Jérôme Wagner

The dinB Gene Encodes a Novel E. coli DNA Polymerase, DNA Pol IV, Involved in Mutagenesis

In Escherichia coli, the dinB gene is required for the SOS-induced lambda untargeted mutagenesis pathway and confers a mutator phenotype to the cell when the gene product is overexpressed. Here, we report that the purified DinB protein is a DNA polymerase. This novel E. coli DNA polymerase (pol IV) is shown to be strictly distributive, devoid of proofreading activity, and prone to elongate bulged (misaligned) primer/template structures. Site-directed mutagenesis experiments of dinB also demonstrate that the polymerase activity of DinB is required for its in vivo mutagenicity. Along with the sequence homologies previously found within the UmuC-like protein family, these results indicate that the uncovered DNA polymerase activity may be a common feature of all these homologous proteins.

All three SOS‐inducible DNA polymerases (Pol II, Pol IV and Pol V) are involved in induced mutagenesis

Most organisms contain several members of a recently discovered class of DNA polymerases (umuC/dinB superfamily) potentially involved in replication of damaged DNA. In Escherichia coli, only Pol V (umuDC) was known to be essential for base substitution mutagenesis induced by UV light or abasic sites. Here we show that, depending upon the nature of the DNA damage and its sequence context, the two additional SOS‐inducible DNA polymerases, Pol II (polB) and Pol IV (dinB), are also involved in error‐free and mutagenic translesion synthesis (TLS). For example, bypass of N‐2‐acetylaminofluorene (AAF) guanine adducts located within the NarI mutation hot spot requires Pol II for −2 frameshifts but Pol V for error‐free TLS. On the other hand, error‐free and −1 frameshift TLS at a benzo(a)pyrene adduct requires both Pol IV and Pol V. Therefore, in response to the vast diversity of existing DNA damage, the cell uses a pool of ‘translesional’ DNA polymerases in order to bypass the various DNA lesions.

The β clamp targets DNA polymerase IV to DNA and strongly increases its processivity

The recent discovery of a new family of ubiquitous DNA polymerases involved in translesion synthesis has shed new light onto the biochemical basis of mutagenesis. Among these polymerases, the dinB gene product (Pol IV) is involved in mutagenesis in Escherichia coli. We show here that the activity of native Pol IV is drastically modified upon interaction with the β subunit, the processivity factor of DNA Pol III. In the absence of the β subunit Pol IV is strictly distributive and no stable complex between Pol IV and DNA could be detected. In contrast, the β clamp allows Pol IV to form a stable initiation complex (t1/2 ≈ 2.3 min), which leads to a dramatic increase in the processivity of Pol IV reaching an average of 300–400 nucleotides. In vivo, the β processivity subunit may target DNA Pol IV to its substrate, generating synthesis tracks much longer than previously thought.

Pivotal role of the β-clamp in translesion DNA synthesis and mutagenesis in E. coli cells

The genetic information is continuously subjected to the attack by endogenous and exogenous chemical and physical carcinogens that damage the DNA template, thus compromising its biochemical functions. Despite the multiple and efficient DNA repair systems that have evolved to cope with the large variety of damages, some lesions may persist and, as a consequence, interfere with DNA replication. By essence, the damaged-DNA replication process (hereafter termed translesion synthesis or TLS) is a major source of point mutations and is therefore deeply involved in the onset of human diseases such as cancer. Recent identification of numerous DNA polymerases involved in TLS has shed new light onto the molecular mechanisms of mutagenesis. Here, we show that in vivo, both error-free and mutagenic bypass activities of the three DNA polymerases known to be involved in TLS in Escherichia coli (PolII, PolIV and PolV) strictly depend upon the integrity of small peptidic sequences identified as their β-clamp binding motif. Thus, in addition to its crucial role as the processivity factor of the PolIII replicase, the β-clamp plays a pivotal role during the TLS process.

