Acetylation of histone H3 lysine 56 regulates replication-coupled nucleosome assembly

Chromatin assembly factor 1 (CAF-1) and Rtt106 participate in the deposition of newly synthesized histones onto replicating DNA to form nucleosomes. This process is critical for the maintenance of genome stability and inheritance of functionally specialized chromatin structures in proliferating cells. However, the molecular functions of the acetylation of newly synthesized histones in this DNA replication-coupled nucleosome assembly pathway remain enigmatic. Here we show that histone H3 acetylated at lysine 56 (H3K56Ac) is incorporated onto replicating DNA and, by increasing the binding affinity of CAF-1 and Rtt106 for histone H3, H3K56Ac enhances the ability of these histone chaperones to assemble DNA into nucleosomes. Genetic analysis indicates that H3K56Ac acts in a nonredundant manner with the acetylation of the N-terminal residues of H3 and H4 in nucleosome assembly. These results reveal a mechanism by which H3K56Ac regulates replication-coupled nucleosome assembly mediated by CAF-1 and Rtt106.     

Replication-dependent marking of DNA by PCNA facilitates CAF-1-coupled inheritance of chromatin

Chromatin assembly factor 1 (CAF-1) is required for inheritance of epigenetically determined chromosomal states in vivo and promotes assembly of chromatin during DNA replication in vitro. Herein, we demonstrate that after DNA replication, replicated, but not unreplicated, DNA is also competent for CAF-1-dependent chromatin assembly. The proliferating cell nuclear antigen (PCNA), a DNA polymerase clamp, is a component of the replication-dependent marking of DNA for chromatin assembly. The clamp loader, replication factor C (RFC), can reverse this mark by unloading PCNA from the replicated DNA. PCNA binds directly to p150, the largest subunit of CAF-1, and the two proteins colocalize at sites of DNA replication in cells. We suggest that PCNA and CAF-1 connect DNA replication to chromatin assembly and the inheritance of epigenetic chromosome states.     

Essential role of chromatin assembly factor-1-mediated rapid nucleosome assembly for DNA replication and cell division in vertebrate cells

Chromatin assembly factor-1 (CAF-1), a complex consisting of p150, p60, and p48 subunits, is highly conserved from yeast to humans and facilitates nucleosome assembly of newly replicated DNA in vitro. To investigate roles of CAF-1 in vertebrates, we generated two conditional DT40 mutants, respectively, devoid of CAF-1p150 and p60. Depletion of each of these CAF-1 subunits led to delayed S-phase progression concomitant with slow DNA synthesis, followed by accumulation in late S/G2 phase and aberrant mitosis associated with extra centrosomes, and then the final consequence was cell death. We demonstrated that CAF-1 is necessary for rapid nucleosome formation during DNA replication in vivo as well as in vitro. Loss of CAF-1 was not associated with the apparent induction of phosphorylations of S-checkpoint kinases Chk1 and Chk2. To elucidate the precise role of domain(s) in CAF-1p150, functional dissection analyses including rescue assays were preformed. Results showed that the binding abilities of CAF-1p150 with CAF-1p60 and DNA polymerase sliding clamp proliferating cell nuclear antigen (PCNA) but not with heterochromatin protein HP1-gamma are required for cell viability. These observations highlighted the essential role of CAF-1-dependent nucleosome assembly in DNA replication and cell proliferation through its interaction with PCNA.     

