Review: nuclear structure and DNA replication

Regulation of loop extrusion on the interphase genome

In the human cell nucleus, dynamically organized chromatin is the substrate for gene regulation, DNA replication, and repair. A central mechanism of DNA loop formation is an ATPase motor cohesin-mediated loop extrusion. The cohesin complexes load and unload onto the chromosome under the control of other regulators that physically interact and affect motor activity. Regulation of the dynamic loading cycle of cohesin influences not only the chromatin structure but also genome-associated human disorders and aging. This review focuses on the recently spotlighted genome organizing factors and the mechanism by which their dynamic interactions shape the genome architecture in interphase.

The Influence of Single, Tandem, and Clustered DNA Damage on the Electronic Properties of the Double Helix: A Theoretical Study

Oxidatively generated damage to DNA frequently appears in the human genome as the effect of aerobic metabolism or as the result of exposure to exogenous oxidizing agents, such as ionization radiation. In this paper, the electronic properties of single, tandem, and clustered DNA damage in comparison with native ds-DNA are discussed as a comparative analysis for the first time. A single lesion—8-oxo-7,8-dihydro-2′-deoxyguanosine (G^oxo), a tandem lesion—(5′S) and (5′R) 5′,8-cyclo-2′-deoxyadenosine (cdA), and the presence of both of them in one helix turn as clustered DNA damage were chosen and taken into consideration. The lowest vertical and adiabatic potential (VIP ~ 5.9 and AIP ~ 5.5 eV, respectively) were found for G^oxo, independently of the discussed DNA lesion type and their distribution within the double helix. Moreover, the VIP and AIP were assigned for ds-trimers, ds- dimers and single base pairs isolated from parental ds-hexamers in their neutral and cationic forms. The above results were confirmed by the charge and spin density population, which revealed that G^oxo can be considered as a cation radical point of destination independently of the DNA damage type (single, tandem, or clustered). Additionally, the different influences of cdA on the charge transfer rate were found and discussed in the context of tandem and clustered lesions. Because oligonucleotide lesions are effectively produced as a result of ionization factors, the presented data in this article might be valuable in developing a new scheme of anticancer radiotherapy efficiency.

Superresolution imaging of chromatin fibers to visualize epigenetic information on replicative DNA

During DNA replication, the genetic information of a cell is copied. Subsequently, identical genetic information is segregated reliably to the two daughter cells through cell division. Meanwhile, DNA replication is intrinsically linked to the process of chromatin duplication, which is required for regulating gene expression and establishing cell identities. Understanding how chromatin is established, maintained or changed during DNA replication represents a fundamental question in biology. Recently, we developed a method to directly visualize chromatin components at individual replication forks undergoing DNA replication. This method builds upon the existing chromatin fiber technique and combines it with cell type-specific chromatin labeling and superresolution microscopy. In this method, a short pulse of nucleoside analog labels replicative regions in the cells of interest. Chromatin fibers are subsequently isolated and attached to a glass slide, after which a laminar flow of lysis buffer extends the lysed chromatin fibers parallel with the direction of the flow. Fibers are then immunostained for different chromatin-associated proteins and mounted for visualization using superresolution microscopy. Replication foci, or 'bubbles,' are identified by the presence of the incorporated nucleoside analog. For researchers experienced in molecular biology and superresolution microscopy, this protocol typically takes 2-3 d from sample preparation to data acquisition, with an additional day for data processing and quantification.

Asymmetric Histone Inheritance in Asymmetrically Dividing Stem Cells

Epigenetic mechanisms play essential roles in determining distinct cell fates during the development of multicellular organisms. Histone proteins represent crucial epigenetic components that help specify cell identities. Previous work has demonstrated that during the asymmetric cell division of Drosophila male germline stem cells (GSCs), histones H3 and H4 are asymmetrically inherited, such that pre-existing (old) histones are segregated towards the self-renewing GSC whereas newly synthesized (new) histones are enriched towards the differentiating daughter cell. In order to further understand the molecular mechanisms underlying this striking phenomenon, two key questions must be answered: when and how old and new histones are differentially incorporated by sister chromatids, and how epigenetically distinct sister chromatids are specifically recognized and segregated. Here, we discuss recent advances in our understanding of the molecular mechanisms and cellular bases underlying these fundamental and important biological processes responsible for generating two distinct cells through one cell division.

The role of the ubiquitin proteasome system in lymphoma

The ubiquitin-proteasome system (UPS) maintains the integrity of cellular processes by controlling protein degradation pathways. The role of the UPS in proliferation, cell cycle, differentiation, DNA repair, protein folding, and apoptosis is well documented, and a wide range of protein activities in these signaling pathways can be manipulated by UPS inhibitors, which include many anti-cancer agents. Naturally occurring and synthetic drugs designed to target the UPS are currently used for hematological cancers, including lymphoma. These drugs largely interfere with the E1 and E2 regions of the 26S proteasome, blocking proteasomal activity and promoting apoptosis by enhancing activities of the extrinsic (death receptors, Trail, Fas) and intrinsic (caspases, Bax, Bcl2, p53, nuclear factor-kappa B, p27) cell death programs. This review focuses on recent clinical developments concerning UPS inhibitors, signaling pathways that are affected by down-regulation of UPS activities, and apoptotic mechanisms promoted by drugs in this class that are used to treat lymphoma.

