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.     

Cell fusion-induced quick change in replication time of the inactive mouse X chromosome: an implication for the maintenance mechanism of late replication.

It is unknown how and why the genetically inactivated mammalian X chromosome replicates late in S phase. There are also occasional inactive X chromosomes characterized by an opposite behavior replicating early in S phase. Two clonal cell lines, MTLB3 and MTLH8, isolated from a cultured murine T-cell lymphoma have an allocyclic X chromosome of the latter type. This precociously replicating X chromosome was judged to be genetically inactive as the late replicating one. Immediately after fusion with another cell line, the precociously replicating X chromosome from these cells starts to replicate late in S phase. This finding seems to suggest that late replication characterizing the inactive X chromosome is actively maintained by a trans-acting factor in female somatic cells, and that its lack entails a switch from late replication to precocious replication. It remains unknown whether this presumptive factor also modifies the autosomal replication pattern.     

Chromosomal distribution of the hamster intracisternal A-particle (IAP) retrotransposons

The retrotransposon-like elements of the intracisternal A-particle (IAP) sequences occur in about 900 copies per haploid hamster cell genome. By applying the fluorescent in situ hybridization (FISH) technique and four different, cloned segments of the IAP element as hybridization probes, these elements were found to be distributed in specific patterns over many of the 44 hamster chromosomes. The hybridization patterns were very similar regardless of whether all four probes or only the IAPI probe carrying the long terminal repeat (LTR) region were used. The IAP elements were found most abundantly, though not exclusively, on the short arms of at least 12 of the autosomes. Of the sex chromosomes, the shorter Y chromosome was stained on both arms, and the X chromosome on one arm by the IAP probes. Primary Syrian hamster cells, the established Syrian hamster cell line BHK21, and the adenovirus type 12 (Ad12)-transformed BHK21 cell line T637 yielded very similar results. In Chinese hamster ovary (CHO) or 3T3 mouse cells, signals could not be elicited by FISH using the Syrian hamster IAP probes. On Southern blots, the DNAs from these cell lines hybridized very weakly, if at all, to the IAP sequences. Thus, IAP sequences were retroposed after Syrian hamster and mouse or Syrian and Chinese hamsters had diverged in evolution.     

Distribution of sister chromatid exchanges in chromosomes of normal Chinese hamster and its cell lines exposed to BrdU and MMC

Sister chromatid exchanges (SCEs) were investigated in chromosomes from normal male Chinese hamster (CH) and its cell lines (CHW, 1102 and 1103). The fibroblasts were grown for two replication cycles in medium containing BrdU and mitomycin C (MMC) at concentrations of 0.01, 0.02 and 0.03 micrograms/ml of medium. The difference in SCEs/cell between male CH and CHW was negligible, but the difference between CHW and 1102 was about 2.6-fold. It is suggested from karyotypic differences between CHW and 1102, that the control of SCEs might be due partly or completely to chromosome 5 in Chinese hamster. The lines CHW and 1102 were less responsive than normal Chinese hamster cells when exposed to different MMC concentrations. It is suggested that the lines CHW and 1102 might be slightly resistant to MMC. The frequency of SCEs decreased with the decrease of chromosome size. SCEs are not preferentially distributed on any autosomal chromosomes. No SCEs were found in normal X-chromosomes. The majority of exchanges appear to be either interband regions or very near band-interband junctions.     

Y chromosome replication and chromosome arrangement in germ line cells and sperm of the rat

The chronology of Y chromosome replication in meiosis of male adult rats was investigated. ³HTdR was injected into the testes and animals were sacrificed at 2-hour intervals from 2 to 24 hour after the injection; and at 2-day intervals from 2 to 64 days after the injection. Autoradiograms from germ line cell spreads were prepared. The study of spermatogonial metaphases showed that the Y chromosome is the last to begin and end DNA synthesis. Consequently, by detecting such a pattern of replication it was possible to trace the asynchronous Y from spermatogonia to sperm. Assuming that Y chromosomes are early replicating in preimplantation embryos of mammals it is proposed that Y chromosome of rats shift from late to early replicating in the first divisions of the fertilized egg. Moreover, the analysis of the patterns of sperm labeling allow one to infer that chromosomes are end-to-end associated in sperm nuclei, and that the Y chromosome and perhaps autosomes as well occupy a constant position in sperm of rats.     

Requirement of human chromosomes 19, 6 and possibly 3 for infection of hamster x human hybrid cells with baboon M7 type C virus.