In vivo study of the nucleosome assembly functions of ASF1 histone chaperones in human cells

Histone chaperones have been implicated in nucleosome assembly and disassembly as well as histone modification. ASF1 is a highly conserved histone H3/H4 chaperone that synergizes in vitro with two other histone chaperones, chromatin assembly factor 1 (CAF-1) and histone repression A factor (HIRA), in DNA synthesis-coupled and DNA synthesis-independent nucleosome assembly. Here, we identify mutants of histones H3.1 and H3.3 that are unable to interact with human ASF1A and ASF1B isoforms but that are still competent to bind CAF-1 and HIRA, respectively. We show that these mutant histones are inefficiently deposited into chromatin in vivo. Furthermore, we found that both ASF1A and ASF1B participate in the DNA synthesis-independent deposition of H3.3 in HeLa cells, thus highlighting an unexpected role for ASF1B in this pathway. This pathway does not require interaction of ASF1 with HIRA. We provide the first direct determination that ASF1A and ASF1B play a role in the efficiency of nucleosome assembly in vivo in human cells.     

AtMCM10 promotes DNA replication-coupled nucleosome assembly in Arabidopsis

Minichromosome Maintenance protein 10 (MCM10) is essential for DNA replication initiation and DNA elongation in yeasts and animals. Although the functions of MCM10 in DNA replication and repair have been well documented, the detailed mechanisms for MCM10 in these processes are not well known. Here, we identified AtMCM10 gene through a forward genetic screening for releasing a silenced marker gene. Although plant MCM10 possesses a similar crystal structure as animal MCM10, AtMCM10 is not essential for plant growth or development in Arabidopsis. AtMCM10 can directly bind to histone H3-H4 and promotes nucleosome assembly in vitro. The nucleosome density is decreased in Atmcm10, and most of the nucleosome density decreased regions in Atmcm10 are also regulated by newly synthesized histone chaperone Chromatin Assembly Factor-1 (CAF-1). Loss of both AtMCM10 and CAF-1 is embryo lethal, indicating that AtMCM10 and CAF-1 are indispensable for replication-coupled nucleosome assembly. AtMCM10 interacts with both new and parental histones. Atmcm10 mutants have lower H3.1 abundance and reduced H3K27me1/3 levels with releasing some silenced transposons. We propose that AtMCM10 deposits new and parental histones during nucleosome assembly, maintaining proper epigenetic modifications and genome stability during DNA replication.     

Replication-coupled chromatin assembly generates a neuronal bilateral asymmetry in C. elegans

Although replication-coupled chromatin assembly is known to be important for the maintenance of patterns of gene expression through sequential cell divisions, the role of replication-coupled chromatin assembly in controlling cell differentiation during animal development remains largely unexplored. Here we report that the CAF-1 protein complex, an evolutionarily conserved histone chaperone that deposits histone H3-H4 proteins onto replicating DNA, is required to generate a bilateral asymmetry in the C. elegans nervous system. A mutation in 1 of 24 C. elegans histone H3 genes specifically eliminates this aspect of neuronal asymmetry by causing a defect in the formation of a histone H3-H4 tetramer and the consequent inhibition of CAF-1-mediated nucleosome formation. Our results reveal that replication-coupled nucleosome assembly is necessary to generate a bilateral asymmetry in C. elegans neuroanatomy and suggest that left-right asymmetric epigenetic regulation can establish bilateral asymmetry in the nervous system.     

Human histone acetyltransferase 1 protein preferentially acetylates H4 histone molecules in H3.1-H4 over H3.3-H4

In mammalian cells, canonical histone H3 (H3.1) and H3 variant (H3.3) differ by five amino acids and are assembled, along with histone H4, into nucleosomes via distinct nucleosome assembly pathways. H3.1-H4 molecules are assembled by histone chaperone CAF-1 in a replication-coupled process, whereas H3.3-H4 are assembled via HIRA in a replication-independent pathway. Newly synthesized histone H4 is acetylated at lysine 5 and 12 (H4K5,12) by histone acetyltransferase 1 (HAT1). However, it remains unclear whether HAT1 and H4K5,12ac differentially regulate these two nucleosome assembly processes. Here, we show that HAT1 binds and acetylates H4 in H3.1-H4 molecules preferentially over H4 in H3.3-H4. Depletion of Hat1, the catalytic subunit of HAT1 complex, results in reduced H3.1 occupancy at H3.1-enriched genes and reduced association of Importin 4 with H3.1, but not H3.3. Finally, depletion of Hat1 or CAF-1p150 leads to changes in expression of a H3.1-enriched gene. These results indicate that HAT1 differentially impacts nucleosome assembly of H3.1-H4 and H3.3-H4.     

