DNA loop domains in a 1.4-Mb region around the human hprt gene mapped by cleavage mediated by nuclear matrix-associated topoisomerase II

We have mapped the positions in a ～1.4-Mb region of genomic DNA around the human hprt gene which are accessible in vivo to cleavage by topoisomerase II associated with the nuclear matrix. These positions, which are interpreted as the boundaries of DNA loop domains, were mapped in K562 cells by examining the truncation of rare-cutter restriction fragments separated by pulsed field gel electrophoresis after topoisomerase II-mediated cleavage, using seven linked markers mapped in this region as probes for indirect end-labeling. Eleven cleavage positions were detected and were interpreted as defining ten loop domains of lengths between 70 and 210?kb (average ～135?kb); the hprt gene resides in a 150-kb loop domain. Loop domain boundaries coincided with three of the fifteen deletion breakpoints mapped in a 600-kb sector of this region in human lymphocytes, within the limits of resolution of pulsed field gel electrophoresis; this correlation was not statistically significant.     

DNA loop domains in a 1.4-Mb region around the human hprt gene mapped by cleavage mediated by nuclear matrix-associated topoisomerase II

We have mapped the positions in a ∼1.4-Mb region of genomic DNA around the human hprt gene which are accessible in vivo to cleavage by topoisomerase II associated with the nuclear matrix. These positions, which are interpreted as the boundaries of DNA loop domains, were mapped in K562 cells by examining the truncation of rare-cutter restriction fragments separated by pulsed field gel electrophoresis after topoisomerase II-mediated cleavage, using seven linked markers mapped in this region as probes for indirect end-labeling. Eleven cleavage positions were detected and were interpreted as defining ten loop domains of lengths between 70 and 210 kb (average ∼135 kb); the hprt gene resides in a 150-kb loop domain. Loop domain boundaries coincided with three of the fifteen deletion breakpoints mapped in a 600-kb sector of this region in human lymphocytes, within the limits of resolution of pulsed field gel electrophoresis; this correlation was not statistically significant. Received: 14 June 1998 / Accepted: 4 September 1998     

Conserved chromatin structure in c-myc 5'flanking DNA after viral transduction

The role of local sequence information in establishing the chromatin structure of the human c-myc upstream region (MUR) was investigated. Adeno-associated virus (AAV)-mediated gene transduction was used to introduce an additional unrearranged copy of the 2.4 kb HindIII-XhoI fragment of the MUR into a novel location in the genome in each of two cloned HeLa cell lines. The AAV-based rep- cap- viral vector SKMA used to transduce the MUR retained only 1.4 kb (24%) of the AAV genome and could accommodate inserts as large as 2.4 kb. SKMA was capable of infecting HeLa cells and integrating into the host genome at single copy number. Integration may have occurred at a preferred site in the HeLa genome, but this site was apparently distinct from the previously identified preferred AAV integration site on human chromosome 19. Indirect end-labelling was used to map DNase I and micrococcal nuclease (MNase) cleavage sites over the transduced c-myc sequences and the endogenous c-myc loci in infected HeLa cells. A similarly ordered chromatin domain, extending 5' from c-myc promoter P0, was found to exist at the transduced c-myc locus in each clone. The position and relative sensitivity of 13 MNase cleavage sites and five DNase I hypersensitive sites, originally identified at the endogenous MUR in non-transduced cells, were shown to be conserved when this DNA was moved to a new chromosome site. A conserved DNase I hypersensitive site also was mapped to the region between the left AAV terminal repeat and AAV promoter P5. These results suggest that the information required to establish the particular chromatin structure of the MUR resides within the local DNA sequence of that region.     

DNA loop anchorage region colocalizes with the replication origin located downstream to the human gene encoding lamin B2

The recently developed procedure of topoisomerase II-mediated DNA loop excision has been used to analyze the topological organization of a human genome fragment containing the gene encoding lamin B2 and the ppv1 gene. A 3.5 kb long DNA loop anchorage/topoisomerase II cleavage region was found within the area under study. This region includes the end of the lamin B2 coding unit and an intergenic region where an origin of DNA replication was previously found. These observations further corroborate the hypothesis that DNA replication origins are located at or close to DNA loop anchorage regions. J. Cell. Biochem. 69:13–18, 1998. © 1998 Wiley-Liss, Inc.     

Tissue specific and position independent expression of the complete gene domain for chicken lysozyme in transgenic mice.

A 21.5 kb DNA fragment carrying the entire chicken lysozyme gene locus was introduced into the germ line of mice. The fragment contains the transcribed region plus 11.5 kb 5'-flanking and 5.5 kb 3'-flanking sequences including all known cis-regulatory elements and the 5' and 3' attachment elements (A-elements) which define the borders of the DNase I sensitive chromatin domain. All sequences which adopt a DNase I hypersensitive chromatin conformation in vivo are present on the construct. Seven founder mice were analysed. All of these expressed chicken lysozyme RNA at high levels specifically in macrophages, as is the case in the donor species. Expression levels are dependent on the copy number of integrated genes indicating that a complete gene locus, as defined by its chromatin structure, functions as an independent regulatory unit when introduced into a heterologous genome.     

