Origin recognition complex binding to a metazoan replication origin

The initiation of DNA replication in eukaryotic cells at the onset of S phase requires the origin recognition complex (ORC) [1]. This six-subunit complex, first isolated in Saccharomyces cerevisiae [2], is evolutionarily conserved [1]. ORC participates in the formation of the prereplicative complex [3], which is necessary to establish replication competence. The ORC-DNA interaction is well established for autonomously replicating sequence (ARS) elements in yeast in which the ARS consensus sequence [4] (ACS) constitutes part of the ORC binding site [2, 5]. Little is known about the ORC-DNA interaction in metazoa. For the Drosophila chorion locus, it has been suggested that ORC binding is dispersed [6]. We have analyzed the amplification origin (ori) II/9A of the fly, Sciara coprophila. We identified a distinct 80-base pair (bp) ORC binding site and mapped the replication start site located adjacent to it. The binding of ORC to this 80-bp core region is ATP dependent and is necessary to establish further interaction with an additional 65-bp of DNA. This is the first time that both the ORC binding site and the replication start site have been identified in a metazoan amplification origin. Thus, our findings extend the paradigm from yeast ARS1 to multicellular eukaryotes, implicating ORC as a determinant of the position of replication initiation.     

The double-strand-break repair model for recombination

We have isolated and characterized several members of the P transposable element family from a Drosophila melanogaster P strain. Large 2.9 kb elements are present as multiple highly conserved copies together with smaller (0.5-1.6 kb), heterogeneous elements. The complete DNA sequences of the 2.9 kb element and four small elements (previously isolated from hybrid-dysgenesis-induced mutations of the white locus) have been determined. Each small element appears to have arisen from the 2.9 kb element by a different internal deletion. P elements have 31 bp perfect inverse terminal repeats and upon insertion duplicate an 8 bp sequence found only once at the site of insertion. Three of the insertions into the white locus occurred at the same nucleotide, indicating a high degree of local site specificity for insertion. The basis of this specificity has been investigated by DNA sequence analysis of the sites where 18 P elements are found. A revertant of one of the white locus mutants has been found to result from precise excision of the P element, restoring the wild-type DNA sequence.     

Structural diversity and dynamics of genomic replication origins in Schizosaccharomyces pombe

DNA replication origins (ORI) in Schizosaccharomyces pombe colocalize with adenine and thymine (A+T)‐rich regions, and earlier analyses have established a size from 0.5 to over 3 kb for a DNA fragment to drive replication in plasmid assays. We have asked what are the requirements for ORI function in the chromosomal context. By designing artificial ORIs, we have found that A+T‐rich fragments as short as 100 bp without homology to S. pombe DNA are able to initiate replication in the genome. On the other hand, functional dissection of endogenous ORIs has revealed that some of them span a few kilobases and include several modules that may be as short as 25–30 contiguous A+Ts capable of initiating replication from ectopic chromosome positions. The search for elements with these characteristics across the genome has uncovered an earlier unnoticed class of low‐efficiency ORIs that fire late during S phase. These results indicate that ORI specification and dynamics varies widely in S. pombe, ranging from very short elements to large regions reminiscent of replication initiation zones in mammals.     

Co-localization of centromere activity,proteins and topoisomerase II within a subdomain of the major human X alpha-satellite array

Dissection of human centromeres is difficult because of the lack of landmarks within highly repeated DNA. We have systematically manipulated a single human X centromere generating a large series of deletion derivatives, which have been examined at four levels: linear DNA structure; the distribution of constitutive centromere proteins; topoisomerase IIalpha cleavage activity; and mitotic stability. We have determined that the human X major alpha-satellite locus, DXZ1, is asymmetrically organized with an active subdomain anchored approximately 150 kb in from the Xp-edge. We demonstrate a major site of topoisomerase II cleavage within this domain that can shift if juxtaposed with a telomere, suggesting that this enzyme recognizes an epigenetic determinant within the DXZ1 chromatin. The observation that the only part of the DXZ1 locus shared by all deletion derivatives is a highly restricted region of <50 kb, which coincides with the topo isomerase II cleavage site, together with the high levels of cleavage detected, identify topoisomerase II as a major player in centromere biology.     

Estrogen-inducible and liver-specific expression of the chicken Very Low Density Apolipoprotein II gene locus in transgenic mice.

We have examined the chicken Very Low Density Apolipoprotein II (apoVLDL II) gene locus in transgenic mice. A DNA fragment composed of the transcribed region, 16 kb of 5' flanking and 400 bp of 3' flanking sequences contained all the information sufficient for estrogen-inducible, liver-specific expression of the apoVLDL II gene. The far-upstream region contains a Negative Regulating Element coinciding with a DNaseI-hypersensitive site at -11 kb. In transgenic mice, the NRE at -11 kb is used for downregulating the expression to a lower maximum level. The NRE might be used for modulating apoVLDL II gene expression, and may be involved in the rapid shut-down of the expression after hormone removal.     

A 46 base pair enhancer sequence within the locus activating region is required for induced expression of the gamma-globin gene during erythroid differentiation.

The locus activating region (LAR), contained within 30 kb of chromatin flanking the human beta-globin gene cluster, has recently been shown to be essential for high level beta-globin gene expression. To determine the effect of fragments containing LAR sequences on globin gene expression, mRNA from a marked gamma-globin gene linked to LAR fragments was assayed in stably transfected K562 erythroleukemia cells. DNaseI hypersensitive site II (HS II), located 10.9 kb upstream of the epsilon-globin gene, was required for high level gamma-globin gene expression. We also showed that a 46 bp enhancer element within HS II was necessary and sufficient for the increased gamma-globin gene expression observed with hemin induced erythroid maturation of K562 cells. These results localize a distant regulatory element important for activation of globin genes during human erythroid cell maturation.     