The ins and outs of nucleosome assembly

De novo nucleosome assembly coupled to DNA replication and repair in vitro involves the histone chaperone chromatin assembly factor 1 (CAF-1). Recent studies support a model in which CAF-1 can be targeted to newly synthesized DNA through a direct interaction with proliferating cell nuclear antigen (PCNA) and can act synergistically with a newly identified histone chaperone. Insights have also been obtained into mechanisms by which this CAF-1-dependent pathway can establish a repressed chromatin state.     

New histone supply regulates replication fork speed and PCNA unloading

Correct duplication of DNA sequence and its organization into chromatin is central to genome function and stability. However, it remains unclear how cells coordinate DNA synthesis with provision of new histones for chromatin assembly to ensure chromosomal stability. In this paper, we show that replication fork speed is dependent on new histone supply and efficient nucleosome assembly. Inhibition of canonical histone biosynthesis impaired replication fork progression and reduced nucleosome occupancy on newly synthesized DNA. Replication forks initially remained stable without activation of conventional checkpoints, although prolonged histone deficiency generated DNA damage. PCNA accumulated on newly synthesized DNA in cells lacking new histones, possibly to maintain opportunity for CAF-1 recruitment and nucleosome assembly. Consistent with this, in vitro and in vivo analysis showed that PCNA unloading is delayed in the absence of nucleosome assembly. We propose that coupling of fork speed and PCNA unloading to nucleosome assembly provides a simple mechanism to adjust DNA replication and maintain chromatin integrity during transient histone shortage.     

Reverse-chaperoning activity of an AAA+ protein

Speed and processivity of replicative DNA polymerases can be enhanced via coupling to a sliding clamp. Due to the closed ring shape of the clamp, a clamp loader protein, belonging to the AAA+ class of ATPases, needs to open the ring-shaped clamp before loading it to DNA. Here, we developed real-time fluorescence assays to study the clamp (PCNA) and the clamp loader (RFC) from the mesophilic archaeon Methanosarcina acetivorans. Unexpectedly, we discovered that RFC can assemble a PCNA ring from monomers in solution. A motion-based DNA polymerization assay showed that the PCNA assembled by RFC is functional. This PCNA assembly activity required the ATP-bound conformation of RFC. Our work demonstrates a reverse-chaperoning activity for an AAA+ protein that can act as a template for the assembly of another protein complex.     

The yeast histone chaperone chromatin assembly factor 1 protects against double-strand DNA-damaging agents

The removal of histones from DNA and their subsequent replacement is likely to be necessary for all processes that require access to the DNA sequence in eukaryotic cells. The histone chaperone chromatin assembly factor 1 (CAF-1) mediates histone H3-H4 assembly during DNA replication and nucleotide excision repair in vitro. We have found that budding yeast deleted for the genes encoding CAF-1 are highly sensitive to double-strand DNA-damaging agents. Our genetic analyses indicate that CAF-1 plays a role in both homologous recombination and nonhomologous end-joining pathways and that the function of CAF-1 during double-strand repair is distinct from that of another histone H3-H4 chaperone, anti-silencing function 1 (ASF1). CAF-1 does not protect the genome by assembling it into a damage-resistant chromatin structure, because induction of CAF-1 after DNA damage is sufficient to restore viability. Furthermore, CAF-1 is not required for repair of the DNA per se or for DNA damage checkpoint function. CAF-1-mediated resistance to DNA damage is dependent on the ability of CAF-1 to bind PCNA, indicating that PCNA may recruit CAF-1 to sites of double-strand DNA repair. We propose that CAF-1 has an essential role in assembling chromatin during double-strand-DNA repair.     