Ability of hamster spermatozoa to digest their own DNA

Mammalian sperm chromatin is bound by protamines into highly condensed toroids with approximately 50 kilobases (kb) of DNA. It is also organized into loop domains of about the same size that are attached at their bases to the proteinaceous nuclear matrix. In this work, we test our model that each sperm DNA-loop domain is condensed into a single protamine toroid. Our model predicts that the protamine toroids are linked by chromatin that is more sensitive to nucleases than the DNA within the toroids. To test this model, we treated hamster sperm nuclei with DNase I and found that the sperm chromatin was digested into fragments with an average size of about 50 kb, by pulse-field gel electrophoresis (PFGE). Surprisingly, we also found that spermatozoa treated with 0.25% Triton X-100 (TX) and 20 mM MgCl2 overnight resulted in the same type of degradation, suggesting that sperm nuclei have a mechanism for digesting their own DNA at the bases of the loop domains. We extracted the nuclei with 2 M NaCl and 10 mM dithiothreitol (DTT) to make nuclear halos. Nuclear matrices prepared from DNase I-treated spermatozoa had no DNA attached, suggesting that DNase I digested the DNA at the bases of the loop domains. TX-treated spermatozoa still had their entire DNA associated with the nuclear matrix, even though the DNA was digested into 50-kb fragments as revealed by PFGE. The data support our donut-loop model for sperm chromatin structure and suggest a functional role for this type of organization in that sperm can digest its own DNA at the sites of attachment to the nuclear matrix.     

Pulsed-field gel electrophoresis analysis of higher-order chromatin structures of Zea mays. Highly methylated DNA in the 50 kb chromatin structure

We have investigated the presence of higher-order chromatin structures in different maize tissues. Taking advantage of the pulsed-field gel electrophoresis technique to analyse large DNA fragments from intact nuclei and cells, we have determined the size distribution of the high-molecular-weight DNA fragments obtained from chromatin degradation by endogenous nucleases in isolated nuclei. Chromatin digestion leads to the appearance of stable DNA fragments of about 50 kb in all the tissues examined, suggesting the folding of DNA in higher-order chromatin domain structures. It has been reported that such chromatin domains are formed by loops of the 30 nm fibres anchored to the nuclear matrix by a complex set of proteins, including DNA topoisomerase II. Treatment of maize protoplasts with the calcium ionophore A23187 and the antitumour drug VM-26, which specifically inhibit the religation of the cleaved DNA in the topoisomerase II reaction, also produces the 50 kb structure. Analysis of the DNA contained in the 50 kb chromatin structure shows a higher degree of methylation than in bulk maize chromosomal DNA. The role of methylated DNA in the chromatin folding is discussed.     

The role of topoisomerase II in the excision of DNA loop domains during apoptosis

Disintegration of nuclear DNA into high molecular weight (HMW) and oligonucleosomal DNA fragments represents two major periodicities of DNA fragmentation during apoptosis. These are thought to originate from the excision of DNA loop domains and from the cleavage of nuclear DNA at the internucleosomal positions, respectively. In this report, we demonstrate that different apoptotic insults induced apoptosis in NB-2a neuroblastoma cells that was invariably accompanied by the formation of HMW DNA fragments of about 50-100 kb but proceeded either with or without oligonucleosomal DNA cleavage, depending on the type of apoptotic inducer. We demonstrate that differences in the pattern of DNA fragmentation were reproducible in a cell-free apoptotic system and develop conditions that allow in vitro separation of the HMW and oligonucleosomal DNA fragmentation activities. In contrast to apoptosis associated with oligonucleosomal DNA fragmentation, the HMW DNA cleavage in apoptotic cells was accompanied by down-regulation of caspase-activated DNase (CAD) and was not affected by z-VAD-fmk, suggesting that the caspase/CAD pathway is not involved in the excision of DNA loop domains. We further demonstrate that nonapoptotic NB-2a cells contain a constitutively present nuclease activity located in the nuclear matrix fraction that possessed the properties of topoisomerase (topo) II and was capable of reproducing the pattern of HMW DNA cleavage that occurred in apoptotic cells. We demonstrate that the early stages of apoptosis induced by different stimuli were accompanied by activation of topo II-mediated HMW DNA cleavage that was reversible after removal of apoptotic inducers, and we present evidence of the involvement of topo II in the formation of HMW DNA fragments at the advanced stages of apoptosis. The results suggest that topo II is involved in caspase-independent excision of DNA loop domains during apoptosis, and this represents an alternative pathway of apoptotic DNA disintegration from CAD-driven caspase-dependent oligonucleosomal DNA cleavage.     

