A mammalian origin of bidirectional DNA replication within the Chinese hamster RPS14 locus

Codon optimization enhances protein expression of Bombyx mori nucleopolyhedrovirus DNA polymerase in E. coli

Bombyx mori nucleopolyhedrovirus (BmNPV) is a major viral agent that causes deadly grasserie disease in silkworms, while BmNPV DNA polymerase (BmNPV-pol), encoded by ORF53 gene, plays a central role in viral DNA replication. Efficacy studies of BmNPV-POL are limited because of poor heterologous protein expression in E. coli. Here, we redesigned the BmNPV-pol to preferentially match codon frequencies of E. coli without altering the amino acid sequence. Following de novo synthesis, codon-optimized BmNPV-pol (co-BmNPV-pol) gene was cloned into pET32a and pGEX-4T-2 vector. The expression of co-BmNPV-POL in E. coli was significantly increased when BmNPV-POL was fused with GST protein rather than a His-tag. The co-BmNPV-POL fusion proteins were isolated using GST affinity chromatography and Mono Q iron exchange chromatography. Protein purity and identity were confirmed by western blot and MALDI-TOF analyses. The biological activity of purified proteins was measured on a poly(dA)/oligo(dT) primer/template. The specific polymerasing activity of the recombinant BmNPV-POL was 6,329 units/mg at optimal conditions. Thus, a large amount of purified protein as a soluble form with high activity would provide many benefits for the functional research and application of BmNPV-POL.

Human non-CG methylation: are human stem cells plant-like?

Non-CG methylation is well characterized in plants, where it appears to play a role in gene silencing and genomic imprinting. Although strong evidence for the presence of non-CG methylation in animals has been available for some time, both its origin and function remain elusive. In this review we discuss available evidence on non-CG methylation in animals in light of evidence suggesting that the human stem cell methylome contains significant levels of methylation outside the CG site.

Identification of a cis-element that determines autonomous DNA replication in eukaryotic cells

A 36-bp human consensus sequence (CCTMDAWKSGBYTSMAAWTWBCMYTTRSCAAATTCC) is capable of supporting autonomous replication of a plasmid after transfection into eukaryotic cells. After transfection and in vitro DNA replication, replicated plasmid DNA containing a mixture of oligonucleotides of this consensus was found to reiterate the consensus. Initiation of DNA replication in vitro occurs within the consensus. One version, A3/4, in pYACneo, could be maintained under selection in HeLa cells, unrearranged and replicating continuously for >170 cell doublings. Stability of plasmid without selection was high (> or =0.9/cell/generation). Homologs of the consensus are found consistently at mammalian chromosomal sites of initiation and within CpG islands. Versions of the consensus function as origins of DNA replication in normal and malignant human cells, immortalized monkey and mouse cells, and normal cow, chicken, and fruit fly cells. Random mutagenesis studies suggest an internal 20-bp consensus sequence of the 36 bp may be sufficient to act as a core origin element. This cis-element consensus sequence is an opportunity for focused analyses of core origin elements and the regulation of initiation of DNA replication.

Latency-associated nuclear antigen (LANA) cooperatively binds to two sites within the terminal repeat, and both sites contribute to the ability of LANA to suppress transcription and to facilitate DNA replication

The latency-associated nuclear antigen (LANA) of Kaposi's sarcoma-associated herpesvirus is a multifunctional protein with important roles in both transcriptional regulation and episomal maintenance. LANA is also a DNA-binding protein and has been shown to specifically bind to a region within the terminal repeat. Here, we have performed a detailed analysis of the DNA-binding activity of LANA and show that it binds two sites separated by 22 bp. We used electrophoretic mobility shift assay to quantitatively analyze the binding sites and determined that the K(d) of the high affinity site is 1.51 +/- 0.16 nm. Examination of the contribution of nucleotides near the ends of the site showed that the core binding site consists of 16 bp, 13 of which are conserved between both sites. Analysis of the affinity of each site alone and in tandem revealed that the binding to the second site is primarily due to cooperativity with the first site. Using deletion and point mutations, we show that both sites contribute to the ability of LANA to suppress transcription and to facilitate DNA replication. In addition, we show that the ability of LANA to carry out these functions is directly proportional to its affinity for the sites in this region. The affinities, spacing, and cooperative binding between the two sites is similar to that of the Epstein-Barr virus dyad symmetry element oriP, suggesting a requirement for such an element in latent replication of these related DNA tumor viruses.

