Chromosomal and nuclear distribution of the HindIII 1.9-kb human DNA repeat segment

A human interspersed repetitive DNA cloned in pBR322, the HindIII 1.9-kb (kilobase pair) sequence, was labeled with biotinylated dUTP and hybridized to acid-fixed chromosomes and paraformaldehyde-fixed whole cells in situ. Using our most sensitive detection techniques this probe highlighted on the order of 200 discrete loci, in punctate or banded arrays, that resembled a Giemsa-dark band pattern on chromosome arms. Interphase cells also displayed many discrete punctate spots of hybridization along chromosome fibers. The ubiquitous Alu sequence repeat also appeared to be concentrated in specific regions of the chromosome and predominantly highlighted Giemsa-light bands. Centromeric or ribosomal spacer DNA repeats used as controls in all studies gave the expected hybridization profiles and showed no non-specific labeling of chromosome arms. Cohesive groups of centromeric DNA arrays and rDNA clusters were observed in interphase nuclei. Refinements in methods for detecting biotin-labeled probes in situ were developed during these studies and calculations indicated that about 20 kb or more of the 1.9-kb repeat were present at each hybridization site. The chromosomal distribution of the 1.9-kb repeat suggests that this sequence may reflect, or participate in defining, ordered structureal domains along the chromosome.     

RNA SYNTHESIS BY EXOGENOUS RNA POLYMERASE ON CYTOLOGICAL PREPARATIONS OF CHROMOSOMES

Cytological preparations of Drosophila polytene chromosomes serve as templates for RNA synthesis carried out by exogenous RNA polymerase (Escherichia coli). Incorporation of labeled ribonucleoside triphosphates into RNA may be observed directly by autoradiography. Because of the effects of rifampicin, actinomycin D, ribonuclease, high salt, and the requirement for all four nucleoside triphosphates, we conclude that the labeling observed over chromosomes is due to DNA-dependent RNA polymerase activity. Using this method, one can observe RNA synthesis in vitro on specific chromosome regions due to the activity of exogenous RNA polymerase. We find that much of the RNA synthesis in this system occurs on DNA sequences which appear to be in a nondenatured state.     

Analysis of the replication pattern of Chinese hamster chromosomes using 5-bromodeoxyuridine suppression of 33258 Hoechst fluorescence

Chinese hamster fibroblasts were synchronized and given 5-bromodeoxyuridine for DNA synthesis except during one hour of the S phase when thymidine was present in the medium. In the next mitosis, chromosomes stained with 33258 Hoechst were banded in appearance when photographed by fluorescence microscopy. The bright regions corresponded to the chromosome segments replicated during the thymidine exposure in the S phase. The segments replicated together during any one hour produced three distinct patterns which were characteristic of early, middle, and late S phase. Most of the fluorescent regions corresponded in size and position with G-bands of these chromosomes. There was no correlation between the staining behavior of a band in G-band procedure and its time-of-replication, i.e., both light and dark G-bands were replicated during early, middle, and late S phase. However, it appears that all of the DNA within a single band is replicated together within one third of the S phase.     

Human rDNA: evolutionary patterns within the genes and tandem arrays derived from multiple chromosomes

Human rDNA forms arrays on five chromosome pairs and is homogenized by concerted evolution through recombination and gene conversion (loci RNR1, RNR2, RNR3, RNR4, RNR5, OMIM: 180450). Homogenization is not perfect, however, so that it becomes possible to study its efficiency within genes, within arrays, and between arrays by measuring and comparing DNA sequence variation. Previous studies with randomly cloned genomic DNA fragments showed that different parts of the gene evolve at different rates but did not allow comparison of rDNA sequences derived from specific chromosomes. We have now cloned and sequenced rDNA fragments from specific acrocentric chromosomes to (1) study homogenization along the rDNA and (2) compare homogenization within chromosomes and between homologous and nonhomologous chromosomes. Our results show high homogeneity among regulatory and coding regions of rDNA on all chromosomes, a surprising homogeneity among adjacent distal non-rDNA sequences, and the existence of one to three very divergent intergenic spacer classes within each array.     

