Eukaryotic DNA replication origins: reconciling disparate data

Various short autonomously replicating sequences from the yeast Kluyveromyces marxianus seemingly without canonical consensus

Eukaryotic autonomously replicating sequences (ARSs) are composed of three domains, A, B, and C. Domain A is comprised of an ARS consensus sequence (ACS), while the B domain has the DNA unwinding element and the C domain is important for DNA-protein interactions. In Saccharomyces cerevisiae and Kluyveromyces lactis ARS101, the ACS is commonly composed of 11 bp, 5ˊ-(A/T)AAA(C/T)ATAAA(A/T)-3ˊ. This core sequence is essential for S. cerevisiae and K. lactis ARS activity. In this study, we identified ARS-containing sequences from genomic libraries of the yeast Kluyveromyces marxianus DMKU3-1042 and validated their replication activities. The identified K. marxianus DMKU3-1042 ARSs (KmARSs) have very effective replication ability but their sequences are divergent and share no common consensus. We have carried out point mutations, deletions, and base pairs substitutions within the sequences of some of the KmARSs to identify the sequence(s) that influence the replication activity. Consensus sequences same as the 11 bp ACS of S. cerevisiae and K. lactis were not found in all minimum functional KmARSs reported here except KmARS7. Moreover, partial sequences from different KmARSs are interchangeable among each other to retain the ARS activity. We have also specifically identified the essential nucleotides, which are indispensable for replication, within some of the KmARSs. Our deletions analysis revealed that only 21 bp in KmARS18 could retain the ARS activity. The identified KmARSs in this study are unique compared to other yeasts’ ARSs, do not share common ACS, and are interchangeable.

•

Identification of minimal autonomously replicating sequences (ARSs) from the yeast Kluyveromyces marxianus DMKU3-1042.

•

The identities of the isolated ARSs are divergent and have no common consensus with the ARSs of other yeasts.

•

A short ARS sequence of twenty-one nucleotides functions as an effective replicator in K. marxianus DMKU3-1042.

•

Segments of ARSs from the yeast K. marxianus are interchangeable among each other.

•

Functional ARSs are found in both the intergenic and coding sequences of the strain DMKU3-1042.

The Armadillo BTB Protein ABAP1 Is a Crucial Player in DNA Replication and Transcription of Nematode-Induced Galls

The biogenesis of root-knot nematode (Meloidogyne spp.)-induced galls requires the hyperactivation of the cell cycle with controlled balance of mitotic and endocycle programs to keep its homeostasis. To better understand gall functioning and to develop new control strategies for this pest, it is essential to find out how the plant host cell cycle programs are responding and integrated during the nematode-induced gall formation. This work investigated the spatial localization of a number of gene transcripts involved in the pre-replication complex during DNA replication in galls and report their akin colocation with the cell cycle S-phase regulator Armadillo BTB Arabidopsis Protein 1 (ABAP1). ABAP1 is a negative regulator of pre-replication complex controlling DNA replication of genes involved in control of cell division and proliferation; therefore, its function has been investigated during gall ontogenesis. Functional analysis was performed upon ABAP1 knockdown and overexpression in Arabidopsis thaliana. We detected ABAP1 promoter activity and localized ABAP1 protein in galls during development, and its overexpression displayed significantly reduced gall sizes containing atypical giant cells. Profuse ABAP1 expression also impaired gall induction and hindered nematode reproduction. Remarkably, ABAP1 knockdown likewise negatively affected gall and nematode development, suggesting its involvement in the feeding site homeostasis. Microscopy analysis of cleared and nuclei-stained whole galls revealed that ABAP1 accumulation resulted in aberrant giant cells displaying interconnected nuclei filled with enlarged heterochromatic regions. Also, imbalanced ABAP1 expression caused changes in expression patterns of genes involved in the cell division control as demonstrated by qRT-PCR. CDT1a, CDT1b, CDKA;1, and CYCB1;1 mRNA levels were significantly increased in galls upon ABAP1 overexpression, possibly contributing to the structural changes in galls during nematode infection. Overall, data obtained in galls reinforced the role of ABAP1 controlling DNA replication and mitosis and, consequently, cell proliferation. ABAP1 expression might likely take part of a highly ordered mechanism balancing of cell cycle control to prevent gall expansion. ABAP1 expression might prevent galls to further expand, limiting excessive mitotic activity. Our data strongly suggest that ABAP1 as a unique plant gene is an essential component for cell cycle regulation throughout gall development during nematode infection and is required for feeding site homeostasis.