Replication of the rat aldolase B locus differs between aldolase B-expressing and non-expressing cells

We previously reported a rat chromosomal origin of DNA replication (oriA1) that encompassed the aldolase B (AldB) gene promoter. Here, we examined utilization of oriA1 in AldB-expressing and non-expressing cells. The results suggested the occurrence of mutually exclusive regulation between DNA replication and transcription. Nascent strand abundance as assayed by competitive polymerase chain reaction using bromodeoxyuridine-labeled nascent DNA indicated that oriA1 is not utilized in AldB-expressing cells, while it is fired in non-expressing cells. In the latter non-expressing cells, the replication fork seemed to slow at 20-22 kb downstream of oriA1.

Construction of a cosmid library of DNA replicated early in the S phase of normal human fibroblasts

We constructed a subgenomic cosmid library of DNA replicated early in the S phase of normal human diploid fibroblasts. Cells were synchronized by release from confluence arrest and incubation in the presence of aphidicolin. Bromodeoxyuridine (BrdUrd) was added to aphidicolin-containing medium to label DNA replicated as cells entered S phase. Nuclear DNA was partially digested with Sau 3AI, and hybrid density DNA was separated in CsCl gradients. The purified early-replicating DNA was cloned into sCos1 cosmid vector. Clones were transferred individually into the wells of 96 microtiter plates (9,216 potential clones). Vigorous bacterial growth was detected in 8,742 of those wells. High-density colony hybridization filters (1, 536 clones/filter) were prepared from a set of replicas of the original plates. Bacteria remaining in the wells of replica plates were combined, mixed with freezing medium, and stored at -80 degrees C. These pooled stocks were analyzed by polymerase chain reaction to determine the presence of specific sequences in the library. Hybridization of high-density filters was used to identify the clones of interest, which were retrieved from the frozen cultures in the 96-well plates. In testing the library for the presence of 14 known early-replicating genes, we found sequences at or near 5 of them: APRT, beta-actin, beta-tubulin, c-myc, and HPRT. This library is a valuable resource for the isolation and analysis of certain DNA sequences replicated at the beginning of S phase, including potential origins of bidirectional replication.

Multiple initiations in the c-myc replication origin independent of chromosomal location

At supramolecular resolution, DNA synthesis begins at preferred replication origins in the chromosomes of metazoan cells. To characterize one of these origins in detail, the initiation of replication was examined in the HeLa c-myc origin. Polymerase chain reaction (PCR) amplification of size-fractionated nascent chromosomal DNAs revealed multiple replication initiation sites over a 12-kb region spanning the c-myc origin, including the transcribed region and the 5' and 3' flanking DNA of the gene. Two of the start sites for chromosomal replication occurred inside a 2.4-kb region of the origin that exhibits autonomously replicating sequence (ARS) activity. When a plasmid containing the 2.4-kb ARS region was transfected into HeLa cells, PCR mapping of nascent plasmid DNA confirmed that the plasmid replicated semiconservatively and autonomously and that replication did not initiate at random sites but rather began at multiple sites in a limited zone overlapping the c-myc DNA insert. Within the resolution of the PCR assay, the same sites that were used in the chromosomal c-myc origin were used in the 2.4-kb ARS fragment. The locations of replication start sites determined by PCR are considered in the context of other functional and structural elements of the c-myc origin.

Evolution of somatic hypermutation and gene conversion in adaptive immunity

Examples of somatic hypermutation of antigen receptor genes can be seen in most lineages of vertebrates, including the cartilaginous fish. Analysis of the phylogenetic data reveals that two distinctive features of the mechanism are shared by most species studied: the mutation hot spot sequence AGY, and a preponderance of point mutations. These data suggest that some of the components of the machinery are shared between ectotherms and mammals. However, unique characters in particular species may have occurred by independent recruitment of novel factors onto the mechanism. A spotty phylogenetic distribution of gene conversion has also been revealed and can be explained if the two mechanisms share some characteristics. Both mutation and conversion require transcription-related sequences and/or factors. We theorized that targeting to V genes can be attained by a paused replication fork that has collided with a transcription complex stalled by a defective Ig transcription activator; the paused replication fork results in recruitment of an error-prone translesion synthesis DNA polymerase (somatic hypermutation) or of DNA repair mechanisms with homologous recombination (gene conversion). In addition, the pathway recruited in different species may be directed by the degree of homology among V genes.