Roles for Gcn5 in promoting nucleosome assembly and maintaining genome integrity

The coordinated process of DNA replication and nucleosome assembly, termed replication-coupled (RC) nucleosome assembly, is important for the maintenance of genome integrity. Loss of genome integrity is linked to aging and cancer. RC nucleosome assembly involves deposition of histone H3-H4 by the histone chaperones CAF-1, Rtt106 and Asf1 onto newly-replicated DNA. Coordinated actions of these three histone chaperones are regulated by modifications on the histone proteins. One such modification is histone H3 lysine 56 acetylation (H3K56Ac), a mark of newly-synthesized histone H3 that regulates the interaction between H3-H4 and the histone chaperones CAF-1 and Rtt106 following DNA replication and DNA repair. Recently, we have shown that the lysine acetyltransferase Gcn5 and H3 N-terminal tail lysine acetylation also regulates the interaction between H3-H4 and CAF-1 to promote the deposition of newly-synthesized histones. Genetic studies indicate that Gcn5 and Rtt109, the H3K56Ac lysine acetyltransferase, function in parallel to maintain genome stability. Utilizing synthetic genetic array analysis, we set out to identify additional genes that function in parallel with Gcn5 in response to DNA damage. We summarize here the role of Gcn5 in nucleosome assembly and suggest that Gcn5 impacts genome integrity via multiple mechanisms, including nucleosome assembly.     

Roles for Gcn5 in promoting nucleosome assembly and maintaining genome integrity

The process of coordinated DNA replication and nucleosome assembly, termed replication-coupled (RC) nucleosome assembly, is important for the maintenance of genome integrity. Loss of genome integrity is linked to aging and cancer. RC nucleosome assembly involves deposition of histone H3–H4 by the histone chaperones CAF-1, Rtt106 and Asf1 onto newly-replicated DNA. Coordinated actions of these three his-tone chaperones are regulated by modifications on the histone proteins. One such modification is histone H3 lysine 56 acetylation (H3K56Ac), a mark of newly-synthesized histone H3 that regulates the interaction between H3–H4 and the histone chaperones CAF-1 and Rtt106 following DNA replication and DNA repair. Recently, we have shown that the lysine acetyltransferase Gcn5 and H3 N-terminal tail lysine acetylation also regulates the interaction between H3–H4 and CAF-1 to promote the deposition of newly-synthesized histones. Genetic studies indicate that Gcn5 and Rtt109, the H3K56Ac lysine acetyltransferase, function in parallel to maintain genome stability. Utilizing synthetic genetic array analysis, we set out to identify additional genes that function in parallel with Gcn5 in response to DNA damage. We summarize here the role of Gcn5 in nucleosome assembly and suggest that Gcn5 impacts genome integrity via multiple mechanisms, including nucleosome assembly.Key words: Gen5, Rtt109, chromatin, nucleosome assembly, genome integrity     

Two Fundamentally Distinct PCNA Interaction Peptides Contribute to Chromatin Assembly Factor 1 Function

