Direct repeats at nuclear matrix-associated DNA regions and their putative control function in the replicating eukaryotic genome

Analysis of the chicken DNA fragments that contain structural sites of attachment to the nuclear matrix: DNA-matrix interactions and replication

Ten short DNA fragments have been selected from a library of the nuclear matrix-attached DNA (nmDNA) from chicken erythrocytes by their ability to hybridize with the fraction of chicken replication origins isolated by nascent DNA strand extrusion. The primary structure of these fragments has been determined. Five of the sequences contained a topoisomerase II recognition site. Most of the studied DNA fragments also have a common eight-nucleotide motif, GCAGACCG/A. A sequence-specific DNA-binding protein with a MW of 55 kDa that interacted with this motif has been identified. Some of the cloned DNA fragments promoted an increased level of transient plasmid replication in transfected chicken cells. The ability of plasmid bearing nmDNA fragments to replicate correlated directly with their ability to target plasmids to the nuclear matrix compartment.

Transcriptional control and the role of silencers in transcriptional regulation in eukaryotes

Mechanisms controlling transcription and its regulation are fundamental to our understanding of molecular biology and, ultimately, cellular biology. Our knowledge of transcription initiation and integral factors such as RNA polymerase is considerable, and more recently our understanding of the involvement of enhancers and complexes such as holoenzyme and mediator has increased dramatically. However, an understanding of transcriptional repression is also essential for a complete understanding of promoter structure and the regulation of gene expression. Transcriptional repression in eukaryotes is achieved through 'silencers', of which there are two types, namely 'silencer elements' and 'negative regulatory elements' (NREs). Silencer elements are classical, position-independent elements that direct an active repression mechanism, and NREs are position-dependent elements that direct a passive repression mechanism. In addition, 'repressors' are DNA-binding trasncription factors that interact directly with silencers. A review of the recent literature reveals that it is the silencer itself and its context within a given promoter, rather than the interacting repressor, that determines the mechanism of repression. Silencers form an intrinsic part of many eukaryotic promoters and, consequently, knowledge of their interactive role with enchancers and other transcriptional elements is essential for our understanding of gene regulation in eukaryotes.

A soluble transcription factor, Oct-1, is also found in the insoluble nuclear matrix and possesses silencing activity in its alanine-rich domain

Expression of the human thyrotropin beta (hTSHbeta) gene is restricted to thyrotrophs, at least in part, by silencing. Using transient-transfection assays, we have localized a silencer element to a region between -128 and -480 bp upstream of the transcription initiation site. The silencing activity was overcome in a thyrotroph-specific manner by an unknown enhancer located in the sequences at -approximately 10000 to -1200 bp. The ubiquitous POU homeodomain protein Oct-1 recognized the A/T-rich silencer element at multiple sites in gel mobility shift assays and in vitro footprinting analyses. The silencing activity of Oct-1 was localized in its C-terminal alanine-rich domain, suggesting that Oct-1 plays a role in silencing of the hTSHbeta promoter. Further, a significant fraction of Oct-1 was shown to be associated with the nuclear matrix, and the hTSHbeta silencer region was tethered to a nuclear matrix of human cells in vivo, suggesting a possible role of the Oct-1-hTSHbeta silencer region interaction in chromatin organization.

Northern blot analysis of simple repetitive sequence transcription in plants

The presence of simple repetitive sequence motifs in RNA from various plant species was probed by Northern blot analysis. Hybridization of total, poly(A)(+)- and poly(A)(-)-RNA with microsatellite-complementary oligonucleotide probes revealed distinct bands with most but not all probe/species combinations, demonstrating the presence of di-, tri- and tetranucleotide repeat motifs in plant transcripts. Only trinucleotide repeat-derived hybridization signals were found to be enriched in the poly(A)(+)-fraction. The quality of Northern blot signals proved to be highly dependent on hybridization stringency. Thus, under the stringency conditions usually applied for oligonucleotide hybridization, some probes [(GT)8, (CAC)5, (TCC)5, and (CCTA)4] cross-hybridized to bands corresponding in size to 18S and/or 26S rRNA. Cross-hybridization to rRNA was significantly reduced at higher stringencies. These results stress the importance of carefully adjusting the hybridization conditions in Northern blot analysis of simple sequence transcripts.

