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.     

High-resolution dynamic and morphological G-bandings (GBG and GTG): a comparative study

Summary A high-resolution replication banding technique, dynamic GBG banding (G-bands after 5-bromodeoxyuridine [BrdUrd] and Giemsa), showed that, at a resolution of 850 bands/genome, GBG banding and GTG banding (G-bands after trypsin and Giemsa) produce almost identical patterns. RBG band (R-bands after BrdUrd and Giemsa) and RHG band (R-bands after heat denaturation and Giemsa) patterns were previously shown to be only 75%–85% coincident; thus GTG banding more accurately reflects replication patterns than does RHG banding. BrdUrd synchronization uses high concentrations of BrdUrd both to substitute early replicating DNA and to arrest cells before the late bands replicate. Release from the block is via a low thymidine concentration. The banding is revealed by the fluorochrome-photolysis-Giemsa (FPG) technique and produces the GBG banding that includes concomitant staining of constitutive heterochromatin. As opposed to other replication G-banding procedures, BrdUrd synchronization and GBG banding produces a reproducible replication band pattern. The discordance between homologs after GBG banding is similar to that after GTG banding and no lateral asymmetry of the constitutive heterochromatin has been observed. Also, BrdUrd synchronization neither significantly depresses the mitotic index, nor induces chromosome breaks. Thus, GBG banding seems as clinically useful as GTG banding and provides important information regarding replication time.     

Lymphoblasts already in the DNA synthesis phase of the cell cycle can be reversibly arrested at the R/G transition

Early and late S-phase of the cell cycle are separated by the R-band/G-band (R/G) transition. This corresponds to the time at which R-band synthesis has been completed while G-band synthesis has yet to begin. The aim of this work was to study cell cycle kinetics during S-phase using different blocking agents: mimosine, methotrexate, 5-fluorouracil, 5-fluoro-2'-deoxyuridine and an excess of thymidine. The stage at which these blocking agents arrest the cell cycle and their efficiency at blocking Epstein-Barr virus transformed lymphoblasts at the R/G transition were evaluated using flow cytometric techniques. Mimosine blocked 90% of the cells near the G1/S-phase boundary. Methotrexate, 5-fluoro-2'-deoxyuridine and 5-fluorouracil, and particularly thymidine, let a significant proportion of cells enter S-phase. The cells were released from the arrest state and their progression through early S-phase was monitored by flow cytometry. Before the cells reached the R/G transition, a second agent was added to inhibit cell cycle progression. For example, the use of mimosine followed by thymidine allowed up to 60% of the cells to be blocked at the R/G transition. The arrest of DNA replication at the R/G transition was confirmed by a marked decrease of 5-bromo-2'-deoxyuridine (BrdUrd) incorporation, revealed by using bivariate flow cytometric analysis. The blocking agent was then removed and the cell cohort was released in the presence of BrdUrd so that replication banding analysis could be performed on the harvested mitotic cells. This yielded a mitotic index of approximately 10% and chromosomes showing replication bands. Flow cytometric analysis combined with cytogenetic banding analysis suggested that the R/G transition is an arrest point within the S-phase of the cell cycle and allowed us to conclude that only cells that have already initiated S-phase are blocked at this point. It corresponds to a susceptible site where S-phase can be arrested easily. The R/G transition could also be a regulatory checkpoint within S-phase, a checkpoint that could respond to imbalance in deoxyribonucleotide pools.     

Dynamic G- and R-banding of human chromosomes for electron microscopy

Synchronized human lymphocytes were exposed to 5-bromo-2-deoxyuridine (BrdUrd) for incorporation in either G-or R-bands. The substituted bands were revealed by monoclonal anti-BrdUrd antibodies disclosed with either gold-labeled antibodies or with the protein A-gold complex. Sharp G-or R-banding, specific for electron microscopy (EM), was obtained. These banding patterns, referred to as GB-AAu (G-bands by BrdUrd using Antibodies and gold [Au]) and RB-AAu (R-bands by BrdUrd using Antibodies and gold [Au]), resemble dynamic band patterns (GBG and RBG) much more than they do morphologic band patterns (GTG and RHG). The G- and R- band patterns allow accurate chromosome identification and karyotyping. An actual karyotype of human GB-AAu-banded chromosomes at the 750 band level, photographed in the EM, is presented. The method produces excellent band separation and band contrast. Variations in band staining intensities were noted and correlated with BrdUrd enrichment. The C-band regions were positively stained after GB-AAu banding while they were negatively stained after RB-AAu banding. Telomeres appeared heterogeneous after GB-AAu banding suggesting that part of the telomeric bands might be late replicating.     