Chromatin assembly factor 1 (CAF-1) deposits histones H3 and H4 rapidly behind replication forks through an interaction with the proliferating cell nuclear antigen (PCNA), a DNA polymerase processivity factor that also binds to a number of replication enzymes and other proteins that act on nascent DNA. The mechanisms that enable CAF-1 and other PCNA-binding proteins to function harmoniously at the replication fork are poorly understood. Here we report that the large subunit of human CAF-1 (p150) contains two distinct PCNA interaction peptides (PIPs). The N-terminal PIP binds strongly to PCNA in vitro but, surprisingly, is dispensable for nucleosome assembly and only makes a modest contribution to targeting p150 to DNA replication foci in vivo. In contrast, the internal PIP (PIP2) lacks one of the highly conserved residues of canonical PIPs and binds weakly to PCNA. Surprisingly, PIP2 is essential for nucleosome assembly during DNA replication in vitro and plays a major role in targeting p150 to sites of DNA replication. Unlike canonical PIPs, such as that of p21, the two p150 PIPs are capable of preferentially inhibiting nucleosome assembly, rather than DNA synthesis, suggesting that intrinsic features of these peptides are part of the mechanism that enables CAF-1 to function behind replication forks without interfering with other PCNA-mediated processes.Eukaryotic cells in S phase not only have to replicate their entire genome but also faithfully reproduce preexisting chromatin structures onto the two nascent chromatids. The duplication of chromatin structures during DNA replication is a challenging task for eukaryotic cells. Newly synthesized histones are deposited very rapidly behind replication forks (150 to 300 bp), almost as soon as enough DNA has emerged from the replisome to allow the formation of nucleosome core particles (52). A key protein involved in coupling nucleosome assembly to DNA replication is chromatin assembly factor 1 (CAF-1). CAF-1 is a complex of three polypeptide subunits, known as p150, p60, and RbAp48 in vertebrates, that mediates the first step in nucleosome formation by depositing newly synthesized histone H3/H4 onto DNA (25, 50).In mouse and human cells, CAF-1 localizes to virtually all DNA replication foci throughout the S phase (28, 38, 49, 54). This strongly argues that CAF-1 is a physiologically relevant histone H3/H4 nucleosome assembly factor. In addition, disruption of CAF-1 function in human cells results in a severe loss of viability that is accompanied by spontaneous DNA damage and a block in S-phase progression (20, 40, 60). Thus, unlike in Saccharomyces cerevisiae, the function of CAF-1 in vertebrates cannot be replaced by that of other nucleosome factors, such as members of the Hir protein family or Rtt106 (24, 27, 29). This may be because, unlike CAF-1, HIRA (a human homologue of yeast Hir1 and Hir2) does not associate with core histones that are synthesized during S phase (55). In human cells, the ability to promote nucleosome assembly preferentially onto replicating DNA is thus far unique to CAF-1.This distinctive property of CAF-1 is mediated through proliferating cell nuclear antigen (PCNA), a homotrimeric ring that encircles double-stranded DNA (4) and acts as a sliding clamp to tether DNA polymerases to their DNA substrate and thereby enhance their processivity. Several lines of biochemical and genetic evidence support the role of PCNA in CAF-1-mediated nucleosome assembly. First, CAF-1 colocalizes with PCNA in vivo and binds directly to PCNA in vitro (27, 35, 49, 61). Second, even in the presence of excess unreplicated DNA, CAF-1 can select fully replicated plasmid DNA molecules as preferential substrates for histone deposition, but only when those molecules are associated with PCNA (49). Third, PCNA-driven DNA synthesis can also attract CAF-1 to sites of DNA repair events, such as nucleotide excision repair (12, 15, 32, 35). Fourth, a specific PCNA mutation impairs the role of CAF-1 in telomeric silencing in S. cerevisiae (48, 61). Interestingly, a number of PCNA mutations that reduce its interaction with other PCNA-binding proteins have apparently no effect on CAF-1 function in vivo (48, 61). This implies that the interaction of CAF-1 with PCNA is substantially different from that of other PCNA-binding proteins.Enhancing DNA polymerase processivity is not the only function of PCNA in DNA replication. The sliding clamp also directly binds to other replication enzymes, such as DNA ligase 1, DNA polymerase δ, and FEN1 (14, 21, 37). In addition to its roles in DNA synthesis and nucleosome assembly, PCNA also directly binds to a number of enzymes that continuously monitor and correct the quality of nascent DNA. These include enzymes involved in epigenetic inheritance, such as the maintenance DNA methyltransferase DNMT1 (8), base excision repair (UNG2) (42), mismatch repair (MSH3 and MSH6) (9), DNA lesion bypass (23), and many other processes (31, 36). Even subtle defects in many of these processes, including CAF-1-dependent nucleosome assembly (39), lead to either chromosome rearrangements or mutator phenotypes, which are common features of many human cancers. Surprisingly, many of these enzymes interact with PCNA via canonical PCNA interaction peptides (PIPs) that conform to the consensus sequence QXXhXXaa, where Q is a glutamine, h is a hydrophobic residue (valine, methionine, leucine, or isoleucine), a is an aromatic residue (phenylalanine, tyrosine, tryptophan, or occasionally histidine), and X represents any amino acid. Therefore, regulatory mechanisms must exist to ensure that these fundamentally distinct PCNA-dependent processes occur in a carefully orchestrated manner without mutually interfering with each other.In order to understand how the action of CAF-1 is coordinated with that of other PCNA-binding proteins at replication forks, we carried out a thorough study of CAF-1 PIPs by analyzing their functions using a number of assays. We found that the p150 subunit of CAF-1 contains two fundamentally distinct PIPs. The N-terminal motif (PIP1) binds strongly to PCNA in vitro but is dispensable for nucleosome assembly during simian virus 40 (SV40) DNA replication. In contrast, despite the lack of a key conserved residue, the second PIP (PIP2) of CAF-1 is crucial for replication-dependent nucleosome assembly in vitro and for targeting CAF-1 to DNA replication foci in vivo. Remarkably, although PIP2 exhibits some features of canonical PIPs, it binds only weakly to PCNA in vitro. We suggest that regulated PCNA binding via this peptide may play an important role in ensuring that CAF-1 can efficiently deposit histones behind replication forks without competing with the numerous other enzymes that require continuous access to PCNA during DNA replication. Consistent with this, we show that CAF-1 PIPs possess the ability to preferentially interfere with nucleosome assembly rather than with DNA synthesis.     