Jasmonate controls leaf growth by repressing cell proliferation and the onset of endoreduplication while maintaining a potential stand-by mode

Phytohormones regulate plant growth from cell division to organ development. Jasmonates (JAs) are signaling molecules that have been implicated in stress-induced responses. However, they have also been shown to inhibit plant growth, but the mechanisms are not well understood. The effects of methyl jasmonate (MeJA) on leaf growth regulation were investigated in Arabidopsis (Arabidopsis thaliana) mutants altered in JA synthesis and perception, allene oxide synthase and coi1-16B (for coronatine insensitive1), respectively. We show that MeJA inhibits leaf growth through the JA receptor COI1 by reducing both cell number and size. Further investigations using flow cytometry analyses allowed us to evaluate ploidy levels and to monitor cell cycle progression in leaves and cotyledons of Arabidopsis and/or Nicotiana benthamiana at different stages of development. Additionally, a novel global transcription profiling analysis involving continuous treatment with MeJA was carried out to identify the molecular players whose expression is regulated during leaf development by this hormone and COI1. The results of these studies revealed that MeJA delays the switch from the mitotic cell cycle to the endoreduplication cycle, which accompanies cell expansion, in a COI1-dependent manner and inhibits the mitotic cycle itself, arresting cells in G1 phase prior to the S-phase transition. Significantly, we show that MeJA activates critical regulators of endoreduplication and affects the expression of key determinants of DNA replication. Our discoveries also suggest that MeJA may contribute to the maintenance of a cellular "stand-by mode" by keeping the expression of ribosomal genes at an elevated level. Finally, we propose a novel model for MeJA-regulated COI1-dependent leaf growth inhibition.

2D gels and their third-dimension potential

Two-dimensional (2D) agarose gel electrophoresis is one of the most powerful methods to analyze the mass and shape of replication intermediates. It is often use to map replication origins but it is also useful to characterize termination of replication, replication fork barriers and even replication fork reversal. Here, we present protocols, figures and movies with a thorough description of different modes of replication for linear DNA fragments and the corresponding patterns they generate in 2D gels.

DNA replication fading as proliferating cells advance in their commitment to terminal differentiation

Terminal differentiation is the process by which cycling cells stop proliferating to start new specific functions. It involves dramatic changes in chromatin organization as well as gene expression. In the present report we used cell flow cytometry and genome wide DNA combing to investigate DNA replication during murine erythroleukemia-induced terminal cell differentiation. The results obtained indicated that the rate of replication fork movement slows down and the inter-origin distance becomes shorter during the precommitment and commitment periods before cells stop proliferating and accumulate in G1. We propose this is a general feature caused by the progressive heterochromatinization that characterizes terminal cell differentiation.

Molecular determinants of origin discrimination by Orc1 initiators in archaea

Unlike bacteria, many eukaryotes initiate DNA replication from genomic sites that lack apparent sequence conservation. These loci are identified and bound by the origin recognition complex (ORC), and subsequently activated by a cascade of events that includes recruitment of an additional factor, Cdc6. Archaeal organisms generally possess one or more Orc1/Cdc6 homologs, belonging to the Initiator clade of ATPases associated with various cellular activities (AAA⁺) superfamily; however, these proteins recognize specific sequences within replication origins. Atomic resolution studies have shown that archaeal Orc1 proteins contact double-stranded DNA through an N-terminal AAA⁺ domain and a C-terminal winged-helix domain (WHD), but use remarkably few base-specific contacts. To investigate the biochemical effects of these associations, we mutated the DNA-interacting elements of the Orc1-1 and Orc1-3 paralogs from the archaeon Sulfolobus solfataricus, and tested their effect on origin binding and deformation. We find that the AAA⁺ domain has an unpredicted role in controlling the sequence selectivity of DNA binding, despite an absence of base-specific contacts to this region. Our results show that both the WHD and ATPase region influence origin recognition by Orc1/Cdc6, and suggest that not only DNA sequence, but also local DNA structure help define archaeal initiator binding sites.