Location of the mouse complement factor H gene (cfh) by FISH analysis and replication R-banding.

A technique for replication R- and G-banding of mouse lymphocyte chromosomes was developed, and the replication R-banding pattern was analyzed. Optimal banding patterns were obtained with thymidine- and BrdU-treatment of lymphocytes in the same cell cycle. This produced replication R-band patterns that were the complete reverse of the G-band patterns on all chromosomes. Replication R-banding methods can be used in conjunction with nonisotopic, fluorescence in situ hybridization (FISH) to localize cloned probes to specific chromosomal bands on mouse chromosomes. with these methods the mouse complement factor H gene (cfh) was localized to the terminal portion of the F region of Chromosome 1. Q-banding patterns were also obtained by the replication R-banding method and may be useful for rapid identification of each chromosome.     

Cytogenetic replication studies with short thymidine pulses in bromodeoxyuridine-substituted chromosomes of different mouse cell lines

Summary In normal diploid fibroblasts of the mouse, 3T3-, SV-3T3-, and Meth A-cells, the chromosome replication patterns were studied by a bromodeoxyuridine (BrdU)-labelling technique. SV-3T3 is a subline of 3T3 transformed by SV 40 and Meth A is a permanent cell line from Balb c transformed by methylcholanthrene. The use of 1 h thymidine pulses permits high resolution of the S-phase after partial synchronization of the cells at G₁/S in an otherwise BrdU-substituted S-phase. It could be shown that the autosomal heterochromatin of the mouse (Mus musculus) starts replication during the early S-phase (R-band replication), continues while R-band chromatin finishes, and still replicates when G-band chromatin starts. The heterochromatin finishes before the majority of G-bands have been replicated. There is no fundamental difference in the course of chromosome replication between the different cell lines studied here. It is concluded that there are no obligate changes in the course of the S-phase linked to the process of transformation.     

Genetic activity of the G- and R-band DNA of human mitotic chromosomes

The concept of genetic inactivity of G-band DNA had been reinvestigated using the modified approach of Korenberg et al (1978). Coefficients of correlation and partial correlation between the relative gene density (g'), the relative G-band material richness (kH/C) and the relative chromosome size (s') were calculated. The kH/C was calculated as the ratio of brightness of fluorescence of chromosomes stained by Hoechst 33258 (Hi) and by chromomycin A3(Ci). The kH/C is the characteristics of G-band chromosome richness, because G-bands become bright after Hoechst 33258 staining and R-bands are bright after chromomycin A3 staining, while no significant C-bands in chromosomes which may be stained by these fluorochromes are discovered. For the kH/C determination the flow cytometry data of Langlois et al (1982) were used. The relative size of chromosomes was determined, based on the flow cytometry data of Young et al (1979). According to Korenberg, the "gene density" (g') in a chromosome was calculated as a ratio of the number of genes located in the chromosome before 1984 (Human Gene Mapping 7) to the relative size of this chromosome. Correlation between the "gene density" and the G-band richness was rs = -0.65. Out of 107 genes located in either G- or R-bands (Human Gene Mapping 7), 90 were mapped in the R-band and only 17 were ascribed to the G-band in metaphase chromosomes. The data on gene replication time show that all genes of the general cell activity and a portion of tissue-specific genes replicate during the early S-phase, together with R-band materials. These three independent lines of evidence are consistent with the notion that the R-band DNA is more genetically active than G-band DNA. The nature of "junk" DNA of G-bands is discussed.     

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.     