The processivity factor β controls DNA polymerase IV traffic during spontaneous mutagenesis and translesion synthesis in vivo

The dinB‐encoded DNA polymerase IV (Pol IV) belongs to the recently identified Y‐family of DNA polymerases. Like other members of this family, Pol IV is involved in translesion synthesis and mutagenesis. Here, we show that the C‐terminal five amino acids of Pol IV are essential in targeting it to the β‐clamp, the processivity factor of the replicative DNA polymerase (Pol III) of Escherichia coli. In vivo, the disruption of this interaction obliterates the function of Pol IV in both spontaneous and induced mutagenesis. These results point to the pivotal role of the processivity clamp during DNA polymerase trafficking in the vicinity of damaged‐template DNA.

Genetics of mutagenesis in E. coli: various combinations of translesion polymerases (Pol II, IV and V) deal with lesion/sequence context diversity

The biochemistry and genetics of translesion synthesis (TLS) and, as a consequence, of mutagenesis has recently received much attention in view of the discovery of novel DNA polymerases, most of which belong to the Y family. These distributive and low fidelity enzymes assist the progression of the high fidelity replication complex in the bypass of DNA lesions that normally hinder its progression. The present paper extends our previous observation that in Escherichia coli all three SOS-inducible DNA polymerases (Pol II, IV and V) are involved in TLS and mutagenesis. The genetic control of frameshift mutation pathways induced by N-2-acetylaminofluorene (AAF) adducts or by oxidative lesions induced by methylene blue and visible light is investigated. The data show various examples of mutation pathways with an absolute requirement for a specific combination of DNA polymerases and, in contrast, other examples where two DNA polymerases exhibit functional redundancy within the same pathway. We suggest that cells respond to the challenge of replicating DNA templates potentially containing a large diversity of DNA lesions by using a pool of accessory DNA polymerases with relaxed specificities that assist the high fidelity replicase.

Role of the ubiquitin-binding domain of Polη in Rad18-independent translesion DNA synthesis in human cell extracts

In eukaryotic cells, the Rad6/Rad18-dependent monoubiquitination of the proliferating cell nuclear antigen (PCNA) plays an essential role in the switching between replication and translesion DNA synthesis (TLS). The DNA polymerase Polη binds to PCNA via a consensus C-terminal PCNA-interacting protein (PIP) motif. It also specifically interacts with monoubiquitinated PCNA thanks to a recently identified ubiquitin-binding domain (UBZ). To investigate whether the TLS activity of Polη is always coupled to PCNA monoubiquitination, we monitor the ability of cell-free extracts to perform DNA synthesis across different types of lesions. We observe that a cis-syn cyclobutane thymine dimer (TT-CPD), but not a N-2-acetylaminofluorene-guanine (G-AAF) adduct, is efficiently bypassed in extracts from Rad18-deficient cells, thus demonstrating the existence of a Polη-dependent and Rad18-independent TLS pathway. In addition, by complementing Polη-deficient cells with PIP and UBZ mutants, we show that each of these domains contributes to Polη activity. The finding that the bypass of a CPD lesion in vitro does not require Ub-PCNA but nevertheless depends on the UBZ domain of Polη, reveals that this domain may play a novel role in the TLS process that is not related to the monoubiquitination status of PCNA.

Postreplication repair mechanisms in the presence of DNA adducts in Escherichia coli