The replication pattern of the endogenous baboon type C virus M7 was studied in 29 primary Chinese hamster × human hybrid clones generated with leukemic cells from two different patients with acute lymphoblastic or myeloblastic leukemia. There was no evidence of viral particulate RDDP or M7 antigen before viral infection. M7 virus replicated in human and some hybrid cells but not in Chinese hamster cells, indicating that M7 requires dominantly expressed human gene(s) for replication. Enzyme and cytogenetic analyses show that a gene(s) coded for by human chromosome 19 is necessary for M7 infection of these hybrids. Detailed cytogenetic correlations revealed, however, that the chromosome 19+/M7 + hybrid clones with intact chromosomes also had copies of chromosomes 3 and 6. Previously, Bevi, the putative integration site for M7 virus, has been assigned to human chromosome 6. Many clones with various combinations of chromosomes 3 and 6 lacked chromosome 19, however, and failed to replicate exogenously applied M7 virus, while tests of 27 secondary clones showed that M7 markers co-segregated with chromosome 19 markers. These findings all confirm the need for a chromosome 19-coded function in Chinese hamster × human hybrids. In addition, the yield of viral particulate RDDP produced into the culture fluid was 50–100 fold less per viral antigen-positive cell in the hybrids compared with human cells. Thus some form of regulation of viral components exists in the hybrid cells. When the virus replicating in hybrid cells was transferred back to human cells, this regulation was relaxed and the yield of RDDP per FA(+) cell greatly increased. We conclude that human chromosomes 6 and 19 code for functions involved in M7 virus metabolism, and we cannot exclude a function coded for by chromosome 3.     

Replication pattern of the X and Y chromosomes in partially synchronized human lymphocyte cultures

The replication pattern of the X and Y chromosomes at the beginning of the synthetic phase was studied in human lymphocyte cultures partially synchronized by the addition of 5-fluoro-2-deoxyuridine (FUdR). The data were evaluated statistically by an analysis of the distribution of silver grain counts over the X and Y chromosomes. —In cells from normal females, one of the X chromosomes began replication later than any other chromosomes of the complement. The short arm of the late replicating X chromosome started replication earlier than the long arm. The telomeric region of the short arm was a preferential site of DNA synthesis at the beginning of replication. —In partially synchronized lymphocyte cultures from a patient with the XXY syndrome, the Y chromosome started replication together with the late replicating X chromosome. The Y chromosome most frequently replicated synchronously with the short arm of the X. The centromeric region of the Y chromosome initiated synthesis before the telomeric region and appeared to replicate synchronously with the telomeric region of the short arm of the X. These findings are discussed with reference to the pairing of the X and Y chromosomes at meiosis.Supported in part by the National Institute of Health Research Grant HD-01979 and National Foundation Birth Defects Research Grant CRCS-40. Dr. Knight was a predoctoral fellow under National Institute of Health Training Program HD-00049-09.     

Karyotype stability of 2 continuous Chinese hamster cell lines--CHO-K1 and V-79

Karyotypes of two continuous Chinese hamster cell lines CHO-K1 and V-79 were studied by G-banding and silver staining. Modal chromosome numbers were 20 and 21, respectively. Both the lines were characterized with a high degree of karyotype stability and constant ratio of normal and marker chromosomes. Nulli- and monosomy were recorded for 9 chromosome pairs in CHO-K1, and 8 pairs in V-79 cell lines. Modal numbers of Ag-positive NOR were 4 in CHO-K1 and 5 in V-79. A definition of the origin of the majority of marker chromosomes in both the lines (11 and 10, respectively) made it possible to establish the exact chromosome content of each cell and to determine the generalized reconstructed karyotypes of cell lines. We established the retention of diploid chromosome set of all the autosomes, the true monosomy for one X-chromosome in both the lines, and the constant extracopying of a short arm of chromosome 3 in the V-79 cell line.     

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.     

大熊猫染色体晚复制带研究

以培养的大熊猫外周血淋巴细胞为实验材料,在细胞培养终止前４ｈ加入ＢｒｄＵ（终浓度为１０μｇ／ｍｌ培养基）,对复制的染色体ＤＮＡ进行ＢｒｄＵ标记。掺入ＢｒｄＵ的染色体经吖啶橙（０．０５％）处理、紫外光照射、Ｇｉｅｍｓａ染色后,可在染色体上获得清晰的复制带纹。根据众多分裂相所显示的不同复制带型,可初步确定大熊猫每一染色体独特的晚复制带纹。在雌性个体的两个Ｘ染色体中,一条Ｘ染色体复制明显落后于另一Ｘ染色体,尤其在迟复制Ｘ染色体长臂近着丝粒区显现出较宽的晚复制带纹。     

The staining of constitutive heterochromatin,and A-T and G-C rich DNA in lymphocytes and primary spermatocytes of the Chinese hamster

