Human damage-specific DNA-binding protein p48. Characterization of XPE mutations and regulation following UV irradiation.

Damage-specific DNA binding (DDB) activity purifies from HeLa cells as a heterodimer (p127 and p48) and is absent from cells of a subset (Ddb(-)) of xeroderma pigmentosum Group E (XPE) patients. Each subunit was overexpressed in insect cells and purified. Both must be present for the damaged DNA band shift characteristic of the HeLa heterodimer. However, overexpressed p48 peptides containing the mutations found in three Ddb(-) XPE strains are inactive, and wild type p48 restores DDB activity to extracts from a fourth XPE Ddb(-) strain, GM01389, in which compound heterozygous mutations in DDB2 (p48) lead to a L350P change from one allele and a Asn-349 deletion from the other. Although these results indicate that these mutations are each responsible for the loss of DDB activity, they do not affect nuclear localization of p48. In normal fibroblasts, a 4-fold increase in p48 mRNA amount was observed 38 h after UV irradiation, preceding a similar elevation in p48 protein and DDB activity at 48 h, implying that p48 limits DDB activity in vivo. Because DNA repair is virtually complete before 48 h, a role for DDB other than DNA repair is suggested.

Nuclear transport of human DDB protein induced by ultraviolet light.

Human damage-specific DNA-binding (DDB) protein can be purified as a heterodimer (p48 and p127) that binds to DNA damaged by ultraviolet light. We report here the effects of UV irradiation on the cellular localization of each DDB subunit as a function of time using green fluorescent fusion proteins in three diploid fibroblast strains: repair-proficient IMR-90 and two repair-deficient xeroderma pigmentosum group E strains (XP95TO and XP3RO). Although p48 remained in the nucleus after UV irradiation, a dynamic nuclear accumulation of p127 from the cytoplasm was found after 24 h. In IMR-90 cells, the nuclear localization of p127 corresponded to the up-regulation of p48 mRNA and protein levels and of DDB activity. XP3RO cells showed delayed but similar kinetics with less transport, whereas XP95TO cells appeared to have different kinetics, suggesting that these cells exhibit different defects in p127 translocation. We propose that p48 might act as the transporter for nuclear entry of p127 but that a third factor might be necessary for efficient transportation.

The naturally occurring mutants of DDB are impaired in stimulating nuclear import of the p125 subunit and E2F1-activated transcription.

The human UV-damaged-DNA binding protein DDB has been linked to the repair deficiency disease xeroderma pigmentosum group E (XP-E), because a subset of XP-E patients lack the damaged-DNA binding function of DDB. Moreover, the microinjection of purified DDB complements the repair deficiency in XP-E cells lacking DDB. Two naturally occurring XP-E mutations of DDB, 82TO and 2RO, have been characterized. They have single amino acid substitutions (K244E and R273H) within the WD motif of the p48 subunit of DDB, and the mutated proteins lack the damaged-DNA binding activity. In this report, we describe a new function of the p48 subunit of DDB, which reveals additional defects in the function of the XP-E mutants. We show that when the subunits of DDB were expressed individually, p48 localized in the nucleus and p125 localized in the cytoplasm. The coexpression of p125 with p48 resulted in an increased accumulation of p125 in the nucleus, indicating that p48 plays a critical role in the nuclear localization of p125. The mutant forms of p48, 2RO and 82TO, are deficient in stimulating the nuclear accumulation of the p125 subunit of DDB. In addition, the mutant 2RO fails to form a stable complex with the p125 subunit of DDB. Our previous studies indicated that DDB can associate with the transcription factor E2F1 and can function as a transcriptional partner of E2F1. Here we show that the two mutants, while they associate with E2F1 as efficiently as wild-type p48, are severely impaired in stimulating E2F1-activated transcription. This is consistent with our observation that both subunits of DDB are required to stimulate E2F1-activated transcription. The results provide insights into the functions of the subunits of DDB and suggest a possible link between the role of DDB in E2F1-activated transcription and the repair deficiency disease XP-E.

