Identification of the critical replication targets of CDK reveals direct regulation of replication initiation factors by the embryo polarity machinery in C. elegans.

During metazoan development, the cell cycle is remodelled to coordinate proliferation with differentiation. Developmental cues cause dramatic changes in the number and timing of replication initiation events, but the mechanisms and physiological importance of such changes are poorly understood. Cyclin-dependent kinases (CDKs) are important for regulating S-phase length in many metazoa, and here we show in the nematode Caenorhabditis elegans that an essential function of CDKs during early embryogenesis is to regulate the interactions between three replication initiation factors SLD-3, SLD-2 and MUS-101 (Dpb11/TopBP1). Mutations that bypass the requirement for CDKs to generate interactions between these factors is partly sufficient for viability in the absence of Cyclin E, demonstrating that this is a critical embryonic function of this Cyclin. Both SLD-2 and SLD-3 are asymmetrically localised in the early embryo and the levels of these proteins inversely correlate with S-phase length. We also show that SLD-2 asymmetry is determined by direct interaction with the polarity protein PKC-3. This study explains an essential function of CDKs for replication initiation in a metazoan and provides the first direct molecular mechanism through which polarization of the embryo is coordinated with DNA replication initiation factors.

Sperm is epigenetically programmed to regulate gene transcription in embryos.

For a long time, it has been assumed that the only role of sperm at fertilization is to introduce the male genome into the egg. Recently, ideas have emerged that the epigenetic state of the sperm nucleus could influence transcription in the embryo. However, conflicting reports have challenged the existence of epigenetic marks on sperm genes, and there are no functional tests supporting the role of sperm epigenetic marking on embryonic gene expression. Here, we show that sperm is epigenetically programmed to regulate embryonic gene expression. By comparing the development of sperm- and spermatid-derived frog embryos, we show that the programming of sperm for successful development relates to its ability to regulate transcription of a set of developmentally important genes. During spermatid maturation into sperm, these genes lose H3K4me2/3 and retain H3K27me3 marks. Experimental removal of these epigenetic marks at fertilization de-regulates gene expression in the resulting embryos in a paternal chromatin-dependent manner. This demonstrates that epigenetic instructions delivered by the sperm at fertilization are required for correct regulation of gene expression in the future embryos. The epigenetic mechanisms of developmental programming revealed here are likely to relate to the mechanisms involved in transgenerational transmission of acquired traits. Understanding how parental experience can influence development of the progeny has broad potential for improving human health.

DNA topoisomerase IIα controls replication origin cluster licensing and firing time in Xenopus egg extracts.

Sperm chromatin incubated in Xenopus egg extracts undergoes origin licensing and nuclear assembly before DNA replication. We found that depletion of DNA topoisomerase IIα (topo IIα), the sole topo II isozyme of eggs and its inhibition by ICRF-193, which clamps topo IIα around DNA have opposite effects on these processes. ICRF-193 slowed down replication origin cluster activation and fork progression in a checkpoint-independent manner, without altering replicon size. In contrast, topo IIα depletion accelerated origin cluster activation, and topo IIα add-back negated overinitiation. Therefore, topo IIα is not required for DNA replication, but topo IIα clamps slow replication, probably by forming roadblocks. ICRF-193 had no effect on DNA synthesis when added after nuclear assembly, confirming that topo IIα activity is dispensable for replication and revealing that topo IIα clamps formed on replicating DNA do not block replication, presumably because topo IIα acts behind and not in front of forks. Topo IIα depletion increased, and topo IIα addition reduced, chromatin loading of MCM2-7 replicative helicase, whereas ICRF-193 did not affect MCM2-7 loading. Therefore, topo IIα restrains MCM2-7 loading in an ICRF-193-resistant manner during origin licensing, suggesting a model for establishing the sequential firing of origin clusters.

Dynamic de novo heterochromatin assembly and disassembly at replication forks ensures fork stability.