The staining of male Chinese hamster chromosomes at meiotic prophase with several banding techniques is described. C-banding results only occasionally in well-differentiated pachytene and diakinesis bivalents. Meiotic C-bands are small compared with those in somatic metaphase chromosomes. In mice C-bands mainly consist of highly repetitive satellite DNA, whereas in Chinese hamsters the majority of the DNA in C-bands is not or hardly repetitive. Especially in Chinese hamsters both the degree of chromatin despiralisation and the folding pattern of the chromatin drastically reduce the distinction of C-bands in late meiotic prophasc chromosomes. In contrast to the situation in mice, C-heterochromatin associations are never observed in Chinese hamster spermatocytes. It is assumed that the presence of satellite DNA rather than constitutive heterochromatin is the basis for the associations of the paracentromeric chromosome regions in mice. The location and behaviour of AT- and GC-rich DNA in Chinese hamster primary spermatocytes is studied with base-specific fluorochromes (H 33258 and Chromomycin A₃ for AT-and GC-rich DNA respectively), in combination with a pretreatment with base-specific non-fluorescent antibiotics (Actinomycin D and Netropsin for GC-and AT-rich DNA respectively). No indications are found for the clustering of AT-or GC-rich DNA in Chinese hamster pachytene nuclei. A comparison of banding patterns observed in somatic metaphases and in diakinesis gives some information about the partial homology of the X and Y chromosome. The results are conflicting. The short arm of the Y chromosome is homologous with a part of the X chromosome. According to the C-band pattern the long arm of the X chromosome is involved in the pairing with Y, whereas fluorescence banding patterns indicate that it is the short arm of X.     

Patterns of late chromosomal DNA replication in unbalanced chinese hamster-mouse somatic cell hybrids

The chromosome late-replication patterns of five mouse × Chinese hamster somatic cell hybrids with reduced hamster complements were compared with those of the Chinese hamster parent cell, in order to determine whether the sequential order of chromosome replication is dependent on the presence of the whole chromosome set. In all hybrid clones the parental pattern could be recognized in a variable proportion of cells, although different chromosomes were missing in each clone. The results suggest that sequential order of replication is not the consequence of any sort of interaction between replication units (such as competition for limiting factors), and point to a considerable degree of autonomy in replication of individual chromosomes or chromosome parts.     

白颊长臂猿染色体的研究

本文对我国云南南部的白须长臂猿（Ｈ．ｌｅｕｃｏｇｅｎｙｓ）染色体的Ｇ带、Ｃ带、晚复制带及Ａｇ－ＮＯＲｓ进行了较为详细的研究。它的２ｎ＝５２,核型公式为４４（Ｍ或ＳＭ）＋６（Ａ）,ＸＹ（Ｍ,Ａ）。Ｃ带表明一些染色体着丝点Ｃ带弱化;有的染色体出现插入的和端位的Ｃ带;Ｘ染色体两臂有端位Ｃ带,Ｙ染色体是Ｃ带阳性和晚复制的。Ａｇ－ＮＯＲｓ的数目,雌体有４个,雄体有５个,Ｙ染色体上具ＮＯＲ。本文对白颊长臂猿与其它长臂猿间的亲缘关系、核型进化的可能途径进行了讨论。     

Chromosomal alterations in cell lines derived from mouse rhabdomyosarcomas induced by crystalline nickel sulfide

Summary Prior studies have shown a preferential decondensation (or fragmentation) of the heterochromatic long arm of the X chromosome of Chinese hamster ovary cells when treated with carcinogenic crystalline NiS particles (crNiS). In this report, we show that the heterochromatic regions of mouse chromosomes are also more frequently involved in aberrations than euchromatic regions, although the heterochromatin in mouse cells is restricted to centromeric regions. We also present the karyotypic analyses of four cell lines derived from tumors induced by leg muscle injections of crystalline nickel sulfide which have been analyzed to determine whether heterochromatic chromosomal regions are preferentially altered in the transformed genotypes. Common to all cell lines was the presence of minichromosomes, which are acrocentric chromosomes smaller than chromosome 19, normally the smallest chromosome of the mouse karyotype. The minichromosomes were present in a majority of cells of each line although the morphology of this extra chromosome varied significantly among the cell lines. C-banding revealed the presence of centromeric DNA and thus these minichromosomes may be the result of chromosome breaks at or near the centromere. In three of the four lines a marker chromosome could be identified as a rearrangement between two chromosomes. In the fourth cell line a rearranged chromosome was present in only 15% of the cells and was not studied in detail. One of the three major marker chromosomes resulted from a centromeric fusion of chromosome 4 while another appeared to be an interchange involving the centromere of chromosome 2 and possibly the telomeric region of chromosome 17. The third marker chromosome involves a rearrangement between chromosome 4 near the telomeric region and what appears to be the centromeric region of chromosome 19. Thus, in these three major marker chromosomes centromeric heterochromatic DNA is clearly implicated in two of the rearrangements and less clearly in the third. The involvement of centromeric DNA in the formation of even two of four markers is consistent with the previously observed preference in the site of action of crNiS for heterochromatic DNA during the early stages of carcinogenesis.     