Studies on early replication patterns in the marsupial Sminthopsis crassicaudata: no evidence for XY replication homologies

We present here the first detailed replication banding study of a marsupial species using the BrdU-replication technique. A comparison of the structural and replication bands of the chromosomes of Sminthopsis crassicaudata clearly demonstrates that the replication behavior is the same as the described for the chromosomes of eutherians. The early replicating segments correspond to R-bands, whereas the late-replicating regions tend to be situated within Q- and C-bands. Use of this technique clearly reveals an early and late replicating X chromosome. The very small Y chromosome can be subdivided into two replication segments, but no replication homologies can be demonstrated between the X and Y chromosomes of S. crassicaudata.     

Mapping of the pattern of DNA replication in polytene chromosome from Chironomus thummi using monoclonal anti-bromodeoxyuridine antibodies

We present results from a nonautoradiographic study of DNA replication in polytene chromosomes from dipteran larvae. Monoclonal antibodies with specificity for 5-bromodeoxyuridine (BrdUrd) were used to localize by indirect immunofluorescence the sites of BrdUrd incorporation and to follow the dynamics of DNA synthesis in salivary gland cells of 4th instar Chironomus thummi larvae. This technique presents numerous advantages over autoradiographic procedures and allows mapping of DNA synthesis patterns at the level of resolution of one chromosomal band. Several replication patterns were observed, classified according to characteristic features, and tentatively assigned to specific periods of the S-phase. In early S-phase, DNA synthesis is first detectable in puffs and interbands, later in bands. Most chromosomal bands appear to initiate DNA synthesis synchronously; however, in bands within centromeric and heterochromatic regions the start of synthesis is delayed. At mid S-phase, all the bands show uniform staining. Subsequent staining patterns are increasingly differential with the bands displaying characteristic fluorescence intensities. As replication progresses through the late S-phase period, the chromosomes show a decreasing number of fluorescent bands. The last bands to terminate replication are located in centromeric and heterochromatic DNA-rich regions and a few bands of low DNA content in region IIAa-c.     

Fluorescence analysis of late DNA replication in human metaphase chromosomes.

Thymidine incorporated as a terminal pulse into chromosomes otherwise substituted with 5-bromodeoxyuridine can be detected by associated bright 33258 Hoechst fluorescence. The location of metaphase chromosome regions identified by this method as last to complete DNA synthesis is consistent with the results of autoradiographic analyses with tritiated thymidine. The very late-replicating regions correspond to a subset of those which appear as bands after chromosomes are stained by quinacrine or modified Giemsa techniques. The high resolution of the 33258 Hoechst fluorescence pattern within individual cells is especially useful for revealing variations in the order of terminal replication. Both homolog asynchrony and fluctuations in the distribution of bright 33258 Hoechst fluorescence within chromosomes from different cells are apparent and localized to individual bands. The results are consistent with the possibility that these bands constitute units of chromosome replication as well as structure.     

Cell-specific variation of X chromosome replication in the Syrian hamster (Mesocricetus auratus)

The sub-division of S-phase in Syrian hamsters, on the basis of BrdU/Hoechst 33258/Giemsa banding, has allowed a quantitative comparison of the replication of individual chromosome bands within defined subphases of S. This analysis has shown that in hamsters, as has been reported in humans, there are distinct patterns of early replication in vitro in the early X, the late X in fibroblasts, and the late X in lymphocytes. In addition, it has been possible to show that, although the pattern of replication of the late X in fibroblasts differs from that in lymphocytes, the time in S at which bands first appear on this chromosome is the same in the two cell types. — No significant heterogeneity can be ascribed to differences between individuals, adult or embryonic sources, culture media, or time of exposure to BrdU. — The absence of any detectable heterogeneity in the replication band frequencies in autosomal heterochromatic arms suggests that the cell-specific variability of the late-replicating X is a feature of facultative rather than constitutive heterochromatin.     