Long-distance control of origin choice and replication timing in the human beta-globin locus are independent of the locus control region

DNA replication in the human beta-globin locus is subject to long-distance regulation. In murine and human erythroid cells, the human locus replicates in early S phase from a bidirectional origin located near the beta-globin gene. This Hispanic thalassemia deletion removes regulatory sequences located over 52 kb from the origin, resulting in replication of the locus from a different origin, a shift in replication timing to late S phase, adoption of a closed chromatin conformation, and silencing of globin gene expression in murine erythroid cells. The sequences deleted include nuclease-hypersensitive sites 2 to 5 (5'HS2-5) of the locus control region (LCR) plus an additional 27-kb upstream region. We tested a targeted deletion of 5'HS2-5 in the normal chromosomal context of the human beta-globin locus to determine the role of these elements in replication origin choice and replication timing. We demonstrate that the 5'HS2-5-deleted locus initiates replication at the appropriate origin and with normal timing in murine erythroid cells, and therefore we conclude that 5'HS2-5 in the classically defined LCR do not control replication in the human beta-globin locus. Recent studies also show that targeted deletion of 5'HS2-5 results in a locus that lacks globin gene expression yet retains an open chromatin conformation. Thus, the replication timing of the locus is closely correlated with nuclease sensitivity but not globin gene expression.     

Chromatin structure at the replication origins and transcription-initiation regions of the ribosomal RNA genes of Tetrahymena

The chromatin structure of regulatory regions of the extrachromosomal rRNA genes of Tetrahymena thermophila was probed by nuclease treatment of isolated nuclei. The chromatin near the origins of replication contains hypersensitive sites for micrococcal nuclease, DNAase I, and DNAase II. These sites persist in starved cells, consistent with the origins' being maintained in an altered chromatin structure independent of DNA replication. The region between the two origins of replication is organized into a phased array of seven nucleosomes, the fourth of which is centered at the axis of symmetry of the palindromic rDNA. The entire transcribed region and 150 bp upstream from the initiation site are generally accessible to nucleases; any histone proteins associated with these regions are clearly not in a highly organized nucleosomal array as seen in the central region. Comparison of the chromatin structures of the central spacer of T. thermophila and T. pyriformis rDNA reveals that deletion or insertion of DNA has occurred in increments of 200 bp. This is taken to imply that there are constraints on the evolution of spacer DNA sequences at the level of the nucleosome.     

The use of chromosomal translocations to study human immunoglobulin gene organization: mapping DH segments within 35 kb of the C mu gene and identification of a new DH locus.

We have studied the Burkitt's lymphoma cell line Daudi which carries the translocation t(8;14). The breakpoint of this translocation on the 14q+ chromosome occurs near to a rearranged DH-JH join, and the actual chromosome junction is a few hundred base pairs upstream of the joined DH element. The nucleotide sequence of the rearranged DH segment shows that it does not come from the previously described D cluster. Using this DH sequence as a probe we have identified two separate DH clusters. One of these is the major DH cluster and is located only 20 kb upstream of the JH segments. A pseudo-VH (probably the first VH segment) is also found approximately 98 kb from JH. A second, minor DH locus has been found which seems to be located on the distal side of the VH locus on chromosome 14, since there is little evidence for rearrangement or deletion of this locus in any B cell DNA analysed. A single VHIII subgroup gene is located within 25 kb of the newly identified DH element: it is possible that this minor locus occurs near the limit of the Igh locus.     

Two distinct intervening sequences in different ribosomal DNA repeat units of Sciara coprophila.

We have prepared a partial gene library of sheared DNA from the fungus fly, Sciara coprophila, by dA-T tailing and insertion into pBR322. Two ribosomal DNA clones which differ from the usual ribosomal DNA organization in this organism were studied in detail. Clone pBc 1L-1 has an intervening sequence of 1.4 kb, and clone pBc 6D-6 has an intervening sequence of 0.9 kb. These intervening sequences occur in about the same position in 28S rDNA, but do not appear to share sequence homology with one another. Previously we found that 90% of Sciara ribosomal DNA is homogenous and lacks an intervening sequence, and our present data explains the size heterogeneity found in most of the remaining 10%. We have found no evidence of size heterogeneity in the nontranscribed spacer.     

Replication origins in metazoan chromosomes: fact or fiction?

The process by which eukaryotic cells decide when and where to initiate DNA replication has been illuminated in yeast, where specific DNA sequences (replication origins) bind a unique group of proteins (origin recognition complex) next to an easily unwound DNA sequence at which replication can begin. The origin recognition complex provides a platform on which additional proteins assemble to form a pre-replication complex that can be activated at S-phase by specific protein kinases. Remarkably, multicellular eukaryotes, such as frogs, flies, and mammals (metazoa), have counterparts to these yeast proteins that are required for DNA replication. Therefore, one might expect metazoan chromosomes to contain specific replication origins as well, a hypothesis that has long been controversial. In fact, recent results strongly support the view that DNA replication origins in metazoan chromosomes consist of one or more high frequency initiation sites and perhaps several low frequency ones that together can appear as a nonspecific initiation zone. Specific replication origins are established during G1-phase of each cell cycle by multiple parameters that include nuclear structure, chromatin structure, DNA sequence, and perhaps DNA modification. Such complexity endows metazoa with the flexibility to change both the number and locations of replication origins in response to the demands of animal development.