The search for origins of DNA replication

The past decade has witnessed an explosion of new information about the nature of DNA replication in eukaryotic cells. Much of this information has resulted from the advent of novel methods for identifying and characterizing origins of DNA replication in the genomes of viruses, plasmids, and cells. These methods can map with remarkable precision sites where replication begins. In addition, they provide assays for origin activity that can be used to identify the sequence of events leading to the formation and activation of prereplication complexes at specific sites in chromosomal DNA. I summarize briefly the current view of eukaryotic replication origins and the methods that have been used to identify and characterize them. Selected methods that show promise for future applications are then described in detail in subsequent articles.

Replication initiation point mapping

Replication in eukaryotes is bidirectional and semi-discontinuous. This asymmetry provides the basis for mapping the origin of bidirectional replication (OBR), which is the transition point from discontinuous to continuous synthesis. The regions of each DNA strand complementary to the leading strand or lagging strand can be measured by the methods of imbalanced DNA synthesis or Okazaki fragment distribution, respectively. The resolution of both of these hybridization-based procedures is a few hundred base pairs. Nucleotide resolution was previously achieved for viral origins by mapping the initiation sites of Okazaki fragments on sequencing gels. To overcome the background caused by nicked DNA, all DNA ends were phosphorylated, RNA primers were removed from the Okazaki fragments by NaOH hydrolysis, and the hydroxyl ends thus created were phosphorylated with 32P. Unfortunately, this method was not sensitive enough to map eukaryotic cellular origins. A new method, replication initiation point (RIP) mapping, that is 1000-fold more sensitive and has been applied to yeast ARS1 where the OBR is mapped to and 18-bp region from within element B1 toward B2 is described here. RIP mapping utilizes Vent (exo-) polymerase to extend from a labeled primer to the DNA/RNA junctions of nascent strand template in an asynchronous population of replicating molecules. The DNA is digested with lambda-exonuclease prior to primer extension to remove nicked contaminating DNA.

Mapping replication fork direction by leading strand analysis

Replication fork polarity methods measure the direction of DNA synthesis by taking advantage of the asymmetric nature of DNA replication. One procedure that has been used on a variety of cell lines from different metazoans relies on the isolation of newly replicated DNA strands in the presence of the protein synthesis inhibitor emetine. Since Okazaki fragments are not synthesized under such conditions, DNA strands produced during continuous exposure to emetine consist mainly of leading strands. In the protocol described, leading strands isolated from emetine treated cells are detected with single-stranded probes representing each strand of the DNA duplex in the region of interest. Hybridization of leading strands to one strand of a cloned genomic template identifies the direction of replication fork movement. If initiation of DNA synthesis occurs from a preferred site, leading strands should diverge from the corresponding initiation region. The leading strand method is particularly useful for mapping initiation in chromosomal loci that do not replicate immediately on entry into S phase and in mapping the replication fork patterns in which candidate initiation regions have not been identified. Cautious interpretation of the results is needed because the method relies heavily on quantitative hybridization. Leading strand data can be difficult to interpret when the genomic targets are very close to initiation regions and when the targets vary in their hybridization efficiency or in the efficiency of incorporation of nucleotide analogs. The experimental details of the method are reviewed, controls to avoid common pitfalls are suggested, protocols to facilitate the accurate interpretation of the results are provided.

Mapping replication origins by nascent DNA strand length

The mapping of replication origins by nascent DNA strand length determination is a very sensitive generally applicable method that identifies even single-copy origins in mammalian chromosomes. A major advantage of this procedure is that there is no need for synchronization of cells or treatment with metabolic agents, which allows the origin to be studied under physiological conditions. This technique is based upon the amplification of specific sequence markers on nascent DNA strands that initiated replication within the region of the putative origin. Therefore, this method requires detailed sequence information of the locus to be analyzed. As a first step, nascent DNA of proliferating cells is pulse-labeled with BrdU followed by size fractionation and purification with anti-BrdU antibodies. The position of putative origins can then be determined via identification of the shortest nascent strands that can be amplified by PCR and hybridized to probes homologous to the amplified segments. Here, we give a detailed description of the theory behind the method and a full recipe for its application. Advantages and limitations of the procedure are discussed.

