Y‐family DNA polymerases have spacious active sites that can accommodate a wide variety of geometric distortions. As a consequence, they are considerably more error‐prone than high‐fidelity replicases. It is hardly surprising, therefore, that the in vivo activity of these polymerases is tightly regulated, so as to minimize their inadvertent access to primer‐termini. We report here that one such mechanism employed by human cells relies on a specific and direct interaction between DNA polymerases ι and η with ubiquitin (Ub). Indeed, we show that both polymerases interact noncovalently with free polyUb chains, as well as mono‐ubiquitinated proliferating cell nuclear antigen (Ub‐PCNA). Mutants of polι (P692R) and polη (H654A) were isolated that are defective in their interactions with polyUb and Ub‐PCNA, whilst retaining their ability to interact with unmodified PCNA. Interestingly, the polymerase mutants exhibit significantly lower levels of replication foci in response to DNA damage, thereby highlighting the biological importance of the polymerase–Ub interaction in regulating the access of the TLS polymerases to stalled replication forks in vivo.
Xeroderma pigmentosum (XP) is a skin cancer-prone autosomal recessive disease characterized by inability to repair UV-induced DNA damage. The major form of XP is defective in nucleotide excision repair (NER) and comprises seven complementation groups (A-G). The genes defective in all groups have been identified unambiguously with the exception of group E. The cells of some XP-E patients are deficient in a protein complex (consisting of two subunits: p127/DDBI and p48/DDB2) which binds to UV-damaged DNA (UV-DDB) and is specifically involved in the removal of photoproducts from the non-transcribed regions of the genome. However, other XP-E patients have been reported not to lack UV-damaged DNA binding activity (DDB(+)). Here we describe several genetically unrelated XP-E patients, not previously analyzed in depth, each carrying two mutated alleles for DDB2, causing either a single amino acid change or a protein truncation or internal deletion. These defects result in a severe decrease of detectable p48 protein, abolish interaction with the p127 subunit, and produce a deficiency in UV-DDB binding activity (DDB(-)). The role of p48 in the repair defect of these patients was demonstrated in vivo and in vitro. Investigation of four DDB(+) cell strains from patients previously assigned to XP-E, allowed us to reclassify all of them into other groups and to show that they do not share the molecular and biochemical features typical for XP-E. Besides confirming that the true XP-E phenotype is DDB(-), resulting from defects in a single gene, DDB2, our results identify the functional domains of the corresponding p48 protein.
A cDNA which encodes a approximately 127 kDa UV-damaged DNA-binding (UV-DDB) protein with high affinity for (6-4)pyrimidine dimers [Abramic', M., Levine, A.S. & Protic', M., J. Biol. Chem. 266: 22493-22500, 1991] has been isolated from a monkey cell cDNA library. The presence of this protein in complexes bound to UV-damaged DNA was confirmed by immunoblotting. The human cognate of the UV-DDB gene was localized to chromosome 11. UV-DDB mRNA was expressed in all human tissues examined, including cells from two patients with xeroderma pigmentosum (group E) that are deficient in UV-DDB activity, which suggests that the binding defect in these cells may reside in a dysfunctional UV-DDB protein. Database searches have revealed significant homology of the UV-DDB protein sequence with partial sequences of yet uncharacterized proteins from Dictyostelium discoideum (44% identity over 529 amino acids) and Oryza sativa (54% identity over 74 residues). According to our results, the UV-DDB polypeptide belongs to a highly conserved, structurally novel family of proteins that may be involved in the early steps of the UV response, e.g., DNA damage recognition.
Background: Accurate bypass of DNA damage by translesion DNA polymerases is critical for cell survival.Results: Wild-type human DNA polymerase ι incorporates ribonucleotides, and a steric gate mutant increases both ribonucleotide incorporation and deoxyribonucleotide selectivity.Conclusion: A single amino acid residue in DNA polymerase ι limits incorporation of ribonucleotides into DNA.Significance: DNA polymerase ι may incorporate ribonucleotides during translesion DNA synthesis.
Cells from complementation groups A through G of the heritable sun-sensitive disorder xeroderma pigmentosum (XP) show defects in nucleotide excision repair of damaged DNA. Proteins representing groups A, B, C, D, F, and G are subunits of the core recognition and incision machinery of repair. XP group E (XP-E) is the mildest form of the disorder, and cells generally show about 50% of the normal repair level. We investigated two protein factors previously implicated in the XP-E defect, UV-damaged DNA binding protein (UV-DDB) and replication protein A (RPA). Three newly identified XP-E cell lines (XP23PV, XP25PV, and a line formerly classified as an XP variant) were defective in UV-DDB binding activity but had levels of RPA in the normal range. The XP-E cell extracts did not display a significant nucleotide excision repair defect in vitro, with either UV-irradiated DNA or a uniquely placed cisplatin lesion used as a substrate. Purified UV-DDB protein did not stimulate repair of naked DNA by DDB ؊ XP-E cell extracts, but microinjection of the protein into DDB ؊ XP-E cells could partially correct the repair defect. RPA stimulated repair in normal, XP-E, or complemented extracts from other XP groups, and so the effect of RPA was not specific for XP-E cell extracts. These data strengthen the connection between XP-E and UV-DDB. Coupled with previous results, the findings suggest that UV-DDB has a role in the repair of DNA in chromatin.
Human DNA polymerases η and ι are best characterized for their ability to facilitate translesion DNA synthesis (TLS). Both polymerases (pols) co-localize in ‘replication factories’ in vivo after cells are exposed to ultraviolet light and this co-localization is mediated through a physical interaction between the two TLS pols. We have mapped the polη-ι interacting region to their respective ubiquitin-binding domains (UBZ in polη and UBM1 and UBM2 in polι), and demonstrate that ubiquitination of either TLS polymerase is a prerequisite for their physical and functional interaction. Importantly, while monoubiquitination of polη precludes its ability to interact with proliferating cell nuclear antigen (PCNA), it enhances its interaction with polι. Furthermore, a polι-ubiquitin chimera interacts avidly with both polη and PCNA. Thus, the ubiquitination status of polη, or polι plays a key regulatory function in controlling the protein partners with which each polymerase interacts, and in doing so, determines the efficiency of targeting the respective polymerase to stalled replication forks where they facilitate TLS.
Background: Many proteins are subject to posttranslational regulation, such as ubiquitination.Results: Human DNA polymerase ι (polι) can be monoubiquitinated at >27 unique sites, and exposure to naphthoquinones results in polyubiquitination of polι.Conclusion: Ubiquitination sites are located across the entire polι polypeptide as well as various structural motifs.Significance: Ubiquitination at these sites is likely to alter cellular functions of polι in vivo.
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