During bacterial replication, DNA polymerases may encounter DNA lesions that block processive DNA synthesis. Uncoupling the replicative helicase from the stalled DNA polymerase results in the formation of single-stranded DNA (ssDNA) gaps, which are repaired by postreplication repair (PRR), a process that involves at least three mechanisms that collectively remove, circumvent or bypass lesions. RecA mediated excision repair (RAMER) and homologous recombination (HR) are strand-exchange mechanisms that appear to be the predominant strategies for gap repair in the absence of prolonged SOS induction. During RAMER, RecA mediates pairing of damaged ssDNA with an undamaged homologous duplex and subsequent exchange of strands between the damaged and undamaged DNA. Repair of the lesion occurs in the context of the strand-exchange product and is initiated by UvrABC excinuclease; the resulting patch is filled by DNA synthesis using the complementary strand of the homologous duplex as a template. HR uses a complementary strand of an undamaged homologous duplex as a transient template for DNA synthesis. HR requires the formation and resolution of Holliday junctions, and is a mechanism to circumvent the lesion; lesions persisting in one of the daughter DNA duplexes will normally be repaired prior to subsequent rounds of replication/cell division. Translesion DNA Synthesis (TLS) does not involve strand-exchange mechanisms; it is carried out by specialized DNA polymerases that are able to catalyze nucleotide incorporation opposite lesions that cannot be bypassed by high-fidelity replicative polymerases. Maximum levels of TLS occur during prolonged SOS induction generally associated with increased mutagenesis. RAMER, HR and TLS are alternative mechanisms for processing a common intermediate-the ssDNA gap containing a RecA nucleofilament. The actual pathway that is utilized will be strongly influenced by multiple factors, including the blocking/coding capacity of the lesion, the nature of the gene products that can be assembled at the ssDNA gap, the availability of a homologous partner for RAMER and HR, and protein:protein interactions and post-translational modifications that modulate the mutagenic activity of Pol-IV and Pol-V.

FF483–484 motif of human Polη mediates its interaction with the POLD2 subunit of Polδ and contributes to DNA damage tolerance

Switching between replicative and translesion synthesis (TLS) DNA polymerases are crucial events for the completion of genomic DNA synthesis when the replication machinery encounters lesions in the DNA template. In eukaryotes, the translesional DNA polymerase η (Polη) plays a central role for accurate bypass of cyclobutane pyrimidine dimers, the predominant DNA lesions induced by ultraviolet irradiation. Polη deficiency is responsible for a variant form of the Xeroderma pigmentosum (XPV) syndrome, characterized by a predisposition to skin cancer. Here, we show that the FF483–484 amino acids in the human Polη (designated F1 motif) are necessary for the interaction of this TLS polymerase with POLD2, the B subunit of the replicative DNA polymerase δ, both in vitro and in vivo. Mutating this motif impairs Polη function in the bypass of both an N-2-acetylaminofluorene adduct and a TT-CPD lesion in cellular extracts. By complementing XPV cells with different forms of Polη, we show that the F1 motif contributes to the progression of DNA synthesis and to the cell survival after UV irradiation. We propose that the integrity of the F1 motif of Polη, necessary for the Polη/POLD2 interaction, is required for the establishment of an efficient TLS complex.

Targeting the replisome with transduced monoclonal antibodies triggers lethal DNA replication stress in cancer cells.

Although chemical inhibition of the DNA damage response (DDR) in cancer cells triggers cell death, it is not clear if the fork blockade achieved with inhibitors that neutralise proteins of the replisome is sufficient on its own to overcome the DDR. Monoclonal antibodies to PCNA, which block the DNA elongation process in vitro, have been developed. When these antibodies were transduced into cancer cells, they are able to inhibit the incorporation of nucleoside analogues. When co-delivered with anti-PCNA siRNA, the cells were flattened and the size of their nuclei increased by up to 3-fold, prior to cell death. Analysis of these nuclei by super-resolution microscopy revealed the presence of large numbers of phosphorylated histone H2AX foci. A senescence-like phenotype of the transduced cells was also observed upon delivery of the corresponding Fab molecules or following PCNA gene disruption or when the Fab fragment of an antibody that neutralises DNA polymerase alpha was used. Primary melanoma cells and leukaemia cells that are resistant to chemical inhibitors were similarly affected by these antibody treatments. These results demonstrate that transduced antibodies can trigger a lethal DNA replication stress, which kills cancer cells by abolishing the biological activity of several constituents of the replisome.