The Xenopus cell cycle: an overview

Oocytes, eggs and embryos from the frog Xenopus laevis have been an important model system for studying cell-cycle regulation for several decades. First, progression through meiosis in the oocyte has been extensively investigated. Oocyte maturation has been shown to involve complex networks of signal transduction pathways, culminating in the cyclic activation and inactivation of Maturation Promoting Factor (MPF), composed of cyclin B and cdc2. After fertilisation, the early embryo undergoes rapid simplified cell cycles which have been recapitulated in cell-free extracts of Xenopus eggs. Experimental manipulation of these extracts has given a wealth of biochemical information about the cell cycle, particularly concerning DNA replication and mitosis. Finally, cells of older embryos adopt a more somatic-type cell cycle and have been used to study the balance between cell cycle and differentiation during development.

Transcription factor Runx1 recruits the polyomavirus replication origin to replication factories

Eukaryotic DNA replication takes place in the replication factories, where replication proteins are properly assembled to form replication forks. Thus, recruitment of DNA replication origins to the replication factories must be the key step for the regulation of DNA replication. The transcription factor Runx1 associates with the nuclear matrix, the putative substructure of DNA replication factories. An earlier report from our laboratory showed that Runx1 activates polyomavirus DNA replication, and that this requires its nuclear matrix-binding activity. Here, we show that Runx1 activates polyomavirus DNA replication by stimulating the binding of the viral-encoded replication initiator/helicase, large T antigen, to its replication origin. We found that newly replicated polyomavirus DNA is associated with the nuclear matrix and that large T antigen is targeted to replication factories, suggesting that polyomavirus is replicated in replication factories on the nuclear matrix. Although Runx1 did not co-localize with large T antigen-containing foci by itself, it co-localized with large T antigen-containing replication factories during Runx1-dependent polyomavirus DNA replication. These observations together suggest that Runx1 recruits the polyomavirus replication origin to the replication factory on the nuclear matrix, and that this requires the nuclear matrix-binding activity of Runx1.

DNA bending in the replication zone of the C3 DNA puff amplicon of Rhynchosciara americana (Diptera: Sciaridae)

Intrinsic bent DNA sites were identified in the 4289 bp segment encompassing the replication zone which directs DNA amplification and transcription of the C3-22 gene of Rhynchosciara americana. Restriction fragments showed reduced electrophoretic mobility in polyacrylamide gels. The 2D modeling of the 3D DNA path and the ENDS ratio values obtained from the dinucleotide wedge model of Trifonov revealed the presence of four major bent sites, positioned at nucleotides -6753, -5433, -5133 and -4757. Sequence analysis showed that these bends are composed of 2-6 bp dA.dT tracts in phase with the DNA helical repeat. The circular permutation analysis permitted the verification that the fragments containing the bending sites promote curvature in other sequence contexts. Computer analyses of the 4289 bp sequence revealed low helical stability (DeltaG values), negative roll angles indicating a narrow minor groove and a putative matrix attachment region. The data presented in this paper add to information about the structural features involved in this amplified segment.

Proliferating cell nuclear antigen recruits cyclin-dependent kinase inhibitor Xic1 to DNA and couples its proteolysis to DNA polymerase switching

The Xenopus cyclin-dependent kinase (CDK) inhibitor, p27(Xic1) (Xic1), binds to CDK2-cyclins and proliferating cell nuclear antigen (PCNA), inhibits DNA synthesis in Xenopus extracts, and is targeted for ubiquitin-mediated proteolysis. Previous studies suggest that Xic1 ubiquitination and degradation are coupled to the initiation of DNA replication, but the precise timing and molecular mechanism of Xic1 proteolysis has not been determined. Here we demonstrate that Xic1 proteolysis is temporally restricted to late replication initiation following the requirements for DNA polymerase alpha-primase, replication factor C, and PCNA. Our studies also indicate that Xic1 degradation is absolutely dependent upon the binding of Xic1 to PCNA in both Xenopus egg and gastrulation stage extracts. Additionally, extracts depleted of PCNA do not support Xic1 proteolysis. Importantly, while the addition of recombinant wild-type PCNA alone restores Xic1 degradation, the addition of a PCNA mutant defective for trimer formation does not restore Xic1 proteolysis in PCNA-depleted extracts, suggesting Xic1 proteolysis requires both PCNA binding to Xic1 and the ability of PCNA to be loaded onto primed DNA by replication factor C. Taken together, our studies suggest that Xic1 is targeted for ubiquitination and degradation during DNA polymerase switching through its interaction with PCNA at a site of initiation.