DNA REPLICATION PATTERNS AND CHROMOSOMAL PROTEIN SYNTHESIS IN OPOSSUM LYMPHOCYTES IN VITRO

DNA replication patterns were determined in the autosomes and sex chromosomes of phytohemagglutinin-stimulated lymphocytes from the opossum (Didelphis virginiana) by employing thymidine-³H labeling and high-resolution radioautography. Opossum chromosomes are desirable experimental material due to their large size, low number (2n = 22), and morphologically distinct sex chromosomes. The autosomes in both sexes began DNA synthesis synchronously and terminated replication asynchronously. One female X chromosome synthesized DNA throughout most of the S phase. Its homologue, however, began replication approximately 3.5 hr later. The two X's terminated DNA synthesis synchronously, slightly later than the autosomes. This form of late replication, in which one X chromosome begins DNA synthesis later than its homologue but completes replication at the same time as its homologue, is apparently unique in the opossum. The male X synthesized DNA throughout S while the Y chromosome exhibited late-replicating characteristics. The two sex chromosomes completed synthesis synchronously, slightly later than the autosomes. Grain counts were performed on all chromosomes to analyze trends in labeling intensity at hourly intervals of S. By analyzing the percent of labeled mitotic figures on radioautographs at various intervals after introduction of arginine-³H, chromosomal protein synthesis was found not to be restricted to any portion of interphase but to increase throughout S and into G₂.     

Differential DNA synthesis in homologous regions of hybrid polytenic chromosomes (Anopheles atroparvus x A. labranchiae)

Differential DNA synthesis is demonstrated in asynaptic regions of the polytenic chromosomes of the Anopheles atroparvus x A. labranchiae hybrid. This differential synthesis is present both in homologous segments with different banding patterns and in morphologically identical segments. Each differential synthesis appears to be related to a specific portion of the replication cycle and due to the fact that one of the two homologues requires a shorter period of time for its duplication.     

Asynchronous Duplication of Chromosomes in Cultured Cells of Chinese Hamster

Chromosome duplication (DNA synthesis) was studied in cultured cells of Chinese hamsters by means of autoradiography following thymidine-H³ incorporation. The technique used was to expose an asynchronously dividing population of rapidly growing cells for a 10 minute interval to a medium with thymidine-H³. Cells were then transferred to a medium with excess unlabeled thymidine. The population was sampled at intervals thereafter and studies made of the frequency of labeled interphases and division figures, and the patterns of labeling of specific chromosomes. The average generation time during these experiments was about 14 hours. DNA synthesis occurred during an interval of about 6 hours and stopped 2 to 3 hours before metaphase. After metaphase the chromosomes usually begin duplication again within 5 to 6 hours. Grain counting, to estimate the amount of tritium incorporated after a short contact with thymidine-H³ and at intervals after transfer to a medium with excess unlabeled thymidine, indicated that the intracellular pool of labeled precursors was diluted within less than a minute so that further labeling would not be detected. The chromosomes labeled during the contact period retained their precise pattern of labeling through another duplication cycle and no turnover of DNA or loss of tritium was detectable. Five or 6 chromosomes of the complement have segments typically late in duplication. Two of these are the X and Y chromosomes. The long arm of the X chromosome and the whole Y chromosome are duplicated in the last half of the interval of DNA synthesis. The short arm of the X chromosome in a male strain is duplicated in the first half of the interval. In another strain (female), one X chromosome had the same timing, but the other one was all duplicated in the last half of the period of DNA synthesis. The DNA in the short arms of 2 medium sized chromosomes, as well as most of the DNA in 1 or 2 of the smallest chromosomes of the complement was replicated late. The study has led to the hypothesis that various chromosomes or parts of chromosomes have a genetically controlled sequence in duplication which may have some functional significance.     

Developmentally programmed DNA rearrangement in Tetrahymena thermophila: Isolation and sequence characterization of three new alternative deletion systems

Extensive developmentally programmed DNA rearrangements, including thousands of internal deletions, occur in the differentiating somatic macronucleus in Tetrahymena thermophila. Some deletion systems involve the use of multiple alternative deletion sites. We report here the cloning and the sequences of three new alternative deletion systems (RR, RP and B) obtained using genomic subtraction. The RP and RR deletion systems are 2 kb apart on chromosome IR, and both involve the removal of < 2 kb of micronuclear sequences. The B deletion system is on chromosome 5 and involves a deletion of > 5 kb. All three deleted regions are very AT rich (∼ 80%) and do not appear to encode any protein. Sequences of the regions flanking the deletion junctions of all three systems revealed no sequence similarity among them nor with any previously reported deletion systems, suggesting that different cis-acting elements are involved for rearrangement. Unlike other deletion systems in ciliates, the B deletion system lacks short terminal direct repeats. Our results suggest an average of at least one alternative deletion system per 134 kb of micronuclear DNA and lead to an estimate that at least 25% of all deletion systems in Tetrahymena utilize alternative ends. The genomic subtraction method employed in this study could prove useful for the isolation of alternatively deleted DNA in special-purpose cases in Tetrahymena and other ciliates. The hybridization parameters for genomic subtraction worked out here for highly AT-rich DNA may have wider usefulness.     