Chk1-cyclin A/Cdk1 axis regulates origin firing programs in mammals

DNA replication is key to ensuring the complete duplication of genomic DNA prior to mitosis and is tightly regulated by both cell cycle machinery and checkpoint signals. Regulation of the S phase program occurs at several stages, affecting origin firing, replication fork elongation, fork velocity, and fork stability, all of which are dependent on S-phase-promoting kinase activity. Somatic mammalian cells use well-established origin programs by which specific regions of the genome are replicated at precise times. However, the mechanisms by which S phase kinases regulate origin firing in mammals are largely unknown. Here, we discuss recent advances in the understanding of how S phase programs are regulated in mammals at the correct regions and at the appropriate times.

Differentially active origins of DNA replication in tumor versus normal cells

Previously, a degenerate 36 bp human consensus sequence was identified as a determinant of autonomous replication in eukaryotic cells. Random mutagenesis analyses further identified an internal 20 bp of the 36 bp consensus sequence as sufficient for acting as a core origin element. Here, we have located six versions of the 20 bp consensus sequence (20mer) on human chromosome 19q13 over a region spanning approximately 211 kb and tested them for ectopic and in situ replication activity by transient episomal replication assays and nascent DNA strand abundance analyses, respectively. The six versions of the 20mer alone were capable of supporting autonomous replication of their respective plasmids, unlike random genomic sequence of the same length. Furthermore, comparative analyses of the endogenous replication activity of these 20mers at their respective chromosomal sites, in five tumor/transformed and two normal cell lines, done by in situ chromosomal DNA replication assays, involving preparation of nascent DNA by the lambda exonuclease method and quantification by real-time PCR, showed that these sites coincided with chromosomal origins of DNA replication in all cell lines. Moreover, a 2- to 3-fold higher origin activity in the tumor/transformed cells by comparison to the normal cells was observed, suggesting a higher activation of these origins in tumor/transformed cell lines.

Regulating the licensing of DNA replication origins in metazoa

Eukaryotic DNA replication is a highly conserved process; the proteins and sequence of events that replicate animal genomes are remarkably similar to those that replicate yeast genomes. Moreover, the assembly of prereplication complexes at DNA replication origins ('DNA licensing') is regulated in all eukaryotes so that no origin fires more than once in a single cell cycle. And yet there are significant differences between species both in the selection of replication origins and in the way in which these origins are licensed to operate. Moreover, these differences impart advantages to multicellular animals and plants that facilitate their development, such as better control over endoreduplication, flexibility in origin selection, and discrimination between quiescent and proliferative states.

Progressive activation of DNA replication initiation in large domains of the immunoglobulin heavy chain locus during B cell development

In mammalian cells, the replication of tissue-specific gene loci is believed to be under developmental control. Here, we provide direct evidence of the existence of developmentally regulated origins of replication in both cell lines and primary cells. By using single-molecule analysis of replicated DNA (SMARD), we identified various groups of coregulated origins that are activated within the Igh locus. These origin clusters can span hundreds of kilobases and are activated sequentially during B cell development, concomitantly with developmentally regulated changes in chromatin structure and transcriptional activity. Finally, we show that the changes in DNA replication initiation that take place during B cell development, within the D-J-C-3'RR region, occur on both alleles (expressed and nonexpressed).

Temporal profile of replication of human chromosomes

Chromosomes in human cancer cells are expected to initiate replication from predictably localized origins, firing reproducibly at discrete times in S phase. Replication products obtained from HeLa cells at different stages of S phase were hybridized to cDNA and genome tiling oligonucleotide microarrays to determine the temporal profile of replication of human chromosomes on a genome-wide scale. About 1,000 genes and chromosomal segments were identified as sites containing efficient origins that fire reproducibly. Early replication was correlated with high gene density. An acute transition of gene density from early to late replicating areas suggests that discrete chromatin states dictate early versus late replication. Surprisingly, at least 60% of the interrogated chromosomal segments replicate equally in all quarters of S phase, suggesting that large stretches of chromosomes are replicated by inefficient, variably located and asynchronous origins and forks, producing a pan-S phase pattern of replication. Thus, at least for aneuploid cancer cells, a typical discrete time of replication in S phase is not seen for large segments of the chromosomes.