Aging and Loss of Germination in Rye Seeds Is Accompanied by a Decreased Fragmentation of Nuclear DNA at Loop Domain Boundaries

To investigate the processes that occur in the embryo cell nuclei in the course of natural and accelerated aging of rye seeds, nuclear DNA structural organization into chromatin loop domains was studied. The loss of germination was shown to be accompanied by a decreased excision of chromatin loop domains. The study of chromatin accessibility to DNase I did not reveal any considerable changes in chromatin architecture that would explain the decreased DNA fragmentation at matrix attachment regions. A soluble nuclear protein of ca. 31 kD was found to manifest nuclease activity, which declined with the loss of germination. The study of DNA fragmentation in histone-depleted nuclei (nucleoids) disclosed a nuclease activity resistant to 2 M NaCl extraction and sensitive to the specific inhibitors of DNA topoisomerase II; the latter activity also declined with aging. The authors conclude that the changes in DNA fragmentation patterns in aging seeds were primarily caused by a decreased activity of the enzymes accounting for the excision of chromatin loop domains.     

Developmental switch in chromatin structure associated with alternate promoter usage in the Drosophila melanogaster alcohol dehydrogenase gene.

During the development of Drosophila melanogaster a switch in alcohol dehydrogenase gene promoter usage occurs, such that proximally initiated mRNA is replaced by mRNA initiated from a more distal location. Investigation of the nucleo-protein organization at this gene in cells inactive for Adh expression, or derived from tissues active at either the proximal or distal promoter, reveals distinct changes in patterns of nucleosome organization and regions of nuclease sensitivity that are strongly correlated with the activity of the gene and its promoter usage. A positioned array of nucleosomes covers the coding region of the inactive gene, but is partially disassembled on gene activation. A series of proximally located hypersensitive sites, detected in early third instar larval fat body cells, are replaced by new, distally located regions of hypersensitivity in late third instar larval fat body, the change apparently coinciding with the promoter switch. Further developmental stage differences are detected in regions over 1 kb upstream of the distal start site. In addition, for both proximally and distally expressing cells, separate and different regions of apparent resistance to DNase I cleavage in chromatin are detected in locations that, in some instances, were previously demonstrated to bind specific factors in vitro.     

Analysis of the chromatin domain organisation around the plastocyanin gene reveals an MAR-specific sequence element in Arabidopsis thaliana.

The Arabidopsis thaliana genome is currently being sequenced, eventually leading towards the unravelling of all potential genes. We wanted to gain more insight into the way this genome might be organized at the ultrastructural level. To this extent we identified matrix attachment regions demarking potential chromatin domains, in a 16 kb region around the plastocyanin gene. The region was cloned and sequenced revealing six genes in addition to the plastocyanin gene. Using an heterologous in vitro nuclear matrix binding assay, to search for evolutionary conserved matrix attachment regions (MARs), we identified three such MARs. These three MARs divide the region into two small chromatin domains of 5 kb, each containing two genes. Comparison of the sequence of the three MARs revealed a degenerated 21 bp sequence that is shared between these MARs and that is not found elsewhere in the region. A similar sequence element is also present in four other MARs of Arabidopsis.Therefore, this sequence may constitute a landmark for the position of MARs in the genome of this plant. In a genomic sequence database of Arabidopsis the 21 bp element is found approximately once every 10 kb. The compactness of the Arabidopsis genome could account for the high incidence of MARs and MRSs we observed.     

The DNase I sensitive state of "active" globin gene chromatin resists trypsin treatments which disrupt chromatin higher order structure

Active genes in higher eukaryotes reside in chromosomal domains which are more sensitive to digestion by DNase I than the surrounding inactive chromatin. Although it is widely assumed that some modification of higher order structure is important to the preferential DNase I sensitivity of active chromatin, this has so far not been tested. Here we show that the structural distinction between DNase I sensitive and resistant chromatin is remarkably stable to digestion by trypsin. Chick embryonic red blood cell nuclei were subjected to increasing levels of trypsin digestion and then assayed in the following three ways: (1) by gel electrophoresis for histone cleavage, (2) by sedimentation and nuclease digestion for loss of higher order structure, and (3) by dot-blot hybridization to globin and ovalbumin probes for disappearance of preferential DNase I sensitivity. We have found that chromatin higher order structure is lost concomitantly with the cleavage of histones H1, H5, and H3. In contrast, the preferential sensitivity of the globin domain to DNase I persists until much higher concentrations of trypsin, and indeed is not completely abolished even by the highest levels of trypsin we have used. We therefore conclude that the structural distinction of active chromatin, recognized by DNase I, does not reside at the level of higher order structure.