Chromatin is dynamically reorganized when DNA replication forks are challenged. However, the process of epigenetic reorganization and its implication for fork stability is poorly understood. Here we discover a checkpoint-regulated cascade of chromatin signalling that activates the histone methyltransferase EHMT2/G9a to catalyse heterochromatin assembly at stressed replication forks. Using biochemical and single molecule chromatin fibre approaches, we show that G9a together with SUV39h1 induces chromatin compaction by accumulating the repressive modifications, H3K9me1/me2/me3, in the vicinity of stressed replication forks. This closed conformation is also favoured by the G9a-dependent exclusion of the H3K9-demethylase JMJD1A/KDM3A, which facilitates heterochromatin disassembly upon fork restart. Untimely heterochromatin disassembly from stressed forks by KDM3A enables PRIMPOL access, triggering single-stranded DNA gap formation and sensitizing cells towards chemotherapeutic drugs. These findings may help in explaining chemotherapy resistance and poor prognosis observed in patients with cancer displaying elevated levels of G9a/H3K9me3.

SMARCAD1-mediated active replication fork stability maintains genome integrity.

The stalled fork protection pathway mediated by breast cancer 1/2 (BRCA1/2) proteins is critical for replication fork stability. However, it is unclear whether additional mechanisms are required to maintain replication fork stability. We describe a hitherto unknown mechanism, by which the SWI/SNF-related matrix-associated actin-dependent regulator of chromatin subfamily-A containing DEAD/H box-1 (SMARCAD1) stabilizes active replication forks, that is essential to maintaining resistance towards replication poisons. We find that SMARCAD1 prevents accumulation of 53BP1-associated nucleosomes to preclude toxic enrichment of 53BP1 at the forks. In the absence of SMARCAD1, 53BP1 mediates untimely dissociation of PCNA via the PCNA-unloader ATAD5, causing frequent fork stalling, inefficient fork restart, and accumulation of single-stranded DNA. Although loss of 53BP1 in SMARCAD1 mutants rescues these defects and restores genome stability, this rescued stabilization also requires BRCA1-mediated fork protection. Notably, fork protection-challenged BRCA1-deficient naïve- or chemoresistant tumors require SMARCAD1-mediated active fork stabilization to maintain unperturbed fork progression and cellular proliferation.

Epigenetic homogeneity in histone methylation underlies sperm programming for embryonic transcription.

Sperm contributes genetic and epigenetic information to the embryo to efficiently support development. However, the mechanism underlying such developmental competence remains elusive. Here, we investigated whether all sperm cells have a common epigenetic configuration that primes transcriptional program for embryonic development. Using calibrated ChIP-seq, we show that remodelling of histones during spermiogenesis results in the retention of methylated histone H3 at the same genomic location in most sperm cell. This homogeneously methylated fraction of histone H3 in the sperm genome is maintained during early embryonic replication. Such methylated histone fraction resisting post-fertilisation reprogramming marks developmental genes whose expression is perturbed upon experimental reduction of histone methylation. A similar homogeneously methylated histone H3 fraction is detected in human sperm. Altogether, we uncover a conserved mechanism of paternal epigenetic information transmission to the embryo through the homogeneous retention of methylated histone in a sperm cells population.

Terminating the replication helicase.

A feature of the cell cycle is that the events of one cycle must be reset before the next one begins. A study now shows that the replication machinery is removed from fully replicated DNA by a conserved ubiquitin- and CDC48 (also known as p97)-dependent pathway. This explains how eukaryotic chromosomes are returned to the unreplicated state.

Single-molecule, antibody-free fluorescent visualisation of replication tracts along barcoded DNA molecules.