Sequence requirement for replication initiation at the rat aldolase B locus implicated in its functional correlation with transcriptional regulation

Transcription promoter of the aldolase B gene was previously shown to be centered on an initiation region of DNA replication in rat hepatoma cells in vivo. Here, we defined an essential region required for replication in a plasmid form upon transfection. Deletion analyses around the origin region revealed that the proximal 200 bp promoter was necessary, but not sufficient for replication as flanking sequence restored replication activity. Therefore, the 200 bp region seemed to cooperate with the flanking sequence to play an important role in replication. Electrophoretic mobility shift assays using nuclear extracts from synchronously growing hepatoma cells showed that some protein factors bound to this region in a cell cycle-regulated manner. Since transcription of the aldolase B gene is repressed in the hepatoma cells, the cell cycle-regulated protein-binding is considered to be involved in regulation of replication initiation.

Absence of an unusual "densely methylated island" at the hamster dhfr ori-beta

An unusual "densely methylated island" (DMI), in which all cytosine residues are methylated on both strands for 127-516 base pairs, has been reported at mammalian origins of DNA replication. This report had far-reaching implications in understanding of DNA methylation and DNA replication. For example, since this DMI appeared in about 90% of proliferating cells, but not in stationary cells, it may regulate origin activation. In an effort to confirm and extend these observations, the DMI at the well characterized ori-beta locus 17 kilobases downstream of the dhfr gene in chromosomes of Chinese hamster ovary cells was checked for methylated cytosines in genomic DNA. The methylation status of this region was examined in randomly proliferating and stationary cells and in cell populations enriched in the G1, S, or G2 + M phases of their cell division cycle. DNA was subjected to 1) cleavage by methylation-sensitive restriction endonucleases, 2) hydrazine modification of cytosines followed by piperidine cleavage, and 3) permanganate modification of 5-methylcytosines (mC) followed by piperidine cleavage. The permanganate reaction is a novel method for direct detection of mC residues that complements the more commonly used hydrazine method. These methods were capable of detecting mC in 2% of the cells. At the region of the proposed DMI, only one mC at a CpG site was detected. However, the ori-beta DMI was not detected in any of these cell populations using any of these methods.

Common structural features of replication origins in all life forms

Origins of replication (ORIs) among prokaryotes, viruses, and multicellular organisms appear to possess simple tri-, tetra-, or higher dispersed repetitions of nucleotides, AT tracts, inverted repeats, one to four binding sites of an initiator protein, intrinsically curved DNA, DNase I-hypersensitive sites, a distinct pattern of DNA methylation, and binding sites for transcription factors. Eukaryotic ORIs are sequestered on the nuclear matrix; this attachment is supposed to facilitate execution of their activation/deactivation programs during development. Furthermore, ORIs fall into various classes with respect to their sequence complexity: those enriched in AT tracts, those with GA- and CT-rich tracts, a smaller class of GC-rich ORIs, and a major class composed of mixed motifs yet containing distinct AT and polypurine or GC stretches. Multimers of an initiator protein in prokaryotes and viruses that might have evolved into a multiprotein replication initiation complex in multicellular organisms bind to the core ORI, causing a structural distortion to the DNA which is transferred to the AT tract flanking the initiator protein site; single-stranded DNA-binding proteins then interact with the melted AT tract as well as with the DNA polymerase alpha-primase complex in animal viruses and mammalian cells, causing initiation in DNA replication. ORIs in mammalian cells seem to colocalize with matrix-attached regions and are proposed to become DNase I-hypersensitive during their activation.

Identification of a herpesvirus Saimiri cis-acting DNA fragment that permits stable replication of episomes in transformed T cells

Herpesvirus saimiri is a lymphotropic herpesvirus capable of immortalizing and transforming T cells both in vitro and in vivo. Immortalized and transformed T cells harbor several copies of the viral genome as a persisting genome. The mapping of the cis-acting genetic cis-acting segment (oriP) required for viral episomal maintenance is reported here. Viral DNA fragments that potentially contain oriP were cloned into a plasmid that contains the hygromycin resistance gene. After several round of subcloning followed by transfection, oriP was mapped to a 1.955-kb viral segment. This viral fragment permits stable plasmid replication without deletion or rearrangement as well as episomal maintenance without integration or recombination. The function of oriP depends on a trans-acting factor(s) encoded by the viral genome. The 1.955-kb viral segment includes a dyad symmetry region located between two small nuclear RNA genes and is located upstream of the dihydrofolate reductase gene homolog. Therefore, this oriP contains novel elements distinct from those of other DNA viruses.

