known as dif (Ecdif). In Bacillus subtilis the RipX and CodV site-specific recombinases have been implicated in an analogous reaction. We present here genetic and biochemical evidence that a 28-bp sequence of DNA (Bsdif), lying 6 degrees counterclockwise from the B. subtilis terminus of replication (172 degrees ), is the site at which RipX and CodV catalyze site-specific recombination reactions required for normal chromosome partitioning. Bsdif in vivo recombination did not require the B. subtilis FtsK homologues, SpoIIIE and YtpT. We also show that the presence or absence of the B. subtilis SPbeta-bacteriophage, and in particular its yopP gene product, appears to strongly modulate the extent of the partitioning defects seen in codV strains and, to a lesser extent, those seen in ripX and dif strains.     

MAMMALIAN CHROMOSOMES IN VITRO : XVIII. DNA Replication Sequence in the Chinese Hamster

The complete DNA replication sequence of the entire complement of chromosomes in the Chinese hamster may be studied by using the method of continuous H³-thymidine labeling and the method of 5-fluorodeoxyuridine block with H³-thymidine pulse labeling as relief. Many chromosomes start DNA synthesis simultaneously at multiple sites, but the sex chromosomes (the Y and the long arm of the X) begin DNA replication approximately 4.5 hours later and are the last members of the complement to finish replication. Generally, chromosomes or segments of chromosomes that begin replication early complete it early, and those which begin late, complete it late. Many chromosomes bear characteristically late replicating regions. During the last hour of the S phase, the entire Y, the long arm of the X, and chromosomes 10 and 11 are heavily labeled. The short arm of chromosome 1, long arm of chromosome 2, distal portion of chromosome 6, and short arms of chromosomes 7, 8, and 9 are moderately labeled. The long arm of chromosome 1 and the short arm of chromosome 2 also have late replicating zones or bands. The centromeres of chromosomes 4 and 5, and occasionally a band on the short arm of the X are lightly labeled.     

Patterns of DNA replication of human chromosomes. II. Replication map and replication model.

Combining higher resolution chromosome analysis and bromodeoxyuridine (BrdU) incorporation, our study demonstrates that: (1) Human chromosomes synthesize DNA in a segmental but highly coordinated fashion. Each chromosome replicates according to its innate pattern of chromosome structure (banding). (2) R-positive bands are demonstrated as the initiation sites of DNA synthesis in all human chromosomes, including late-replicating chromosomes such as the LX and Y. (3) Replication is clearly biphasic in the sense that late-replicating elements, such as G-bands, the Yh, C-bands, and the entire LX, initiate replication after it has been completed in the autosomal R-bands (euchromatin) with minimal or no overlap. The chronological priority of R-band replication followed by G-bands is also retained in the facultative heterochromatin or late-replicating X chromosome (LX). Therefore, the inclusion of G-bands as a truly late-replicating chromatin type or G(Q)-heterochromatin is suggested. (4) Lateral asymmetry (LA) in the Y chromosome can be detected after less than half-cycle in 5-bromodeoxyuridine (BrdUrd), and the presence of at least two regions of LA in this chromosome is confirmed. (5) Finally, the replicational map of human chromosomes is presented, and a model of replication chronology is suggested. Based on this model, a system of nomenclature is proposed to place individual mitoses (or chromosomes) within S-phase, according to their pattern of replication banding. Potential applications of this methodology in clinical and theoretical cytogenetics are suggested.     

The bacterial nucleoid: a highly organized and dynamic structure

Recent advances in bacterial cell biology have revealed unanticipated structural and functional complexity, reminiscent of eukaryotic cells. Particular progress has been made in understanding the structure, replication, and segregation of the bacterial chromosome. It emerged that multiple mechanisms cooperate to establish a dynamic assembly of supercoiled domains, which are stacked in consecutive order to adopt a defined higher-level organization. The position of genetic loci on the chromosome is thereby linearly correlated with their position in the cell. SMC complexes and histone-like proteins continuously remodel the nucleoid to reconcile chromatin compaction with DNA replication and gene regulation. Moreover, active transport processes ensure the efficient segregation of sister chromosomes and the faithful restoration of nucleoid organization while DNA replication and condensation are in progress.