A yeast chromosomal origin of DNA replication defined by multiple functional elements.

Although it has been demonstrated that discrete origins of DNA replication exist in eukaryotic cellular chromosomes, the detailed organization of a eukaryotic cellular origin remains to be determined. Linker substitution mutations were constructed across the entire Saccharomyces cerevisiae chromosomal origin, ARS1. Functional studies of these mutants revealed one essential element (A), which includes a match to the ARS consensus sequence, and three additional elements (B1, B2, and B3), which collectively are also essential for origin function. These four elements arranged exactly as in ARS1, but surrounded by completely unrelated sequence, functioned as an efficient origin. Element B3 is the binding site for the transcription factor-origin binding protein ABF1. Other transcription factor binding sites substitute for the B3 element and a trans-acting transcriptional activation domain is required. The multipartite nature of a chromosomal replication origin and the role of transcriptional activators in its function present a striking similarity to the organization of eukaryotic promoters.

Global DNA methylation profiling reveals silencing of a secreted form of Epha7 in mouse and human germinal center B-cell lymphomas.

Most human lymphomas originate from transformed germinal center (GC) B lymphocytes. While activating mutations and translocations of MYC, BCL2 and BCL6 promote specific GC lymphoma subtypes, other genetic and epigenetic modifications that contribute to malignant progression in the GC remain poorly defined. Recently, aberrant expression of the TCL1 proto-oncogene was identified in major GC lymphoma subtypes. TCL1 transgenic mice offer unique models of both aggressive GC and marginal zone B-cell lymphomas, further supporting a role for TCL1 in B-cell transformation. Here, restriction landmark genomic scanning was employed to discover tumor-associated epigenetic alterations in malignant GC and marginal zone B-cells in TCL1 transgenic mice. Multiple genes were identified that underwent DNA hypermethylation and decreased expression in TCL1 transgenic tumors. Further, we identified a secreted isoform of EPHA7, a member of the Eph family of receptor tyrosine kinases that are able to influence tumor invasiveness, metastasis and neovascularization. EPHA7 was hypermethylated and repressed in both mouse and human GC B-cell non-Hodgkin lymphomas, with the potential to influence tumor progression and spread. These data provide the first set of hypermethylated genes with the potential to complement TCL1-mediated GC B-cell transformation and spread.

Functional conservation of multiple elements in yeast chromosomal replicators.

Replicators that control the initiation of DNA replication in the chromosomes of Saccharomyces cerevisiae retain their function when cloned into plasmids, where they are commonly referred to as autonomously replicating sequences (ARSs). Previous studies of the structure of ARS1 in both plasmid and chromosome contexts have shown that it contains one essential DNA element, A, that includes a match to the ARS consensus sequence (ACS), and three additional elements, B1, B2, and B3, that are also important for ARS function. Elements A and B3 are bound by a candidate initiator protein called the origin recognition complex and ARS-binding factor 1, respectively. Although the A and B3 elements have been found in other ARSs, sequence comparisons among ARSs have failed to identify B1- and B2-like elements. To assess the generality of the modular nature of yeast replicators, linker substitution mutagenesis of another yeast chromosomal replicator, ARS307, was performed. Three DNA sequence elements were identified in ARS307, and they were demonstrated to be functionally equivalent to the A, B1, and B2 elements present in ARS1. Despite the lack of DNA sequence similarity, the B1 and B2 elements at each ARS were functionally conserved. Single-base substitutions in the core of the ARS1 B1 and B2 elements identified critical nucleotides required for the function of the B1 element. In contrast, no single-point mutations were found to affect B2 function. The results suggest that multiple DNA sequence elements might be a general and conserved feature of replicator sequences in S. cerevisiae.

A link between repetitive sequences and gene replication time.

Genes display a wide range of replication times in S phase. In general, late replication is associated with transcriptionally repressive states and early replication with transcriptional competence. Rare examples of early-replicating repressive states have also been identified that are consistent with molecular evidence that repressive states are not all uniform in nature. Here we show that the replication times of over 4000 Drosophila genes correlate with the abundance of repetitive sequences in approximately 200-kb regions flanking the genes. In particular, Satellite-Related sequences (SRs) and the simple sequence repeats (SSRs) (CA)n and (ACTG)n were increasingly abundant in the regions flanking progressively later replicating genes, while (CATA)n repeats were more abundant around earlier replicating genes. These four sequences comprise less than 0.5% of the 'euchromatic genome' in Drosophila, yet they account for 5% of the variation of gene replication timing. Although the effect is not strong, it is broad: 99% of the genome is within the region of correlation of at least one of the above repeats. The role of SSRs and non-centromeric SRs in the genome is not known. We propose that SSRs and SRs foster transcriptionally repressive states throughout the genome in order to minimize spurious transcription.

Mammalian X chromosome inactivation.