Mapping the sites of initiation of DNA replication in rat and human rRNA genes

To study the organization of DNA replication in mammalian rRNA genes, the sites of initiation of DNA synthesis in rat and human rRNA genes were mapped by two independent techniques. In rat cells the growth of the nascent DNA chains was blocked by Trioxsalen cross-links introduced in vivo. The fraction of "restricted" nascent DNA chains labeled in vivo was isolated, and the abundance in this fraction of cloned ribosomal DNA sequences was determined by hybridization. In the experiments with human cells, the nascent DNA chains were allowed to grow unrestricted for a certain period of time and the movement of the replication forks along the rRNA genes was followed by hybridization of cloned ribosomal DNA sequences to the "unrestricted" nascent DNA fragments fractionated according to size. The results show that in both rRNA genes there are two well defined regions of initiation of DNA synthesis. The first one is located upstream of the transcription units and the second one is located at the 3'-end of the coding regions of the ribosomal DNA repeats.

Origins of replication and the nuclear matrix: the DHFR domain as a paradigm

The eukaryotic genome appears to be organized in a loopwise fashion by periodic attachment to the nuclear matrix. The proposal that a chromatin loop corresponds to a functional domain has stirred interest in the properties of the DNA sequences at the bases of these loops, the matrix-attached regions (MARs). Evidence has been presented suggesting that certain MARs act as boundary elements isolating domains from their chromosomal context. MARs have also been found in the vicinity of promoters and enhancers and they could act by displacing these cis-regulatory elements into the proper nuclear subcompartment. Attachment to the matrix might also play a role in DNA replication. A large body of evidence indicates that replication occurs on the nuclear matrix. This implies that any DNA sequence will be attached to the matrix at a certain time during the cell cycle. This transient mode of attachment contrasts with the proposed permanent attachment of origins of DNA replication with the nuclear matrix. While some data exist that support this suggestion, the current lack of understanding of the mammalian replication origin precludes definitive conclusions regarding the role of MARs in the initiation process.

A densely methylated DNA island is associated with a chromosomal replication origin in the human RPS14 locus

We describe a 258-bp densely methylated DNA island (DMI) and chromosomal origin of bidirectional DNA replication within the transcribed portion of the human RPS14 intron 1. Together with the DMIs previously detected in two functional Chinese hamster replication origins [see Ref. 1, pp. 5636-5644], observations described in this report strengthen the correlation between densely methylated DNA islands and active mammalian chromosomal replication origins. Accordingly, DMIs may prove to be reliable physical markers for origins of bidirectional DNA replication in complex genomic DNAs of higher animals.

Regulation of human RPS14 transcription by intronic antisense RNAs and ribosomal protein S14

RNase protection studies reveal two stable RNAs (250 and 280 nucleotides) transcribed from the antisense strand of the human ribosomal protein gene RPS14's first intron. These transcripts, designated alpha-250 and alpha-280, map to overlapping segments of the intron's 5' sequence. Neither RNA encodes a polypeptide sequence, and both are expressed in all human cells and tissues examined. Although alpha-280 is detected among both the cells' nuclear and cytoplasmic RNAs, the great majority of alpha-250 is found in the cytoplasmic subcellular compartment. As judged by its resistance to high concentrations of alpha-amanitin, cell-free transcription of alpha-250 and alpha-280 appears to involve RNA polymerase I. Tissue culture transfection and cell-free transcription experiments demonstrate that alpha-250 and alpha-280 stimulate S14 mRNA transcription, whereas free ribosomal protein S14 inhibits it. Electrophoretic mobility shift experiments indicate specific binary molecular interactions between r-protein S14, its message and the antisense RNAs. In light of these data, we propose a model for fine regulation of human RPS14 transcription that involves RPS14 intron 1 antisense RNAs as positive effectors and S14 protein as a negative effector.