Mutations specific to the xeroderma pigmentosum group E Ddb- phenotype.

The activity of a damage-specific DNA-binding protein (DDB) is absent from a subset, Ddb-, of cell strains from patients with xeroderma pigmentosum group E (XP-E). DDB is a heterodimer of 127-kDa and 48-kDa subunits. We have now identified single-base mutations in the gene of the 48-kDa subunit in cells from the three known Ddb- individuals, but not in XP-E strains that have the activity. An A --> G transition causes a K244E change in XP82TO and a G --> A transition causes an R273H change in XP2RO and XP3RO. No mutations were found in the cDNA of the 127-kDa subunit. Overexpression of p48 in insect cells greatly increases DDB activity in the cells, especially if p127 is jointly overexpressed. These results demonstrate that p48 is required for DNA binding activity, but at the same time necessitate further definition of the genetic basis of XP group E.

Functional complementation of xeroderma pigmentosum complementation group E by replication protein A in an in vitro system.

Xeroderma pigmentosum (XP) is caused by a defect in nucleotide excision repair. Patients in the complementation group E (XP-E) have the mildest form of the disease and the highest level of residual repair activity. About 20% of the cell strains derived from XP-E patients lack a damaged DNA-binding protein (DDB) activity that binds to ultraviolet-induced (6-4) photoproducts with high affinity. We report here that cell-free extracts prepared from XP-E cell strains that either lacked or contained DDB activity were severely defective in excising DNA damage including (6-4) photoproducts. However, this excision activity defect was not restored by addition of purified DDB that, in fact, inhibited removal of (6-4) photoproducts by the human excision nuclease reconstituted from purified proteins. Extensive purification of correcting activity from HeLa cells revealed that the correcting activity is inseparable from the human replication/repair protein A [RPA (also known as human single stranded DNA binding protein, HSSB)]. Indeed, supplementing XP-E extracts with recombinant human RPA purified from Escherichia coli restored excision activity. However, no mutation was found in the genes encoding the three subunits of RPA in an XP-E (DDB-) cell line. It is concluded that RPA functionally complements XP-E extracts in vitro, but it is not genetically altered in XP-E patients.

Cisplatin-induced alterations in the expression of the mRNAs for UV-damage recognition protein.

Enhanced DNA repair is believed to be an important mechanism of the cisplatin-resistant phenotype. UV-damage recognition protein (UV-DRP) recognizes and binds to DNA lesions and may play a role in DNA nucleotide excision repair and/or replicative bypass (which is associated with post-replication repair). Potential alternations in the expression of mRNAs for UV-DRP were analyzed in this study. Two pairs of parental and cisplatin-resistant human ovarian carcinoma cell lines were utilized. Gene expression level was assessed by northern blot hybridization. No alterations in mRNA levels for the large subunit of UV-DRP were found following cisplatin treatment, whereas mRNA levels for the small subunit of UV-DRP were induced up to 4.5-fold. The time-course and concentration-response of this induction corresponded to the previously reported increase in the UV-DRP binding activity, as measured by gel shift assay. UV-DRP binding activity in cell extracts corresponds to expression of small subunit mRNA but not to expression of large subunit mRNA. These data suggest that the small subunit may be limiting for UV-DRP activity.

Chromosomal localization and cDNA cloning of the genes (DDB1 and DDB2) for the p127 and p48 subunits of a human damage-specific DNA binding protein.

DDB is a damage-specific DNA binding protein whose binding activity is absent from a minority of cell strains from individuals with xeroderma pigmentosum Group E, a human hereditary disease characterized by defective nucleotide excision DNA repair and an increased incidence of skin cancer. The binding activity from HeLa cells is associated with polypeptides of M(r) 124,000 and 41,000 as determined by SDS-polyacrylamide gels. This report describes the isolation of full-length human cDNAs encoding each polypeptide of DDB. The predicted peptide molecular masses based on open reading frames are 127,000 and 48,000. When expressed in an in vitro rabbit reticulocyte system, the p48 subunit migrates with an M(r) of 41 kDa on SDS-polyacrylamide gels, similarly to the peptide purified from HeLa cells. There is no significant homology between the derived p48 peptide sequence and any proteins in current databases, and the derived peptide sequence of p127 has homology only with the monkey DDB p127 (98% nucleotide identity and only one conserved amino acid substitution). Using a fluorescence in situ hybridization technique, the DDB p127 locus (DDB1) was assigned to the chromosomal location 11q12-q13, and the DDB p48 locus (DDB2) to 11p11-p12.