The human stress-activated protein kin17 belongs to the multiprotein DNA replication complex and associates in vivo with mammalian replication origins

The human stress-activated protein kin17 accumulates in the nuclei of proliferating cells with predominant colocalization with sites of active DNA replication. The distribution of kin17 protein is in equilibrium between chromatin-DNA and the nuclear matrix. An increased association with nonchromatin nuclear structure is observed in S-phase cells. We demonstrated here that kin17 protein strongly associates in vivo with DNA fragments containing replication origins in both human HeLa and monkey CV-1 cells. This association was 10-fold higher than that observed with nonorigin control DNA fragments in exponentially growing cells. In addition, the association of kin17 protein to DNA fragments containing replication origins was also analyzed as a function of the cell cycle. High binding of kin17 protein was found at the G(1)/S border and throughout the S phase and was negligible in both G(0) and M phases. Specific monoclonal antibodies against kin17 protein induced a threefold inhibition of in vitro DNA replication of a plasmid containing a minimal replication origin that could be partially restored by the addition of recombinant kin17 protein. Immunoelectron microscopy confirmed the colocalization of kin17 protein with replication proteins like RPA, PCNA, and DNA polymerase alpha. A two-step chromatographic fractionation of nuclear extracts from HeLa cells revealed that kin17 protein localized in vivo in distinct protein complexes of high molecular weight. We found that kin17 protein purified within an approximately 600-kDa protein complex able to support in vitro DNA replication by means of two different biochemical methods designed to isolate replication complexes. In addition, the reduced in vitro DNA replication activity of the multiprotein replication complex after immunodepletion for kin17 protein highlighted for a direct role in DNA replication at the origins.

The Mcm467 complex of Saccharomyces cerevisiae is preferentially activated by autonomously replicating DNA sequences

We have analyzed the role of single-stranded DNA (ssDNA) in the modulation of the ATPase activity of Mcm467 helicase of the yeast Saccharomyces cerevisiae. The ATPase activity of the Mcm467 complex is modulated in a sequence-specific manner and that the ssDNA sequences derived from the origin of DNA replication of S. cerevisiae autonomously replicating sequence 1 (ARS1) are the most effective stimulators. Synthetic oligonucleotides, such as oligo(dA) and oligo(dT), also stimulated the ATPase activity of the Mcm467 complex, where oligo(dT) was more effective than oligo(dA). However, the preference of a thymidine stretch appeared unimportant, because with yeast ARS1 derived sequences, the A-rich strand was as effective in stimulating the ATPase activity, as was the T-rich strand. Both of these strands were more effective stimulators than either oligo(dA)( )()or oligo(dT). The DNA helicase activity of Mcm467 complex is also significantly stimulated by the ARS1-derived sequences. These results indicate that the ssDNA sequences containing A and B1 motifs of ARS1, activate the Mcm467 complex and stimulate its ATPase and DNA helicase activities. Our results also indicate that the yeast replication protein A stimulated the ATPase activity of the Mcm467 complex.

A role for macromolecular crowding effects in the assembly and function of compartments in the nucleus

The mechanisms which cause macromolecules to form discrete compartments within the nucleus are not understood. Here, two ubiquitous compartments, nucleoli, and PML bodies, are shown to disassemble when K562 cell nuclei expand in medium of low monovalent cation concentration; their major proteins dispersed as seen by immunofluorescence and immunoelectron microscopy, and nucleolar transcript elongation fell by approximately 85%. These compartments reassembled and nucleolar transcription recovered in the same medium after adding inert, penetrating macromolecules (8 kDa polyethylene glycol (PEG), or 10.5 kDa dextran) to 12% w/v, showing that disassembly was not caused by the low cation concentration. These responses satisfy the criteria for crowding or volume exclusion effects which occur in concentrated mixtures of macromolecules; upon expansion the macromolecular concentration within the nucleus falls, and can be restored by PEG or dextran. These observations, together with evidence of a high concentration of macromolecules in the nucleus (in the range of 100mg/ml) which must cause strong crowding forces, suggest strongly that these forces play an essential role in driving the formation, and maintaining the function of nuclear compartments. This view is consistent with their dynamic and mobile nature and can provide interpretations of several unexplained observations in nuclear biology.

Localization and dynamics of small circular DNA in live mammalian nuclei

While genomic DNA, packaged into chromatin, is known to be locally constrained but highly dynamic in the nuclei of living cells, little is known about the localization and dynamics of small circular DNA molecules that invade cells by virus infection, application of gene therapy vectors or experimental transfection. To address this point, we have created traceable model substrates by direct labeling of plasmid DNA with fluorescent peptide nucleic acids, and have investigated their fate after microinjection into living cells. Here, we report that foreign DNA rapidly undergoes interactions with intranuclear structural sites that strongly reduce its mobility and restrict the DNA to regions excluding nucleoli and nuclear bodies such as PML bodies. The labeled plasmids partially co-localize with SAF-A, a well characterized marker protein for the nuclear 'scaffold' or 'matrix', and are resistant towards extraction by detergent and, in part, elevated salt concentrations. We show that the localization and the low mobility of plasmids is independent of the plasmid sequence, and does not require the presence of either a scaffold attachment region (SAR) DNA element or a functional promoter.