Selective binding of specific mouse genomic DNA fragments by mouse vimentin filaments in vitro

Mouse vimentin intermediate filaments (IFs) reconstituted in vitro were analyzed for their capacity to select certain DNA sequences from a mixture of about 500-bp-long fragments of total mouse genomic DNA. The fragments preferentially bound by the IFs and enriched by several cycles of affinity binding and polymerase chain reaction (PCR) amplification were cloned and sequenced. In general, they were G-rich and highly repetitive in that they often contained Gn, (GT)n, and (GA)n repeat elements. Other, more complex repeat sequences were identified as well. Apart from the capacity to adopt a Z-DNA and triple helix configuration under superhelical tension, many fragments were potentially able to form cruciform structures and contained consensus binding sites for various transcription factors. All of these sequence elements are known to occur in introns and 5'/3'-flanking regions of genes and to play roles in DNA transcription, recombination and replication. A FASTA search of the EMBL data bank indeed revealed that sequences homologous to the mouse repetitive DNA fragments are commonly associated with gene-regulatory elements. Unexpectedly, vimentin IFs also bound a large number of apparently overlapping, AT-rich DNA fragments that could be aligned into a composite sequence highly homologous to the 234-bp consensus centromere repeat sequence of gamma-satellite DNA. Previous experiments have shown a high affinity of vimentin for G-rich, repetitive telomere DNA sequences, superhelical DNA, and core histones. Taken together, these data support the hypothesis that, after penetration of the double nuclear membrane via an as yet unidentified mechanism, vimentin IFs cooperatively fix repetitive DNA sequence elements in a differentiation-specific manner in the nuclear periphery subjacent to the nuclear lamina and thus participate in the organization of chromatin and in the control of transcription, replication, and recombination processes. This includes aspects of global regulation of gene expression such as the position effects associated with translocation of genes to heterochromatic centromere and telomere regions of the chromosomes.

Specificity and functional significance of DNA interaction with the nuclear matrix: new approaches to clarify the old questions

In this chapter the specificity of chromosomal DNA partitioning into topological loops is discussed. Different experimental approaches used for the analysis of the above problem are critically reviewed. This discussion is followed by presentation of a novel approach for mapping the DNA loop anchorage sites that we have developed. This approach, based on the excision of the whole DNA loops by topoisomerase II-mediated DNA cleavage at matrix attachment sites, seems to constitute a unique tool for the analysis of topological organization of chromosomal DNA in living cells. We also discuss experimental results indicating that the DNA-loop anchorage sites form "weak points" in chromosomes that are preferentially sensitive to cleavage with both endogenous and exogenous nucleases. In connection with this discussion, rationales for the supposition that DNA loops constitute basic units of eukaryotic genome organization and evolution are considered. The chapter concludes by suggesting a new model of spatial organization of eukaryotic genome within the cell nucleus that resolves apparent contradictions between different data on the specificity of DNA interaction with the nuclear matrix.

Physiological aspects of genome variability in tissue culture. II. Growth phase-dependent quantitative variability of repetitive BstNI fragments of primary cultures of Daucus carota L

Systematic investigations on the occurrence of differential DNA replication in carrot cultures, expressed at the total genome level, were performed. The genome of Daucus carota L. could be characterized by a pattern of repetitive BstNI fragments that was independent of tissue specificity or cultivar differences. Characterization of the genomic DNA of the secondary phloem of carrot roots, in comparison to the DNA of the induced primary cultures at different growth phases, revealed dramatic differences in the copy number of the repetitive fragments. Highly proliferative tissue showed extensive reduction in the proportion of repetitive sequences in the genome in all of the 37 investigated variants. In contrast, during subsequent transition to stationary growth the repetitive fragments re-amplified. The results suggest that the quantitative genome organisation was involved in the regulation of the growth potential of cells. A hypothesis is discussed suggesting a determining influence of the observed differential DNA replication on cell-cycle rates and the cell program of proliferative tissue by structural and positioning effects on DNA loops. To study the causality of somaclonal variation, research on the relationship between physiological genome variability and the induction of heritable changes is recommended.