Cloning and characterisation of polymorphic heterochromatic segments of Brachycome dichromosomatica

After selective enrichment and differential hybridisation of C_ot-1 DNA fractions of plants with and without polymorphic heterochromatic segments, a repetitive sequence (called Bds1) specific to the polymorphic chromosome segments of Brachycome dichromosomatica (Brachyscome dichromosomatica) was isolated. A single repeat unit of Bds1 is 92 bp long and is organised in tandem arrays at three different polymorphic segment sites on the chromosomes of cytodeme A2. Although all three sites showed extensive polymorphism between plants, the karyotypes of all analysed mitotic root cells were stable within a single plant. Electron microscopy revealed heavily condensed chromatin structures at the most obvious polymorphic site. The mechanisms that generate and maintain the observed chromosome structure polymorphisms are discussed. Received: 16 March 1999; in revised form: 28 September 1999 / Accepted: 11 November 1999     

Comparison of homologous polytene chromosomes in Phaseolus coccineus embryo suspensor cells: morphological,autoradiographic and cytophotometric analyses

The functional behaviour of unpaired homologous polytene chromosomes (2n=22), was investigated in nuclei of Phaseolus coccineus embryo suspensor cells. Observations were carried out on the morphological level and after ³H-thymidine and ³H-uridine autoradiography. Histone and total protein contents in the chromatin were also investigated. It was shown that corresponding regions of homologous chromosomes may show different functional structures. ³H-thymidine incorporation demonstrated differences between homologues in both DNA synthesis leading to chromosome endoreduplication (polytenization) and DNA amplification (extra DNA synthesis). ³H-uridine autoradiography showed that homologous regions in a given chromosome pair may display three labeling patterns: i) both regions labeled; ii) both regions unlabeled; iii) one region labeled and the other unlabeled. These three states are found to occur in different cells of one and the same embryo suspensor. Differences between homologous chromosome regions were also found in the ratios between DNA and protein contents in their chromatin. These results, which show that the functional activity of homologous chromosomes of the same complement may greatly differ, are discussed in relation to the characteristics of the system investigated.     

Statistical patterns of the anomalous staining of 5-bromodeoxyuridine-substituted chromosomes

Five large chromosome segments showing sometimes an abnormal staining were found in the genome of Chinese hamster (clone 237). Three types of abnormal staining were recorded. After one round of replication in the presence of BrdUrd these segments showed a hetero-staining, whereas after two rounds of replication the same segments showed iso-dark or iso-light staining. Pulse labeling with 3H-thymidine showed that all these segments were the late-replicating ones. The labeling proceeded according to all-or-none principle; in a given cell all five segments showed either presence or absence of the label. On the contrary, the abnormal staining was statistically distributed among these segments. These results are in disagreement with the current view that the abnormal staining is associated with asymmetrical distribution of thymine among two strands of DNA duplex. The above regularities are considered as an argument for the two-stranded model of chromosome.     

A STUDY OF THE NUCLEOLAR MATERIAL IN SCIARA COPROPHILA

In the polytene chromosomes of Sciara coprophila, in addition to a nucleolus, large numbers of nucleolarlike structures or micronucleoli are formed. A detailed mapping localized the nucleolar organizer at one end of the X chromosome and revealed that approximately 18% of the bands of each chromosome are potentially capable of producing micronucleoli. Most of these sites are in regions known from a previous study to show asynchronous DNA replication: DNA puffs and certain heterochromatic regions. Micronucleoli are rarely found in association with bulbs. The RNA metabolism of the polytene chromosomes during late fourth instar was studied using radioautographic techniques. Isolated glands were incubated in tritiated uridine for 10 to 30 min, and radioautographs were made of squash preparations. Despite the wide range of variation found among different larval cultures, the following pattern was observed. Just prior to and at the beginning of DNA puff formation, a period of intense extrachromosomal nucleolar and micronucleolar RNA synthesis occurs. After maximal development of the DNA puffs, the synthesis of extrachromosomal RNA is at a low point, while incorporation into bulbs and DNA puffs remains high. With the onset of the prepupal stage, all nuclear RNA synthesis ceases.     