Codanin-1, mutated in the anaemic disease CDAI, regulates Asf1 function in S-phase histone supply

Efficient supply of new histones during DNA replication is critical to restore chromatin organization and maintain genome function. The histone chaperone anti-silencing function 1 (Asf1) serves a key function in providing H3.1-H4 to CAF-1 for replication-coupled nucleosome assembly. We identify Codanin-1 as a novel interaction partner of Asf1 regulating S-phase histone supply. Mutations in Codanin-1 can cause congenital dyserythropoietic anaemia type I (CDAI), characterized by chromatin abnormalities in bone marrow erythroblasts. Codanin-1 is part of a cytosolic Asf1-H3.1-H4-Importin-4 complex and binds directly to Asf1 via a conserved B-domain, implying a mutually exclusive interaction with the chaperones CAF-1 and HIRA. Codanin-1 depletion accelerates the rate of DNA replication and increases the level of chromatin-bound Asf1, suggesting that Codanin-1 guards a limiting step in chromatin replication. Consistently, ectopic Codanin-1 expression arrests S-phase progression by sequestering Asf1 in the cytoplasm, blocking histone delivery. We propose that Codanin-1 acts as a negative regulator of Asf1 function in chromatin assembly. This function is compromised by two CDAI mutations that impair complex formation with Asf1, providing insight into the molecular basis for CDAI disease.     

A CAF-1-PCNA-mediated chromatin assembly pathway triggered by sensing DNA damage

Sensing DNA damage is crucial for the maintenance of genomic integrity and cell cycle progression. The participation of chromatin in these events is becoming of increasing interest. We show that the presence of single-strand breaks and gaps, formed either directly or during DNA damage processing, can trigger the propagation of nucleosomal arrays. This nucleosome assembly pathway involves the histone chaperone chromatin assembly factor 1 (CAF-1). The largest subunit (p150) of this factor interacts directly with proliferating cell nuclear antigen (PCNA), and critical regions for this interaction on both proteins have been mapped. To isolate proteins specifically recruited during DNA repair, damaged DNA linked to magnetic beads was used. The binding of both PCNA and CAF-1 to this damaged DNA was dependent on the number of DNA lesions and required ATP. Chromatin assembly linked to the repair of single-strand breaks was disrupted by depletion of PCNA from a cell-free system. This defect was rescued by complementation with recombinant PCNA, arguing for role of PCNA in mediating chromatin assembly linked to DNA repair. We discuss the importance of the PCNA-CAF-1 interaction in the context of DNA damage processing and checkpoint control.     