Exploiting a minimal system to study the epigenetic control of DNA replication: the interplay between transcription and replication

In order to analyze epigenetic factors involved in the regulation of DNA replication in higher eukaryotic cells, minimal systems have to be established. We have recently constructed a non-viral episomal vector system which replicates episomally in mammalian cells and is stably maintained in the cell in the absence of selection. The potential functional elements contained in this construct are an expression cassette upstream of a chromosomal S/MAR sequence and the SV40 origin of replication. In this report we describe that an active transcription upstream of the S/MAR running into this sequence is required and probably sufficient for episomal replication. We propose a model for the activation of replication in this system which may be the basis for further analysis of replication control in other systems.

The contribution of cis-elements to disease-associated repeat instability: clinical and experimental evidence

Alterations in the length (instability) of gene-specific microsatellites and minisatellites are associated with at least 35 human diseases. This review will discuss the various cis-elements that contribute to repeat instability, primarily through examination of the most abundant disease-associated repetitive element, trinucleotide repeats. For the purpose of this review, we define cis-elements to include the sequence of the repeat units, the length and purity of the repeat tracts, the sequences flanking the repeat, as well as the surrounding epigenetic environment, including DNA methylation and chromatin structure. Gender-, tissue-, developmental- and locus-specific cis-elements in conjunction with trans-factors may facilitate instability through the processes of DNA replication, repair and/or recombination. Here we review the available human data that supports the involvement of cis-elements in repeat instability with limited reference to model systems. In diverse tissues at different developmental times and at specific loci, repetitive elements display variable levels of instability, suggesting vastly different mechanisms may be responsible for repeat instability amongst the disease loci and between various tissues.

Relationship among location of T-antigen-induced DNA distortion, auxiliary sequences, and DNA replication efficiency

T-antigen-induced DNA distortion was studied in a series of simian virus 40 (SV40) plasmid constructs whose relative replication efficiency ranges from 0.2 to 36. Bending was detected in the wild-type SV40 regulatory region consisting of three copies of the GC-rich 21-bp repeat but not in constructs with only one or two copies of the 21-bp repeat. In a construct with enhanced replication efficiency, bending occurred in a 69-bp cellular sequence located upstream of a single copy of the 21-bp repeat. Bending occurred both upstream of ori and in the three 21-bp repeats located downstream of ori in a construct with reduced replication efficiency. In a construct with no 21-bp repeats, DNA distortion occurred downstream of ori. The results indicate that SV40 DNA replication is enhanced when the structure of the regulatory region allows the DNA to form a bent structure upstream of the initial movement of the replication fork.

Chromatin assembly factor 1 is essential and couples chromatin assembly to DNA replication in vivo

De novo chromatin assembly maintains histone density on the daughter strands in the wake of the replication fork. The heterotrimer chromatin assembly factor 1 (CAF-1) couples DNA replication to histone deposition in vitro, but is not essential for yeast cell proliferation. Depletion of CAF-1 in human cell lines demonstrated that CAF-1 was required for efficient progression through S-phase. Cells lacking CAF-1 accumulated in early and mid S-phase and replicated DNA slowly. The checkpoint kinase Chk1, but not Chk2, was phosphorylated in response to CAF-1 depletion, consistent with a DNA replication defect. CAF-1-depleted cell extracts completely lacked DNA replication-coupled chromatin assembly activity, suggesting that CAF-1 is required for efficient S-phase progression in human cells. These results indicate that, in contrast to yeast, human CAF-1 is necessary for coupling chromatin assembly with DNA replication.

Dynamics of DNA replication in mammalian somatic cells: nucleotide pool modulates origin choice and interorigin spacing

Selection of active origins and regulation of interorigin spacing are poorly understood in mammalian cells. Using tricolor analysis of combed DNA molecules, we studied an amplified locus containing the known origin, oriGNAI3. We visualized replication firing events at this and other discrete regions and established a strict correlation between AT richness and initiation sites. We found that oriGNAI3 is the prominent origin of the domain, the firing of which correlates with silencing of neighboring sites and establishes large interorigin distances. We demonstrate that cells reversibly respond to a reduction in nucleotide availability by slowing the rate of replication fork progression; in addition, the efficiency of initiation at oriGNAI3 is lowered while other normally dormant origins in the region are activated, which results in an overall increase in the density of initiation events. Thus, nucleotide pools are involved in the specification of active origins, which in turn defines their density along chromosomes.

The 'ORC cycle': a novel pathway for regulating eukaryotic DNA replication

The function of the 'origin recognition complex' (ORC) in eukaryotic cells is to select genomic sites where pre-replication complexes (pre-RCs) can be assembled. Subsequent activation of these pre-RCs results in bi-directional DNA replication that originates at or close to the ORC DNA binding sites. Recent results have revealed that one or more of the six ORC subunits is modified during the G1 to S-phase transition in such a way that ORC activity is inhibited until mitosis is complete and a nuclear membrane is assembled. In yeast, Cdk1/Clb phosphorylates ORC. In frog eggs, pre-RC assembly destabilizes ORC/chromatin sites, and ORC is eventually hyperphosphorylated and released. In mammals, the affinity of Orc1 for chromatin is selectively reduced during S-phase and restored during early G1-phase. Unbound Orc1 is ubiquitinated during S-phase and in some cases degraded. Thus, most, perhaps all, eukaryotes exhibit some manifestation of an 'ORC cycle' that restricts the ability of ORC to initiate pre-RC assembly to the early G1-phase of the cell cycle, making the 'ORC cycle' the premier step in determining when replication begins.