Nuclear matrix-associated DNA fragments enhance autonomous replication of plasmids in chicken cells

Most cells of higher eukaryotes may maintain several rounds of replication of circular DNA. Efficiency of replication is usually low, and depends on the length of the circular DNA rather than on the sequence context. We have isolated and characterized several short DNA fragments that form structural sites of attachment to the nuclear matrix (nmDNA) in chicken cells, and tested whether they would enhance autonomous replication of DNA in chicken cells as compared to the vector DNA. Indeed, a several-fold increase in a short-term replication efficiency was detected using a semi-conservative replication and a DpnI-resistance assay. Most of the cloned matrix-associated fragments were recovered in the nuclear matrix fraction when introduced into cultured chicken cells as a circular DNA. The data obtained suggest that the observed enhancement in the replication efficiency of the circular DNA may be due to their recruitment to the nuclear matrix by the nmDNA.

Conformations of the alternating (C-T)n sequence under neutral and low pH

The structures of the (C-T)n sequence at two different pHs have been analyzed by 500 MHz 2D-NMR using a modified DNA decamer d(CT[m5C]TCU[m5C]UCT) as a model system. The chemical modifications serve to perturb the monotonous C-T repeat, and consequently to yield a better chemical shift dispersion. The results reinforce our earlier suggestion that there are three major pH-dependent conformational species: two antiparallel-stranded (APS) duplexes at pH 7 and pH 3, and a different structure near pH 5. Structural refinement of the decamer duplexes at pH = 7.5 and pH = 2.9 using 2D-NOE data suggests that the C:T or C+:T base pairs are continuously stacked. Exchangeable proton NMR spectra at pH 7.5 and pH 2.9 are consistent with C:T or C+:T base pairing schemes in which a water molecule bridges the two bases.

NMR studies of pH-dependent conformational polymorphism of alternating (C-T)n sequences

Alternating (C-T)n sequences are involved in the H-DNA structure associated with (GA)n.(CT)n sequences. Low pH values facilitate H-DNA formation. We have undertaken a detailed analysis of the structural consequences of the (C-T)n sequence as a function of pH. The structures of three DNA oligonucleotides, d(CT)4, d(TC)4 and d(TC)15, have been studied by NMR. We found that their conformations are polymorphic and pH dependent. There are at least three major conformational species: an antiparallel-stranded (APS) duplex with entirely C:T base pairs at pH 7, an antiparallel-stranded (APS) duplex with entirely C+:T base pairs at pH 3, and a possible parallel-stranded (PS) duplex with C+:C and T:T base pairs near pH 5. In the intermediate pH range, the APS duplex may have varying numbers of C+:T and C:T base pairs, and there may be a fast exchange going on between APS duplex species involving these two kinds of base pairs. However, the transition between the APS and PS duplexes is slow. Structural refinement of the two octamers, d(TC)4 and d(CT)4, at pH = 6.9 and pH = 3 using 2D-NOE data suggests that the molecules are likely in the duplex form at 5 degrees C. We lack evidence that the structure at pH 3 is a PS structure with T nucleotides residing in the exterior of the helix. Titration of the longer oligonucleotide, d(TC)15, showed a prominent pKa of approximately 6, approaching the value of 7.0 obtained from the titration of poly-(dC).

Association of fragile X syndrome with delayed replication of the FMR1 gene

The fragile X syndrome is commonly associated with mutant alleles of the FMR1 gene that are hypermethylated and have large expansions of CGG repeats. We present data here on the replication timing of FMR1 that confirm predictions of delayed replication of alleles from affected males. The normal FMR1 allele replicates late in S phase, while alleles from affected males replicate later, the major peak of replication occurring in the flow cytometry fraction usually referred to as G2/M. The delayed timing of replication is not the direct result of a single replication fork stalling at the expanded CGG repeat, because delayed replication was observed for regions on both sides of the repeat. The domain of altered replication timing includes sites at least 150 kb 5' and 34 kb 3' of the repeat, indicating that genes in addition to FMR1 may be affected.