Chromosome replication patterns in the Djungarian hamster (Phodopus sungorus)

Patterns of early and late replication in the individual chromosomes of the Djungarian hamster (Phodopus sungorus) have been studied using the techniques of Giemsa staining suppression when bromodeoxyuridine is incorporated into the DNA. — Late replicating autosome regions correspond to G-band regions, early replication regions are less clearly demarcated but correspond to R-band regions plus some G-band zones. In part this reduction in sharpness of early replication bands may be due to the fact that nearly all metaphase G-bands contain R-band material since they are compounded from blocks of sub-G bands. — The long arm of the X chromosomes in the female differ in the start time of synthesis but are rarely separable at the close of S. There are no differences between the short arms. In the male, Y starts very late but finishes about the same time as the X which behaves like the early replicating X of the female.Visiting worker from Department of Biological Sciences, Sambulpur University, Burla 768017, India     

Analysis of DNA replication patterns of human fibroblast chromosomes the replication map

Summary A replication map of human fibroblast chromosomes from two diploid human female fibroblast lines, 46,XX and 46,X, del (X)(q13), was determined using the fluorescent plus Giemsa (FPG) technique. Each chromosome was found to stain homogeneously dark when thymidine was incorporated for the entire S phase of that particular cell. As the duration of exposure to thymidine progressively decreased by increasing the incubation time in bromodeoxyuridine, the staining intensity of chromosomes decreased and, concurrently, gaps in the staining began to appear. These gaps coincide with R bands and represent the earliest areas to complete DNA synthesis. As these areas widen and increase in frequency, first Q and G bands appear, and finally C bands.Homologous X chromosomes were easily differentiated by either a comparison of the bands present or their staining intensity. The replication kinetics of the structurally abnormal heterocyclic X chromosome were very similar to those of the normal heterocyclic X chromosome. The X chromosome with deletion of a portion of the long arm was consistently late in replication.     

Chromosome banding and compaction

Summary We have described a characteristic substructure of mitotic chromosomes, the chromosomal unit fibre, with lengths about five times the length of the corresponding metaphase chromosomes and a uniform diameter of 0.4 m. In order to study the relationship of chromosome banding to chromosome compaction, methods have been devised to obtain banding patterns on chromosomal unit fibres, similar to G-band patterns of intact mitotic chromosomes. The total number of bands plus interbands per haploid human karyotype is estimated at about 3000. The banding pattern of chromosomal unit fibres indicates a certain resemblance to the normal G-banding pattern of human chromosomes even if the details indicate a short-range random distribution.     

Tandem duplication dup(X)(q13q22) in a male proband inherited from the mother showing mosaicism of X-inactivation

Summary An aberrant X chromosome containing extra material in the long arm was observed in a psychomotoric retarded boy and his healthy, short-statured mother. The proband showed generalized muscular hypotony, growth retardation, and somatic anomalies including hypoplastic genitalia and cryptorchism.Chromosomal banding techniques suggested a tandem duplication of the segment Xq13Xq22.In the mother the vast majority of lymphocytes showed late replication of the aberrant X chromosome. Some of her cells, however, contained an apparently active aberrant X. Both the early- and late-replicating aberrant X exhibited late replication patterns very similar to those described for normal X chromosomes in lymphocytes. Asynchrony of DNA replication among the two segments Xq13Xq22 in the dup(X) was never observed.We consider that the clinical picture of the proband is caused by an excess of active X material.     

High-resolution analysis of DNA replication domain organization across an R/G-band boundary.

Establishing how mammalian chromosome replication is regulated and how groups of replication origins are organized into replication bands will significantly increase our understanding of chromosome organization. Replication time bands in mammalian chromosomes show overall congruency with structural R- and G-banding patterns as revealed by different chromosome banding techniques. Thus, chromosome bands reflect variations in the longitudinal structure and function of the chromosome, but little is known about the structural basis of the metaphase chromosome banding pattern. At the microscopic level, both structural R and G bands and replication bands occupy discrete domains along chromosomes, suggesting separation by distinct boundaries. The purpose of this study was to determine replication timing differences encompassing a boundary between differentially replicating chromosomal bands. Using competitive PCR on replicated DNA from flow-sorted cell cycle fractions, we have analyzed the replication timing of markers spanning roughly 5 Mb of human chromosome 13q14.3/q21.1. This is only the second report of high-resolution analysis of replication timing differences across an R/G-band boundary. In contrast to previous work, however, we find that band boundaries are defined by a gradient in replication timing rather than by a sharp boundary separating R and G bands into functionally distinct chromatin compartments. These findings indicate that topographical band boundaries are not defined by specific sequences or structures.     