Type III intermediate filament proteins interact with four-way junction DNA and facilitate its cleavage by the junction-resolving enzyme T7 endonuclease I

The isolation from proliferating mouse and human embryo fibroblasts of SDS-stable crosslinkage products of vimentin with DNA fragments containing inverted repeats capable of cruciform formation under superhelical stress and the competitive effect of a synthetic Holliday junction on the binding of cytoplasmic intermediate filament (cIF) proteins to supercoiled DNA prompted a detailed investigation of the proteins' capacity to associate with four-way junction DNA and to influence its processing by junction-resolving endonucleases. Electrophoretic mobility shift analysis of reaction products obtained from vimentin and Holliday junctions under varying ionic conditions revealed efficient complex formation of the filament protein not only with the unstacked, square-planar configuration of the junctions but also with their coaxially stacked X-conformation. Glial fibrillary acidic protein (GFAP) was less efficient and desmin virtually inactive in complex formation. Electron microscopy showed binding of vimentin tetramers or octamers almost exclusively to the branchpoint of the Holliday junctions under physiological ionic conditions. Even at several hundredfold molar excess, sequence-related single- and double-stranded DNAs were unable to chase Holliday junctions from their complexes with vimentin. Vimentin also stimulated bacteriophage T7 endonuclease I in introducing single-strand cuts diametrically across the branchpoint and thus in the resolution of the Holliday junctions. This effect is very likely due to vimentin-induced structural distortion of the branchpoint, as suggested by the results of hydroxyl radical footprinting of Holliday junctions in the absence and the presence of vimentin. Moreover, vimentin, and to a lesser extent GFAP and desmin, interacted with the cruciform structures of inverted repeats inserted into a supercoiled vector plasmid, thereby changing their configuration via branch migration and sensibilizing them to processing by T7 endonuclease I. This refers to both plasmid relaxation caused by unilateral scission and, particularly, linearization via bilateral scission at primary and cIF protein-induced secondary cruciform branchpoints that were identified by T7 endonuclease I footprinting. cIF proteins share these activities with a variety of other architectural proteins interacting with and structurally modulating four-way DNA junctions. In view of the known and hypothetical functions of four-way DNA junctions and associated protein factors in DNA metabolism, cIF proteins as complementary nuclear matrix proteins may play important roles in such nuclear matrix-associated processes as DNA replication, recombination, repair, and transcription, with special emphasis on both the preservation and evolution of the genome.

Chromosome-based vectors for gene therapy

Currently used vectors in human gene therapy suffer from a number of limitations with respect to safety and reproducibility. There is increasing agreement that the ideal vector for gene therapy should be completely based on chromosomal elements and behave as an independent functional unit after integration into the genome or when retained as an episome. In this review we will first discuss the chromosomal elements, such as enhancers, locus control regions, boundary elements, insulators and scaffold- or matrix-attachment regions, involved in the hierarchic regulation of mammalian gene expression and replication. These elements have been used to design vectors that behave as artificial domains when integrating into the genome. We then discuss recent progress in the use of mammalian artificial chromosomes and small circular non-viral vectors for their use as expression systems in mammalian cells.

Chromosome localization changes in the Trypanosoma cruzi nucleus

Chromosome localization in the interphase nuclei of eukaryotes depends on gene replication and transcription. Little is known about chromosome localization in protozoan parasites such as trypanosomes, which have unique mechanisms for the control of gene expression, with most genes being posttranscriptionally regulated. In the present study, we examined where the chromosomes are replicated in Trypanosoma cruzi, the agent of Chagas' disease. The replication sites, identified by the incorporation of 5-bromodeoxyuridine, are located at the nuclear periphery in proliferating epimastigote forms in the early S phase of the cell cycle. When the S phase ends and cells progress through the cell cycle, 5-bromodeoxyuridine labeling is observed in the nuclear interior, suggesting that chromosomes move. We next monitored chromosome locations in different stages of the cell cycle by using a satellite DNA sequence as a probe in a fluorescence in situ hybridization assay. We found two distinct labeling patterns according to the cell cycle stage. The first one is seen in the G(1) phase, in hydroxyurea-arrested epimastigotes or in trypomastigotes, which are differentiated nondividing forms. In all of these forms the satellite DNA is found in dots randomly dispersed in the nucleus. The other pattern is found in cells from the S phase to the G(2) phase. In these cells, the satellite DNA is found preferentially at the nuclear periphery. The labeling at the nuclear periphery disappears only after mitosis. Also, DNA detected with terminal deoxynucleotidyl transferase is found distributed throughout the nuclear space in the G(1) phase but concentrated at the nuclear periphery in the S phase to the G(2) phase. These results strongly suggest that T. cruzi chromosomes move and, after entering the S phase, become constrained at the nuclear periphery, where replication occurs.