X chromosome inactivation in mammals requires expression of the gene Xist, which maps to the X chromosome inactivation centre (Xic) and encodes an untranslated RNA. Truncation of Xist RNA by gene targeting is lethal for female embryos and prevents the inactivation of the X chromosome carrying the deletion. This indicates that Xist RNA is necessary for initiation and propagation of the inactivation process. Xist is transcribed from the inactive X and its expression is silenced by DNA methylation, suggesting that methylation is crucial for shielding the active X chromosome against the inactivation process. Gene transfer experiments using transgenes the size of yeast artificial chromosomes have determined that a 450 kb fragment of DNA carrying Xist acts as an inactivation centre and is sufficient for initiation, propagation and maintenance of the inactive state. The elements for counting and choosing X chromosomes are part of the transgene. We have shown that X inactivation is mediated by a post-translational mechanism, i.e. the stabilization of Xist RNA, rather than by the regulation of the Xist promoter.

Replicator dominance in a eukaryotic chromosome.

Replicators are genetic elements that control initiation at an origin of DNA replication (ori). They were first identified in the yeast Saccharomyces cerevisiae as autonomously replicating sequences (ARSs) that confer on a plasmid the ability to replicate in the S phase of the cell cycle. The DNA sequences required for ARS function on a plasmid have been defined, but because many sequences that participate in ARS activity are not components of chromosomal replicators, a mutational analysis of the ARS1 replicator located on chromosome IV of S. cerevisiae was performed. The results of this analysis indicate that four DNA elements (A, B1, B2 and B3) are either essential or important for ori activation in the chromosome. In a yeast strain containing two closely spaced and identical copies of the ARS1 replicator in the chromosome, only one is active. The mechanism of replicator repression requires the essential A element of the active replicator. This element is the binding site for the origin recognition complex (ORC), a putative initiator protein. The process that determines which replicator is used, however, depends entirely upon flanking DNA sequences.

Role of the Xist gene in X chromosome choosing.

In female mammals a "random choice" mechanism decides which of the two X chromosomes will be inactivated. It has been postulated that Xist is crucial for heterochromatinization and thus functions downstream of the choice mechanism. Here we report that females heterozygous for an internal deletion in the Xist gene, which includes part of exon 1 and extends to exon 5, undergo primary nonrandom inactivation of the wild-type X chromosome. The Xist gene, therefore, not only has a role in chromatin remodeling, but also includes an element required for X chromosome choosing. In conflict with the prevailing view of how choosing occurs, the element identified by the deletion plays a positive role in the choice mechanism and forces a reassessment of how X chromosome choosing is thought to occur.

DNA replication and the cell cycle.

The replication of DNA in the eukaryotic cell cycle is one of the most highly regulated events in cell growth and division. Biochemical studies on the replication of the genome of the small DNA virus simian virus 40 (SV40) have resulted in the identification of a number of DNA replication proteins from human cells. One of these, Replication Protein A (RPA), was phosphorylated in a cell cycle-dependent manner, beginning at the onset of DNA replication. RPA was phosphorylated in vitro by the cell cycle-regulated cdc2 protein kinase. This kinase also stimulated the unwinding of the SV40 origin of DNA replication during initiation of DNA replication in vitro, suggesting a mechanism by which cdc2 kinase may regulate DNA replication. Functional homologues of the DNA replication factors have been identified in extracts from the yeast Saccharomyces cerevisiae, enabling a genetic characterization of the role of these proteins in the replication of cellular DNA. A cellular origin binding protein had not been characterized. To identify proteins that function like T antigen at cellular origins of DNA replication, we examined the structure of a yeast origin of DNA replication in detail. This origin consists of four separate functional elements, one of which is essential. A multiprotein complex that binds to the essential element has been identified and purified. This protein complex binds to all known cellular origins from S. cerevisiae and may function as an origin recognition complex.

Xist-deficient mice are defective in dosage compensation but not spermatogenesis.

The X-linked Xist gene encodes a large untranslated RNA that has been implicated in mammalian dosage compensation and in spermatogenesis. To investigate the function of the Xist gene product, we have generated male and female mice that carry a deletion in the structural gene but maintain a functional Xist promoter. Mutant males were healthy and fertile. Females that inherited the mutation from their mothers were also normal and had the wild-type paternal X chromosome inactive in every cell. In contrast to maternal transmission, females that carry the mutation on the paternal X chromosome were severely growth-retarded and died early in embryogenesis. The wild-type maternal X chromosome was inactive in every cell of the growth-retarded embryo proper, whereas both X chromosomes were expressed in the mutant female trophoblast where X inactivation is imprinted. However, an XO mouse with a paternally inherited Xist mutation was healthy and appeared normal. The imprinted lethal phenotype of the mutant females is therefore due to the inability of extraembryonic tissue with two active X chromosomes to sustain the embryo. Our results indicate that the Xist RNA is required for female dosage compensation but plays no role in spermatogenesis.