Normal X chromosome induced reversion in the direction of chromosome segregation in mouse-Chinese hamster somatic cell hybrids

The effect of a normal mouse X chromosome on the chromosome segregation of mouse-Chinese hamster somatic cell hybrids was determined by (i) producing hybrids between the mouse sarcoma line CMS4 and a microcell hybrid (mfe4) of the hamster line E36, containing a mouse X chromosome from a normal cell; (ii) isolating hybrids between CMS4 and a 6-thioguanine selected (X minus) mfe4 subpopulation; (iii) comparing the direction of segregation in the two sets of hybrids. It was found that the normal X chromosome, like the X chromosomes from two MCA-transformed sarcoma lines reported previously [9], has the ability to switch the chromosome segregation of mouse-Chinese hamster somatic cell hybrids. We conclude that the reversal in chromosome segregation is mediated by factors located on the X chromosome. We designate these genetic elements as segregation reversal genes or sr genes.     

On the homology between the X and the Y chromosomes of the Chinese hamster

The chiasmatic association of the heteromorphic sex chromosomes in the spermatocytes of the Chinese hamster was observed in squash and/or air-dried preparations. The pairing arm of the Y was invariably its short arm. Although the X in diakinesis did not show distinct long and short arm as in mitotic metaphase, the DNA replication patterns of the sex chromosomes in spermatogonia suggested that the distal segment of the long arm of the X is homologous to the short arm of the Y.     

Stable telocentric chromosomes produced by centric fission in chinese hamster cells in vitro

Metaphase examination of pseudodiploid Chinese hamster cells revealed that spontaneous breaks or fission occurred rather frequently (2.9%) at the centromeric regions of subtelo- or metacentric chromosomes, resulting in the production of telocentric chromosomes. The centromeric fission appeared to occur in every member of the chromosome complement. An attempt was made to isolate cells possessing thus derived telocentrics from the cell population and gave two clonal lines which were retaining one and two telocentric chromosomes, respectively. Both banding and labeling patterns of these chromosomes indicated unequivocally their X chromosome origin. They were transmitted successively to the daughter cells during a 3-month culture period, showing no tendency to fuse to produce a metacentric chromosome.Contribution No. 897 from the National Institute of Genetics, Japan.     

Chromosome banding in Amphibia

High-resolution replication banding patterns were induced in prometaphase and prophase chromosomes of Xenopus laevis by treating kidney cell lines with 5-bromodeoxyuridine (BrdU) and deoxythymidine (dT) in succession. Up to 650 early and late replicating bands per haploid karyotype were demonstrated in the very long prophase chromosomes. This permits an exact identification of all chromosome pairs of X. laevis. Late replicating heterochromatin was located by analysing the time sequence of replication throughout the second half of S-phase. Neither heteromorphic sex chromosomes nor sex chromosome-specific replication bands were demonstrated in the heterogametic ZW females of X. laevis. A detailed examination of the BrdU/dT-labelled prometaphases and prophases revealed that the X. laevis chromosomes can be arranged in groups of four (quartets), most of which show conspicuous similarities in length, centromere position, and replication pattern. This is interpreted as further evidence for an ancient allotetraploid origin of X. laevis.by H.C. MacgregorThis paper is dedicated to Prof. Wolfgang Engel on the occasion of his 50th birthday     

Presence of an Allocyclic Early Replicating X Chromosome in Female Embryos of the Rat, Chinese Hamster and Rabbit

Previous studies on early female mouse embryos revealed the presence of two kinds of inactive X chromosomes, one replicating late and the other early in the DNA synthetic period. The X chromosome that replicates early is of special interest because of its paternal origin, preferential occurrence in trophectoderm and primitive endoderm derivatives, and programmed shift to the late replicator. This study by BrdU labeling and acridine orange fluorescence staining was undertaken to examine whether the inactive X chromosome behaves in a similar manner in other laboratory mammals. In rat embryos the paternal X chromosome was found to show the same behavior in extraembryonic tissues. Early replicating chromosomes were also found in the extraembryonic regions of Chinese hamster and rabbit embryos, although their parental origin could not be determined due to the absent of X chromosome polymorphism in these species. Probably the early replicating X chromosome occurs commonly in mammals. Its functional significance is unknown.     

X chromosome inactivaton and SV40 transformation of mammalian cells.

Five embryonic mouse cultures and one human fibroblast culture were transformed with SV40. The cultures were studied cytologically to see if the normal pattern of sex chromosome replication was maintained in SV40 transformed cells. Characteristic late replication patterns were observed for both the X and Y chromosomes, and there was no evidence for loss of the inactive X chromosome, even in cells with 4 or more X chromosomes. The human line was heterozygous at two X-linked loci and a clonal analysis showed that the expression of X-linked genes was not affected by SV40 transformation.