A Mammalian bromodomain protein, brd4, interacts with replication factor C and inhibits progression to S phase

Brd4 belongs to the BET family of nuclear proteins that carry two bromodomains implicated in the interaction with chromatin. Expression of Brd4 correlates with cell growth and is induced during early G(1) upon mitogenic stimuli. In the present study, we investigated the role of Brd4 in cell growth regulation. We found that ectopic expression of Brd4 in NIH 3T3 and HeLa cells inhibits cell cycle progression from G(1) to S. Coimmunoprecipitation experiments showed that endogenous and transfected Brd4 interacts with replication factor C (RFC), the conserved five-subunit complex essential for DNA replication. In vitro analysis showed that Brd4 binds directly to the largest subunit, RFC-140, thereby interacting with the entire RFC. In line with the inhibitory activity seen in vivo, recombinant Brd4 inhibited RFC-dependent DNA elongation reactions in vitro. Analysis of Brd4 deletion mutants indicated that both the interaction with RFC-140 and the inhibition of entry into S phase are dependent on the second bromodomain of Brd4. Lastly, supporting the functional importance of this interaction, it was found that cotransfection with RFC-140 reduced the growth-inhibitory effect of Brd4. Taken as a whole, the present study suggests that Brd4 regulates cell cycle progression in part by interacting with RFC.

Role and function of the 26S proteasome in proliferation and apoptosis

The 26S proteasome constitutes the central proteolytic machinery of the highly conserved ubiquitin/proteasome system, the cell's major tool for extralysosomal protein degradation. Recently, a plethora of cell proteins implicated in the regulation of basic cellular processes, such as proliferation, differentiation, cell cycling, and apoptosis have been discovered to undergo processing and functional limitation by entering the ubiquitin/proteasome pathway with the final destination to be proteolytically degraded by the 26S proteasome. Because both negative and positive regulators of proliferation and apoptosis undergo proteasomal degradation in a tightly regulated and temporally controlled fashion, the 26S proteasome can play opposite roles in the regulation of proliferation and apoptosis. These roles are apparently defined by the cell's environment and proliferative state. Finally, proteasomal protein degradation is deregulated in a number of human diseases, including cancer and neurodegenerative and myodegenerative diseases, which all exhibit an imbalance of proliferation and apoptosis. An improved understanding of the modes of proteasomal action should lead to the development of beneficial therapeutic and diagnostic strategies in the future.

Targeting critical regions in genomic DNA with AT-specific anticancer drugs

Cellular DNA is not a uniform target for DNA-reactive drugs. At the nucleotide level, drugs recognize and bind short motifs of a few base pairs. The location of drug adducts at the genomic level depends on how these short motifs are distributed in larger domains. This aspect, referred to as region specificity, may be critical for the biological outcome of drug action. Recent studies demonstrated that certain minor groove binding (MGB) drugs, such as bizelesin, produce region-specific lesions in cellular DNA. Bizelesin binds mainly T(A/T)(4)A sites, which are on average scarce, but occasionally cluster in distinct minisatellite regions (200-1000 bp of approximately 85-100% AT), herein referred to as AT islands. Bizelesin-targeted AT islands are likely to function as strong matrix attachment regions (MARs), domains that organize DNA loops on the nuclear matrix. Distortion of MAR-like AT islands may be a basis for the observed inhibition of new replicon initiation and the extreme lethality of bizelesin adducts (<10 adducts/cell for cell growth inhibition). Hence, long AT-islands represent a novel class of critical targets for anticancer drugs. The AT island paradigm illustrates the potential of the concept of regional targeting as an essential component of the rational design of new sequence-specific DNA-reactive drugs.

Replication and subnuclear location dynamics of the immunoglobulin heavy-chain locus in B-lineage cells

The murine immunoglobulin heavy-chain (Igh) locus provides an important model for understanding the replication of tissue-specific gene loci in mammalian cells. We have observed two DNA replication programs with dramatically different temporal replication patterns for the Igh locus in B-lineage cells. In pro- and pre-B-cell lines and in ex vivo-expanded pro-B cells, the entire locus is replicated early in S phase. In three cell lines that exhibit the early-replication pattern, we found that replication forks progress in both directions through the constant-region genes, which is consistent with the activation of multiple initiation sites. In contrast, in plasma cell lines, replication of the Igh locus occurs through a triphasic pattern similar to that previously detected in MEL cells. Sequences downstream of the Igh-C alpha gene replicate early in S, while heavy-chain variable (Vh) gene sequences replicate late in S. An approximately 500-kb transition region connecting sequences that replicate early and late is replicated progressively later in S. The formation of the transition region in different cell lines is independent of the sequences encompassed. In B-cell lines that exhibit a triphasic-replication pattern, replication forks progress in one direction through the examined constant-region genes. Timing data and the direction of replication fork movement indicate that replication of the transition region occurs by a single replication fork, as previously described for MEL cells. Associated with the contrasting replication programs are differences in the subnuclear locations of Igh loci. When the entire locus is replicated early in S, the Igh locus is located away from the nuclear periphery, but when Vh gene sequences replicate late and there is a temporal-transition region, the entire Igh locus is located near the nuclear periphery.