How does inactivation change timing of replication in the human X chromosome?

Summary The kinetics of replication of the inactive (late replicating) X chromosome (LRX) were studied in karyotypically normal lymphocytes and human amniotic fluid cells. Both cell types were successively pulse labeled with 1-h or 1/2-h thymidine pulses in an otherwise BrdU-substituted S phase after partial synchronization of the cultures at G₁/S. For the first time with this technique, the entire sequence of replication was analyzed for the LRX from the beginning to the end of the S phase, with special reference to mid S (R-band to G-band transition replication). The inactive X is the last chromosome of the metaphase to start replication, with a delay of 1 or 2h, after which time a thymidine pulse results in R-type patterns. In mid S, the inactive X is the first chromosome to switch to G-type replication (without overlapping of both types and without any detectable replication pause). Until the end of S, a thymidine pulse results in G-type patterns. To rule out artifacts that might arise by the synchronization of cultures in these experiments, controls were carried out with BrdU pulses and the BrdU antibody technique without synchronization. In the course of replication, no fundamental difference was seen between the two different cell types examined. In contrast to studies using continuos labeling, this study did not reveal an interindividual difference of replication kinetics in the LRXs of the seven individuals studied; thus it is concluded that the inactive X chromosome shows only one characteristic course of replication.     

Analysis of deoxyribonucleic acid replication in human X chromosomes by fluorescence microscopy.

The genetically inactive, late-replicating human female X chromosome can be effectively distinguished from its more active, earlier-replicating homologue, when cells are grown according to the appropriate BrdU-33258 Hoechst protocol. Results obtained from a fluorescence analysis of DNA replication in X chromosomes are consistent with those from previous autoradiographic studies, but reflect additional sensitivity and resolution offered by the BrdU-Hoechst methodology. Both qualitative and quantitative differences in 33258 Hoechst fluorescence intensity, reflecting alterations in replication kinetics, can be detected between the two X chromosomes in female cells. The pattern of replication in the single X chromosome in male cells is indistinguishable from that of the early female X. Intercellular fluctuations in the distribution of regions replicating early or late in S phase, particularly with reference to the late female X, can be localized to structural bands, suggesting multifocal control of DNA synthesis in X chromosomes.     

Replication patterns of the fragile X in heterozygous carriers: analysis by a BrdUrd antibody method.

The replication status of the fragile X chromosomes was studied in short-term cultures of lymphocytes from six female heterozygous carriers. The fragile X was induced by adding 0.1 microM fluorodeoxyuridine during the last 24 h of culturing. The replication status of the X chromosomes was studied using a bromodeoxyuridine (BrdUrd) antibody method. BrdUrd was added (1) at a final concentration of 0.2 micrograms/ml during the early S phase of chromosome replication (16-10 h before harvest), (2) at 0.2 microgram/ml during the late S phase (the last 6 h of culturing), (3) at 20 micrograms/ml during the early S phase, and (4) at 20 micrograms/ml during the late S phase. BrdUrd that was incorporated into replicating chromosomes was detected by using a nuclease and BrdUrd monoclonal antibody. The frequency of the fragile X was reduced by BrdUrd treatment. The degree of reduction was more severe in the 20 micrograms/ml than in the 0.2 microgram/ml series and was more severe with late S than with early S treatment. Of the early- and late-replicating fragile X chromosomes, those which were actively replicating during a BrdUrd treatment were more reduced than the others. Thus, the average rate of early and late S treatment with 0.2 microgram BrdUrd/ml was assumed to be the closest reflection of the situation in vivo. There was no correlation between the average rate of the early replicating, active fragile X and the intelligence of the heterozygous carriers studied.