Yeast histone deposition protein Asf1p requires Hir proteins and PCNA for heterochromatic silencing

BACKGROUND: Position-dependent gene silencing in yeast involves many factors, including the four HIR genes and nucleosome assembly proteins Asf1p and chromatin assembly factor I (CAF-I, encoded by the CAC1-3 genes). Both cac Delta asfl Delta and cac Delta hir Delta double mutants display synergistic reductions in heterochromatic gene silencing. However, the relationship between the contributions of HIR genes and ASF1 to silencing has not previously been explored. RESULTS: Our biochemical and genetic studies of yeast Asf1p revealed links to Hir protein function. In vitro, an active histone deposition complex was formed from recombinant yeast Asf1p and histones H3 and H4 that lack a newly synthesized acetylation pattern. This Asf1p/H3/H4 complex generated micrococcal nuclease--resistant DNA in the absence of DNA replication and stimulated nucleosome assembly activity by recombinant yeast CAF-I during DNA synthesis. Also, Asf1p bound to the Hir1p and Hir2p proteins in vitro and in cell extracts. In vivo, the HIR1 and ASF1 genes contributed to silencing the heterochromatic HML locus via the same genetic pathway. Deletion of either HIR1 or ASF1 eliminated telomeric gene silencing in combination with pol30--8, encoding an altered form of the DNA polymerase processivity factor PCNA that prevents CAF-I from contributing to silencing. Conversely, other pol30 alleles prevented Asf1/Hir proteins from contributing to silencing. CONCLUSIONS: Yeast CAF-I and Asf1p cooperate to form nucleosomes in vitro. In vivo, Asf1p and Hir proteins physically interact and together promote heterochromatic gene silencing in a manner requiring PCNA. This Asf1/Hir silencing pathway functionally overlaps with CAF-I activity.     

The Chromatin Assembly Factor 1 Promotes Rad51-Dependent Template Switches at Replication Forks by Counteracting D-Loop Disassembly by the RecQ-Type Helicase Rqh1

At blocked replication forks, homologous recombination mediates the nascent strands to switch template in order to ensure replication restart, but faulty template switches underlie genome rearrangements in cancer cells and genomic disorders. Recombination occurs within DNA packaged into chromatin that must first be relaxed and then restored when recombination is completed. The chromatin assembly factor 1, CAF-1, is a histone H3-H4 chaperone involved in DNA synthesis-coupled chromatin assembly during DNA replication and DNA repair. We reveal a novel chromatin factor-dependent step during replication-coupled DNA repair: Fission yeast CAF-1 promotes Rad51-dependent template switches at replication forks, independently of the postreplication repair pathway. We used a physical assay that allows the analysis of the individual steps of template switch, from the recruitment of recombination factors to the formation of joint molecules, combined with a quantitative measure of the resulting rearrangements. We reveal functional and physical interplays between CAF-1 and the RecQ-helicase Rqh1, the BLM homologue, mutations in which cause Bloom''s syndrome, a human disease associating genome instability with cancer predisposition. We establish that CAF-1 promotes template switch by counteracting D-loop disassembly by Rqh1. Consequently, the likelihood of faulty template switches is controlled by antagonistic activities of CAF-1 and Rqh1 in the stability of the D-loop. D-loop stabilization requires the ability of CAF-1 to interact with PCNA and is thus linked to the DNA synthesis step. We propose that CAF-1 plays a regulatory role during template switch by assembling chromatin on the D-loop and thereby impacting the resolution of the D-loop.