Cell cycle specific plasmid DNA replication in the nuclear extract of Saccharomyces cerevisiae: modulation by replication protein A and proliferating cell nuclear antigen

Plasmid DNA replication in nuclear extracts of Saccharomyces cerevisiae in vitro has been shown to be S-phase specific, similar to that observed in vivo. We report here a reconstituted in vitro system with partially purified replication proteins, purified replication protein A (RPA), and recombinant proliferating cell nuclear antigen (PCNA). Nuclear extracts from S-phase, G(1)-phase, and unsynchronized yeast cells were fractionated by phosphocellulose chromatography. Protein fraction (polymerase fraction) enriched with replication proteins, including DNA polymerases (alpha, delta, etc.), was isolated, which was not capable of in vitro replication of supercoiled plasmid DNA. However, when purified yeast RPA and recombinant PCNA together were added to the polymerase fraction obtained from S-phase synchronized cells, in vitro plasmid DNA replication was restored. In vitro plasmid DNA replication with polymerase fractions from unsynchronized and G(1)-phase cells could not be reconstituted upon addition of purified RPA and PCNA. RPA and PCNA isolated from various phases of the cell cycle complemented the S-phase polymerase pool to the same extent. Reconstituted systems with the S-phase polymerase pool, complemented with either the RPA- and PCNA-containing fraction or purified RPA and recombinant PCNA together, were able to produce replication intermediates (ranging in size from 50 to 1500 bp) similar to that observed with the S-phase nuclear extract. Results presented here demonstrate that both RPA and PCNA are cell cycle-independent in their ability to stimulate in vitro plasmid DNA replication, whereas replication factors in the polymerase fractions are strictly S-phase dependent.

The genome factor in region-specific DNA damage: the DNA-reactive drug U-78779 prefers mixed A/T-G/C sequences at the nucleotide level but is region-specific for long pure AT islands at the genomic level

Bizelesin is the first anticancer drug capable of damaging specific regions of the genome with clusters of its binding sites T(A/T)(4)A. This study characterized the sequence- and region-specificity of a bizelesin analogue, U-78779, designed to interact with mixed A/T-G/C motifs. At the nucleotide level, U-78779 was found to prefer runs of A/Ts interspersed with 1 or 2 G/C pairs, although 25% of the identified sites corresponded to pure AT motifs similar to bizelesin sites. The in silico computational analysis showed that the preferred mixed A/T-G/C motifs distribute uniformly at the genomic level. In contrast, the secondary, pure AT motifs (A/T)(6)A were found densely clustered in the same long islands of AT-rich DNA that bizelesin targets. Mapping the sites and quantitating the frequencies of U-78779 adducts in model AT island and non-AT island naked DNAs demonstrated that clusters of pure AT motifs outcompete isolated mixed A/T-G/C sites in attracting drug binding. Regional preference of U-78779 for AT island domains was verified also in DNA from drug-treated cells. Thus, while the primary sequence preference gives rise to non-region-specific scattered lesions, the clustering of the minor pure AT binding motifs seems to determine region-specificity of U-78779 in the human genome. The closely correlated cytotoxic activities of U-78779 and bizelesin in several cell lines further imply that both drugs may share common cellular targets. This study underscores the significance of the genome factor in a drug's potential for region-specific DNA damage, by showing that it can take precedence over drug binding preferences at the nucleotide level.

Roads to polyploidy: the megakaryocyte example

Polyploidy, recognized by multiple copies of the haploid chromosome number, has been described in plants, insects, and in mammalian cells such as, the platelet precursors, the megakaryocytes. Several of these cell types reach high ploidy via a different cell cycle. Megakaryocytes undergo an endomitotic cell cycle, which consists of an S phase interrupted by a gap, during which the cells enter mitosis but skip anaphase B and cytokinesis. Here, we review the mechanisms that lead to this cell cycle and to polyploidy in megakaryocytes, while also comparing them to those described for other systems in which high ploidy is achieved. Overall, polyploidy is associated with an orchestrated change in expression of several genes, of which, some may be a result of high ploidy and hence a determinant of a new cell physiology, while others are inducers of polyploidization. Future studies will aim to further explore these two groups of genes.