Functional and structural analyses of mouse genomic regions screened by the morphological specific-locus test

Genetic analyses of certain classes of mutations recovered in the mouse specific-locus test (SLT) have characterized arrays of deletions, overlapping at the marked loci. Complementation maps, generated for several of the regions, have identified a number of functional units surrounding each marked locus and have ordered the mutations into complementation groups. Molecular entry to all but one of the marked regions has been achieved by (1) identifying proviral integrations in, or close to, the specific loci (d, se, a, c); (2) mapping random anonymous clones from appropriately enriched libraries to the longest deleted segments, then submapping to more limited segments on the basis of complementation and deletion-breakpoint maps (c, p); (3) similarly mapping known clones thought to be located in pertinent chromosomal regions (p, c, d); and (4) cloning specific genes that reside in regions corresponding to the deletions (b, c, p). The molecular analyses have confirmed that genetically-inferred deletions are structural deletions of DNA. The emerging physical maps are concordant with the complementation maps, and in several cases have discriminated among members of a complementation group with respect to breakpoint positions. Deletion-breakpoint-fusion fragments have prove to be highly useful for making large chromosomal jumps to facilitate physical mapping. The recent advances toward correlating physical and functional maps of specific regions of the mouse genome owe much to the existence of arrays of mutations involving loci marked in the SLT. In turn, the characterizations of these regions have made it possible to demonstrate qualitative differences among mutations resulting from different treatments. This new capability for qualitative analysis, which will increase as the molecular studies proceed, further enhances the value of the SLT, which has been extensively used for quantitative studies in germ-cell mutagenesis.     

Diverse patterns of the tandem repeats organization in rye chromosomes

Although the monomer size, nucleotide sequence, abundance and species distribution of tandemly organized DNA families are well characterized, little is known about the internal structure of tandem arrays, including total arrays size and the pattern of monomers distribution. Using our rye specific probes, pSc200 and pSc250, we addressed these issues for telomere associated rye heterochromatin where these families are very abundant. Fluorescence in situ hybridization (FISH) on meiotic chromosomes revealed a specific mosaic arrangement of domains for each chromosome arm where either pSc200 or pSc250 predominates without any obvious tendency in order and size of domains. DNA of rye-wheat monosomic additions studied by pulse field gel electrophoresis produced a unique overall blot hybridization display for each of the rye chromosomes. The FISH signals on DNA fibres showed multiple monomer arrangement patterns of both repetitive families as well as of the Arabidopsis-type telomere repeat. The majority of the arrays consisted of the monomers of both families in different patterns separated by spacers. The primary structure of some spacer sequences revealed scrambled regions of similarity to various known repetitive elements. This level of complexity in the long-range organization of tandem arrays has not been previously reported for any plant species. The various patterns of internal structure of the tandem arrays are likely to have resulted from evolutionary interplay, array homogenization and the generation of heterogeneity mediated by double-strand breaks and associated repair mechanisms.     

Prokaryotic RNA preparation methods useful for high density array analysis: comparison of two approaches

High density oligonucleotide arrays have been used extensively for expression studies of eukaryotic organisms. We have designed a prokaryotic high density oligonucleotide array using the complete Escherichia coli genome sequence to monitor expression levels of all genes and intergenic regions in the genome. Because previously described methods for preparing labeled target nucleic acids are not useful for prokaryotic cell analysis using such arrays, a mRNA enrichment and direct labeling protocol was developed together with a cDNA synthesis protocol. The reproducibility of each labeling method was determined using high density oligonucleotide probe arrays as a read-out methodology and the expression results from direct labeling were compared to the expression results from the cDNA synthesis. About 50% of all annotated E.coli open reading frames are observed to be transcribed, as measured by both protocols, when the cells were grown in rich LB medium. Each labeling method individually showed a high degree of concordance in replica experiments (95 and 99%, respectively), but when each sample preparation method was compared to the other, ~32% of the genes observed to be expressed were discordant. However, both labeling methods can detect the same relative gene expression changes when RNA from IPTG-induced cells was labeled and compared to RNA from uninduced E.coli cells.     

Complex high-resolution linkage disequilibrium and haplotype patterns of single-nucleotide polymorphisms in 2.5 Mb of sequence on human chromosome 21.