DNA combing is a standard technique to map DNA replication at the single molecule level. Typically, replicating DNA is metabolically labelled with nucleoside or nucleotide analogs, purified, stretched on coverslips and treated with fluorescent antibodies to reveal tracts of newly synthesized DNA. Fibres containing a locus of interest can then be identified by fluorescent in situ hybridization (FISH) with DNA probes. These steps are complex and the throughput is low. Here, we describe a simpler, antibody-free method to reveal replication tracts and identify the locus of origin of combed DNA replication intermediates. DNA was replicated in Xenopus egg extracts in the presence of a fluorescent dUTP. Purified DNA was barcoded by nicking with Nt.BspQI, a site-specific nicking endonuclease (NE), followed by limited nick-translation in the presence of another fluorescent dUTP. DNA was then stained with YOYO-1, a fluorescent DNA intercalator, and combed. Direct epifluorescence revealed the DNA molecules, their replication tracts and their Nt.BspQI sites in three distinct colours. Replication intermediates could thus be aligned to a reference genome map. In addition, replicated DNA segments showed a stronger YOYO-1 fluorescence than unreplicated segments. The entire length, replication tracts, and NE sites of combed DNA molecules can be simultaneously visualized in three distinct colours by standard epifluorescence microscopy, with no need for antibody staining and/or FISH detection. Furthermore, replication bubbles can be detected by quantitative YOYO-1 staining, eliminating the need for metabolic labelling. These results provide a starting point for genome-wide, single-molecule mapping of DNA replication in any organism.

CDK phosphorylation of SLD-2 is required for replication initiation and germline development in C. elegans.

Cyclin-dependent kinase (CDK) plays a vital role in proliferation control across eukaryotes. Despite this, how CDK mediates cell cycle and developmental transitions in metazoa is poorly understood. In this paper, we identify orthologues of Sld2, a CDK target that is important for DNA replication in yeast, and characterize SLD-2 in the nematode worm Caenorhabditis elegans. We demonstrate that SLD-2 is required for replication initiation and the nuclear retention of a critical component of the replicative helicase CDC-45 in embryos. SLD-2 is a CDK target in vivo, and phosphorylation regulates the interaction with another replication factor, MUS-101. By mutation of the CDK sites in sld-2, we show that CDK phosphorylation of SLD-2 is essential in C. elegans. Finally, using a phosphomimicking sld-2 mutant, we demonstrate that timely CDK phosphorylation of SLD-2 is an important control mechanism to allow normal proliferation in the germline. These results determine an essential function of CDK in metazoa and identify a developmental role for regulated SLD-2 phosphorylation.

Expression of Nox1 in 3T3 cells increases cellular acid production but not proton conductance.

The role of the NADPH oxidase homolog 1 (Nox1) in plasma membrane H(+) conductance and cellular H(+) production was investigated in 3T3 cells stably expressing Nox1 (Nox1 3T3) compared to vector-expressing control cells (mock 3T3). In whole cell patch clamp experiments both Nox1 and mock 3T3 expressed a similar H(+) conductance (Nox1 3T3, 13.2+/-8.6 pS/pF; mock 3T3, 16.6+/-13.4 pS/pF) with a number of similar characteristics (e.g., current-voltage relations, current activation kinetics, Zn(2+)-sensitivity). When the intracellular pH of cells was alkalinized with NH(4)Cl, rates of intracellular acidification were significantly higher in Nox1 3T3 compared to mock 3T3. Nox1 3T3 showed a time course of acidification that followed a double-exponential function with a fast and a slow component of, on average, tau=165 s and 1780 s, whereas mock 3T3 showed only a single slow tau of 1560 s. Expression of Nox1 also caused cells to acidify the extracellular medium at higher rates than control cells; Nox1 3T3 released 96+/-19 fmol h(-1)cell(-1) of acid equivalents compared to 19+/-12 fmol h(-1)cell(-1) in mock 3T3. These data show that expression of Nox1 results in a mechanism that has the capacity to rapidly acidify the cytosol and generate significant amounts of acid. No significant effect of Nox1 expression on the plasma membrane H(+) conductance was found.