Dual control of replication timing. Stochastic onset but programmed completion of mammalian chromosome duplication

In mammalian cells, DNA replication proceeds according to a precise temporal order during the S phase, but how this program is controlled remains poorly understood. We analyzed the replication-dependent bromodeoxyuridine banding of chromosomes in Chinese hamster cells treated with the spindle poison nocodazole. In these cells, nocodazole induces a transient mitotic arrest, followed by DNA re-replication without intervening cell division. Nuclear fragmentation is often observed in tetraploid derivatives, and previous studies suggest that replication timing of chromosomes could be affected when they are segregated into different micronuclei. Here we show that the onset of replication is frequently asynchronous on individual chromosomes during the re-replication process. Moreover, fluorescence in situ hybridization analysis revealed that replication synchrony is equally altered in fragmented and non-fragmented nuclei, indicating that asynchronous onset of replication is not dependent on physical separation of the chromosomes into isolated compartments. We also show that the ordered program of replication is always preserved along individual chromosomes. Our results demonstrate that the onset of replication of individual chromosomes in the same nuclear compartment can be uncoupled from the time of S-phase entry and from the programmed replication of chromosome sub-domains, revealing that multi-level controls contribute to establish replication timing in mammalian cells.

Reconstitution of enhancer function in paternal pronuclei of one-cell mouse embryos

How chromatin-mediated transcription regulates the beginning of mammalian development is currently unknown. Factors responsible for promoter repression and enhancer-mediated relief of this repression are not present in the paternal pronuclei of one-cell mouse embryos but are present in the zygotic nuclei of two-cell embryos. Here we show that coinjection of purified histones and a plasmid-encoded reporter gene into the paternal pronuclei of one-cell embryos at a specific histone-DNA concentration could recreate the behavior observed in two-cell embryos: acquisition of promoter repression and subsequent relief of this repression either by functional enhancers or by histone deacetylase inhibitors. Furthermore, the extent of enhancer-mediated stimulation in one-cell embryos depended on the acetylation status of the injected histones, on the treatment of embryos with a histone deacetylase inhibitor, and on the developmentally regulated appearance of enhancer-specific coactivator activity. The coinjected plasmids in one-cell embryos also exhibited chromatin assembly, as determined by a supercoiling assay. Thus, injection of histones into one-cell embryos faithfully reproduced the chromatin-mediated transcription observed in two-cell embryos. These results suggest that the need for enhancers to stimulate promoters through relief of chromatin-mediated repression occurs once the parental genomes are organized into chromatin. Furthermore, we present a model mammalian system in which the role of individual histones, and particular domains within the histones that are targeted in enhancer function, can be examined using purified mutant histones.

DNA replication efficiency depends on transcription factor-binding sites

Naturally arising variants of simian virus 40 (SV40), generated by serial passage of the virus at high multiplicities of infection, provide important insight into the role of transcription factor-binding sites in enhancing DNA replication. Although the variants that arise from numerous recombination events are the result of selective pressure to replicate more efficiently than the other variants in the infection, there is no transcription pressure. Therefore, it is interesting that a minimum of two viral Sp1 transcription factor-binding sites are retained and that host AP-1 and NF-1 transcription factor-binding sites are incorporated into the 100-bp regulatory region that maximizes DNA replication in these variants. We cotransfected COS-1 cells (that provide viral large T antigen for DNA replication) to examine the effect of transcription factor-binding sites on the replication of plasmid constructs that contain the SV40 origin of replication (ori). The level of relative replication efficiency (RRE) depends on the number and type of transcription factor-binding sites. Replication increases as the number of transcription factor-binding sites increases within the regulatory region of the variants; AP-1 sites are more effective than NF-1 transcription factor-binding sites. Competition between constructs in transfections magnifies the difference in their RREs. The results indicate that transcription factor-binding sites play an important role in enhancing DNA replication.

Ubiquitin-mediated proteolysis of vertebrate G1- and S-phase regulators

Cell-cycle progression in all eukaryotes is driven by cyclin-dependent kinases (CDKs) and their cyclin partners. In vertebrates, the proper and timely duplication of the genome during S-phase relies on the coordinated activities of positive regulators such as CDK-cyclins and E2F, and negative regulators such as CDK inhibitors of the Cip/Kip and INK4 families. Recent and ongoing work indicates that many important regulators of G1- and S-phases are targeted for ubiquitination and subsequent degradation by the 26S proteasome. The proteolysis of key proteins during G1- and S-phases appears to be central for proper custodial regulation of DNA replication and the maintenance of cellular homeostasis in general. This review highlights the current literature regarding ubiquitin-mediated proteolysis of G1- and S-phase regulators and the control of events during the initiation and completion of DNA replication in vertebrates.

Initiation of eukaryotic DNA replication: conservative or liberal?

The mechanism for initiation of eukaryotic DNA replication is highly conserved: the proteins required to initiate replication, the sequence of events leading to initiation, and the regulation of initiation are remarkably similar throughout the eukaryotic kingdom. Nevertheless, there is a liberal attitude when it comes to selecting initiation sites. Differences appear to exist in the composition of replication origins and in the way proteins recognize these origins. In fact, some multicellular eukaryotes (the metazoans) can change the number and locations of initiation sites during animal development, revealing that selection of initiation sites depends on epigenetic as well as genetic parameters. Here we have attempted to summarize our understanding of this process, to identify the similarities and differences between single cell and multicellular eukaryotes, and to examine the extent to which origin recognition proteins and replication origins have been conserved among eukaryotes. Published 2000 Wiley-Liss, Inc.