Chemical footprinting of structural and functional elements of dhfr oribeta during the CHOC 400 cell cycle

Oribeta, an origin of replication 3' to Chinese hamster dihydrofolate reductase (dhfr) gene, contains several sequence elements that function as components of a chromosomal replicator. Here we have examined sensitivity to KMnO(4) in vitro and in living cells of three regions within dhfr oribeta which contribute to replicator function: the origin of bidirectional DNA replication (OBR) that serves as an initiation site for DNA synthesis, a stably bent DNA region that binds activator protein one (AP-1) and RIP60 in vitro, and an AT-rich region that contains a dA/dT(23) dinucleotide repeat that has properties of a DNA unwinding element. The in vitro patterns of KMnO(4) modification in linear plasmid differed from that in supercoiled plasmid most prominently in the dA/dT(23) repeat, with evidence of palindrome extrusion in supercoiled plasmid. Although palindrome extrusion was not detected in genomic DNA during the cell cycle, the pattern of genomic DNA modification within the dA/dT(23) repeat differed substantially from that of either linear or plasmid DNA in vitro. An AT-rich region that borders the dA/dT repeat was also highly sensitive to modification by KMnO(4) in cells. Within the bent DNA region, the patterns of chemical modification of both the AP-1 and RIP60 sites differed between plasmid and genomic DNA, and minor differences in the in vitro and cellular modification patterns also were observed for the OBR. Nonetheless, there was little evidence of cell cycle-specific modifications in any sequence examined. These studies suggest that sequences within dhfr oribeta adopt specific conformations in cells, with the most prominent changes in the AT-rich region associated with the dA/dT(23) repeat and DNA unwinding.

The ribosomal RNA gene promoter and adjacent cis-acting DNA sequences govern plasmid DNA partitioning and stable inheritance in the parasitic protozoan Leishmania

Detailed analysis of the Leishmania donovani ribosomal RNA (rRNA) gene promoter region has allowed the identification of cis-acting sequences involved in plasmid DNA partitioning and stable plasmid inheritance. We report that plasmids bearing the 350 bp rRNA promoter along with the 200 bp region immediately 3' to the promoter exhibited a 6.5-fold increase in transformation frequency and were transmitted to daughter cells as single-copy molecules. This is in contrast to what has been observed for plasmid molecules in this organism so far. Moreover, we show that these low-copy-number plasmids displayed a remarkable mitotic stability in the absence of selective pressure. The region in the vicinity of the RNA pol I transcription initiation site, and also in the adjacent 200 nt, displays a complex structural organization and shares sequence similarity to the yeast autonomously replicating consensus sequence and centromere DNA elements. Deletion analyses indicated that these elements were necessary but not sufficient for plasmid DNA partitioning and stable inheritance, and that the rRNA promoter region was required for optimal function. These results suggest an interplay between RNA pol I transcription, DNA replication, DNA partitioning and mitotic stability in trypanosomatids. This is the first example of defined DNA elements for plasmid partitioning and stable inheritance in the protozoan parasite Leishmania.

DNA topology, not DNA sequence, is a critical determinant for Drosophila ORC-DNA binding

Drosophila origin recognition complex (ORC) localizes to defined positions on chromosomes, and in follicle cells the chorion gene amplification loci are well-studied examples. However, the mechanism of specific localization is not known. We have studied the DNA binding of DmORC to investigate the cis-requirements for DmORC:DNA interaction. DmORC displays at best six-fold differences in the relative affinities to DNA from the third chorion locus and to random fragments in vitro, and chemical probing and DNase1 protection experiments did not identify a discrete binding site for DmORC on any of these fragments. The intrinsic DNA-binding specificity of DmORC is therefore insufficient to target DmORC to origins of replication in vivo. However, the topological state of the DNA significantly influences the affinity of DmORC to DNA. We found that the affinity of DmORC for negatively supercoiled DNA is about 30-fold higher than for either relaxed or linear DNA. These data provide biochemical evidence for the notion that origin specification in metazoa likely involves mechanisms other than simple replicator-initiator interactions and that in vivo other proteins must determine ORC's localization.