Comparative analysis of binding of human damaged DNA-binding protein (XPE) and Escherichia coli damage recognition protein (UvrA) to the major ultraviolet photoproducts: T[c,s]T, T[t,s]T, T[6-4]T, and T[Dewar]T.

Human cells contain a protein that binds to UV-irradiated DNA with high affinity. This protein, the damaged DNA-binding protein (DDB), is absent from some xeroderma pigmentosum complementation group E cell strains; therefore, it has been suggested that it may be the damage recognition subunit of a human excision nuclease complex. However, the identity of the UV photoproduct bound by DDB and the role of this protein in nucleotide excision repair have been controversial. In this study, we used several synthetic DNA substrates, each of which contains one of the major UV photoproducts, and DDB purified to apparent homogeneity to quantify the specific binding of DDB to various photoproducts. For comparison, the binding of the same photoproducts by the Escherichia coli damage recognition protein UvrA, which is known to be a subunit of the E. coli excision nuclease, was also measured. UvrA and DDB each bound with high affinity to T[t,s]T, T[6-4]T, and T[Dewar]T, but only marginally discriminated between an undamaged oligomer and an oligomer with a T[c,s]T. In contrast to these similarities with regard to the binding to UV photoproducts, UvrA bound to another excision repair substrate, the psoralen-thymine monoadduct, with high specificity, whereas DDB was unable to distinguish between psoralen-adducted DNA and undamaged DNA. We conclude that DDB may play a special role in the repair of UV damage, but it cannot be the sole damage recognition subunit of human excision nuclease.

Purification of PCNA as a nucleotide excision repair protein.

Human cell free extracts carry out nucleotide excision repair in vitro. The extract is readily separated into two fractions by chromatography on a DEAE column. Neither the low salt (0.1 M KCl) nor the high salt (0.8 M KCl) fractions are capable of repair synthesis but the combination of the two restore the repair synthesis activity. Using the repair synthesis assay we purified a protein of 37 kDa from the high salt fraction which upon addition to the low salt fraction restores repair synthesis activity. Amino acid sequence analysis, amino acid composition and immunoblotting with PCNA antibodies revealed that the 37 kDa protein is the proliferating cell nuclear antigen (PCNA) known to stimulate DNA Polymerases delta and epsilon. By using an assay which specifically measures the excision of thymine dimers we found that PCNA is not required for the actual excision reaction per se but increases the extent of excision by enabling the excision repair enzyme to turn over catalytically.

Limitations of the in vitro repair synthesis assay for probing the role of DNA repair in platinum resistance.

Several studies have implicated enhanced DNA repair in acquired platinum resistance. To better understand the mechanism of increased repair we have employed an in vitro assay using cell-free extracts from platinum sensitive and resistant murine and human cell lines. Since the platinum resistant murine cell lines used in our previous studies had shown increased repair of diaminocyclohexane(dach)-Pt-DNA adducts while one of the resistant human cell lines did not, we have measured in vitro repair synthesis on DNA damaged by (d,l)-trans-1,2-diaminocyclohexanedichloroplatinum(II) (PtCl2(dach)). The results of this assay were strongly dependent on the method used to calculate repair synthesis activity and appeared to disagree with previous estimates of repair activity in these cell lines. By one method of calculation the in vitro repair synthesis assay underestimated the ratio of repair activities in the resistant versus the sensitive murine cell lines, while by the other method the in vitro assay overestimated the ratio of repair activities in the resistant versus the sensitive human cell lines.