One approach to identify potentially important segments of the human genome is to search for DNA regions with nonrandom patterns of human sequence variation. Previous studies have investigated these patterns primarily in and around candidate gene regions. Here, we determined patterns of DNA sequence variation in 2.5 Mb of finished sequence from five regions on human chromosome 21. By sequencing 13 individual chromosomes, we identified 1460 single-nucleotide polymorphisms (SNPs) and obtained unambiguous haplotypes for all chromosomes. For all five chromosomal regions, we observed segments with high linkage disequilibrium (LD), extending from 1.7 to>81 kb (average 21.7 kb), disrupted by segments of similar or larger size with no significant LD between SNPs. At least 25% of the contig sequences consisted of segments with high LD between SNPs. Each of these segments was characterized by a restricted number of observed haplotypes,with the major haplotype found in over 60% of all chromosomes. In contrast, the interspersed segments with low LD showed significantly more haplotype patterns. The position and extent of the segments of high LD with restricted haplotype variability did not coincide with the location of coding sequences. Our results indicate that LD and haplotype patterns need to be investigated with closely spaced SNPs throughout the human genome, independent of the location of coding sequences, to reliably identify regions with significant LD useful for disease association studies.     

CRISPR-CAS9 D10A nickase target-specific fluorescent labeling of double strand DNA for whole genome mapping and structural variation analysis

We have developed a new, sequence-specific DNA labeling strategy that will dramatically improve DNA mapping in complex and structurally variant genomic regions, as well as facilitate high-throughput automated whole-genome mapping. The method uses the Cas9 D10A protein, which contains a nuclease disabling mutation in one of the two nuclease domains of Cas9, to create a guide RNA-directed DNA nick in the context of an in vitro-assembled CRISPR-CAS9-DNA complex. Fluorescent nucleotides are then incorporated adjacent to the nicking site with a DNA polymerase to label the guide RNA-determined target sequences. This labeling strategy is very powerful in targeting repetitive sequences as well as in barcoding genomic regions and structural variants not amenable to current labeling methods that rely on uneven distributions of restriction site motifs in the DNA. Importantly, it renders the labeled double-stranded DNA available in long intact stretches for high-throughput analysis in nanochannel arrays as well as for lower throughput targeted analysis of labeled DNA regions using alternative methods for stretching and imaging the labeled long DNA molecules. Thus, this method will dramatically improve both automated high-throughput genome-wide mapping as well as targeted analyses of complex regions containing repetitive and structurally variant DNA.     

Toward a bacterial genome technology: integration of theEscherichia coli prophage lambda genome into theBacillus subtilis 168 chromosome

A novel approach to the cloning large DNAs in theBacillus subtilis chromosome was examined. AnEscherichia coli prophage lambda DNA (48.5 kb) was assembled in the chromosome ofB. subtilis. The lambda DNA was first subcloned in four segments, having partially overlapping regions. Assembly of the complete prophage was achieved by successive transformation using three discrete DNA integration modes: overlap-elongation, Campbell-type integration, and gap-filling. In theB. subtilis chromosome, DNA was elongated, using contiguous DNA segments, via overlap-elongation. Jumping from one end of a contiguous DNA stretch to another segment was achieved by Campbell-type integration. The remaining gap was sealed by gap-filling. The incorporated lambda DNA thus assembled was stably replicated as part of the 4188 kbB. subtilis chromosome under non-selective conditions. The present method can be used to accommodate larger DNAs in theB. subtilis chromosome and possible applications of this technique are discussed.     

The replicative organization of DNA in polytene chromosomes ofDrosophila hydei

Salivary-gland nuclei ofDrosophila hydei were pulse-labeledin vitro with³H-thymidine and studied autoradiographically in squash preparations. The distribution of radioactive label over the length of the polytene chromosomes was discontinuous in most of the labeled nuclei; in some nuclei the pattern of incorporation was continuous. Comparison of the various labeling patterns of homologous chromosome regions in different nuclei showed that specific replicating units are replicated in a specific order. By combining autoradiography with cytophotometry of Feulgen-stained chromosomes, it was possible to correlate thymidine labeling of specific bands with their DNA content. The resulting data indicate that during the S-period many or perhaps all of the replicating units in a salivary-gland nucleus start DNA synthesis simultaneously but complete it at different times. Furthermore, the data support the hypothesis that the chromomere is a unit of replication or replicon. The DNA content of haploid chromomeres was found to be about 5×10^-4 pg for the largest bands inDrosophila hydei. From the results of H³-thymidine autoradiography and Feulgen-cytophotometry on neuroblast and anlage nuclei it was concluded that during growth of the polytenic nucleus heterochromatin is for the most part excluded from duplication. The results of DNA measurements in interbands of polytene chromosomes do not agree with a multistrand structure for the haploid chromatid. A chromosome model is proposed which is in accordance with the reported results and with current views concerning the replicative organization of chromosomes.