DNA fingerprinting in sugar beet (Beta vulgaris) - identification of double-haploid breeding lines

The distribution and abundance of simple repetitive sequences complementary to the synthetic oligonucleotides (GACA)4, (GATA)4, (GTG)5 and (CA)8 in the genomes of several cultivars of Beta vulgaris and in the wild beet B. vulgaris ssp. maritima were investigated. Hybridization experiments revealed that all four motifs were present, though at different abundances, in the genomes of all of the investigated beet cultivars. Considerable intraspecific variation of the resulting DNA fingerprints was observed. The extent of polymorphism depends on the oligonucleotide probe. The most informative banding patterns were obtained with the (GATA)4 probe hybridized to HinfI-, HaeIII-, or RsaI-restricted DNA, respectively. DNA fingerprinting with (GATA)4 allowed a clear differentiation of double-haploid breeding lines (DH lines). We demonstrated that the application of oligonucleotide probes for DNA fingerprinting is a sensitive tool for genome diagnosis in cultivated beet.

Control of eukaryotic DNA replication at the chromosomal level

A hypothesis for the control of eukaryotic DNA replication at the chromosomal level is proposed. The specific regulatory problem arises from the subdivision of the genome into thousands of individually replicating units, each of which must be duplicated a single time during S-phase. The hypothesis is based on the finding of direct repeats at replication origins. Such repeats can adopt, beyond the full-length double helical structure, another configuration exposing two single-stranded loops that provide suitable templates for the initiation of DNA replication. Any further initiation at the same origin is excluded as the single strandedness is eliminated by the replication process. Restoration of the initiable loop structure is proposed to occur by DNA-protein rearrangements involved in chromosome condensation and duplication of the chromosomal protein backbone during mitosis. A possible role of the maturation promoting factor (MPF) is suggested.

Identification of novel single-stranded d(TC)n binding proteins in several mammalian species

A group of single-stranded d(TC)n specific binding proteins has been detected in the nuclear extracts of several mammalian species that included mouse, human, African green monkey, chimpanzee, and Chinese muntjac. Southwestern analysis of 500 mM KCI nuclear extracts has shown that these proteins cluster in a similar size range, 55.5 to 57 kD. An additional 54 kD band was present for the three primate species examined. The single-stranded d(TC)n binding activity was confirmed with bandshift assay. Specific double-stranded binding activity for duplex d(TC)n.d(GA)n or single-stranded d(GA)n was not detected. The conservation of size distribution and d(TC)n-binding activity across the species examined indicates that this class of single-stranded binding proteins may have an important biological function in vivo.

Specific organization of genes in relation to the sperm nuclear matrix

We have recently reported that mammalian sperm DNA, the most highly condensed and functionally inert eukaryotic DNA, is organized into DNA loop domains attached at their bases to a sperm nuclear matrix (Chromosoma, 98: 153, 1989). We report here the specific arrangement of genes within the sperm loop domains by measuring the proximity of six hamster genes to the sperm nuclear matrix. After restriction endonuclease treatment of sperm nuclear matrices, five genes were clearly not associated with the sperm nuclear matrix and only one, alpha A-crystallin, was within 2 Kb of the matrix. This suggests that sperm DNA is organized in a specific manner in relation to the sperm matrix.

Chromosome reproduction: units of DNA for segregation

Evidence is summarized which indicates that the DNA loop anchoring proteins in chromosomes are effectively heterodimers that stack and are fastened into a bilaterally symmetrical array along the chromonemal axis. The evidence consists primarily of the observations made twenty five to thirty years ago on the pattern of sister chromatid exchanges and the way the DNA chains are sorted in the formation of diplochromosomes in cells that have undergone endoreduplication. The evidence indicates that each chain of DNA in the single duplex, which is assumed to run the length of a chromosome, is anchored to a bilaterally symmetrical axis of heterodimers that sort the two original chains among the four derived chromatids of each diplochromosome in a very precise way. These observations are considered in the context of investigations on the nature of scaffold proteins and the loop anchorage sequences, as well as the advances being made on the nature of DNA binding proteins and the roles of topoisomerase II.