Overexpression and purification of human XPA using a baculovirus expression system

Small-Molecule Inhibitor Screen for DNA Repair Proteins

With the recent interest in targeting the DNA damage response (DDR) and DNA repair, new screening methodologies are needed to broaden the scope of targetable proteins beyond kinases and traditional enzymes. Many of the proteins involved in the DDR and repair impart their activity by making specific contacts with DNA. These protein-nucleic acid interactions represent a tractable target for perturbation with small molecules. We describe a high throughput, solution-based equilibrium binding fluorescence polarization assay that can be applied to a wide array of protein-nucleic acid interactions. The assay is sensitive, stable, and able to identify small molecules capable of blocking DNA-protein interactions.

Design and Structure-Guided Development of Novel Inhibitors of the Xeroderma Pigmentosum Group A (XPA) Protein-DNA Interaction

XPA is a unique and essential protein required for the nucleotide excision DNA repair pathway and represents a therapeutic target in oncology. Herein, we are the first to develop novel inhibitors of the XPA-DNA interaction through structure-guided drug design efforts. Ester derivatives of the compounds 1 (X80), 22, and 24 displayed excellent inhibitory activity (IC₅₀ of 0.82 ± 0.18 μM and 1.3 ± 0.22 μM, respectively) but poor solubility. We have synthesized novel amide derivatives that retain potency and have much improved solubility. Furthermore, compound 1 analogs exhibited good specificity for XPA over RPA (replication protein A), another DNA-binding protein that participates in the nucleotide excision repair (NER) pathway. Importantly, there were no significant interactions observed by the X80 class of compounds directly with DNA. Molecular docking studies revealed a mechanistic model for the interaction, and these studies could serve as the basis for continued analysis of structure-activity relationships and drug development efforts of this novel target.

Recognition of DNA Termini by the C-Terminal Region of the Ku80 and the DNA-Dependent Protein Kinase Catalytic Subunit

DNA double strand breaks (DSBs) can be generated by endogenous cellular processes or exogenous agents in mammalian cells. These breaks are highly variable with respect to DNA sequence and structure and all are recognized in some context by the DNA-dependent protein kinase (DNA-PK). DNA-PK is a critical component necessary for the recognition and repair of DSBs via non-homologous end joining (NHEJ). Previously studies have shown that DNA-PK responds differentially to variations in DSB structure, but how DNA-PK senses differences in DNA substrate sequence and structure is unknown. Here we explore the enzymatic mechanisms by which DNA-PK is activated by various DNA substrates and provide evidence that the DNA-PK is differentially activated by DNA structural variations as a function of the C-terminal region of Ku80. Discrimination based on terminal DNA sequence variations, on the other hand, is independent of the Ku80 C-terminal interactions and likely results exclusively from DNA-dependent protein kinase catalytic subunit interactions with the DNA. We also show that sequence differences in DNA termini can drastically influence DNA repair through altered DNA-PK activation. These results indicate that even subtle differences in DNA substrates influence DNA-PK activation and ultimately the efficiency of DSB repair.

Identification of Mre11 as a target for heat radiosensitization

Thermal radiosensitization is believed to be mediated by an inhibition of double-strand break (DSB) repair, but the exact mechanism of radiosensitization remains to be elucidated. Previously, we demonstrated that proteins of the Mre11/Rad50/Nbs1 complex (MRN) translocate from the nucleus to the cytoplasm in cells have that been heated or heated and then irradiated; this finding led us to propose that heat radiosensitization was due at least in part to translocation of MRN. In the current study, we used leptomycin B to inhibit MRN translocation in heated, irradiated cells, but we found that heat radiosensitization was not altered. Thus enhanced radiosensitivity was not attributed to translocation of MRN proteins. To determine which of the MRN subunits contributed to heat radiosensitization, we compared the extent of heat radiosensitization in wild-type cells with that of cells hypomorphic for Mre11 or Nbs1 or cells in which the level of Rad50 was suppressed. We found that neither Nbs1 nor Rad50 is involved in heat radiosensitization, because a similar amount of heat radiosensitization was observed in cells deficient in those proteins compared to cells expressing normal levels. However, heat radiosensitization was not observed in A-TLD1 cells deficient in Mre11. Measurement of exonuclease activity of purified Mre11 heated at 42.5°C or 45.5°C indicated that the protein is very heat-labile. Immunoprecipitation of Mre11 from heated HeLa cells also revealed that hsp70 associates with Mre11 and that this association is maintained long after heating. Taken together, these findings implicate Mre11 as a target for heat radiosensitization and suggest that heat radiosensitization and inhibition of DSB repair may be mediated by heat-induced conformational changes in Mre11.

Interrogation of nucleotide excision repair capacity: impact on platinum-based cancer therapy

DNA repair is essential for routine monitoring and repair of damage imparted to our genetic material by exposure to endogenous and exogenous carcinogens, including reactive oxygen species, UV light, and chemicals such as those found in cigarette smoke. Without DNA repair pathways, the continual assault on our DNA would be highly mutagenic and the risk of cancer increased. Paradoxically, the same pathways that help prevent cancer development are detrimental to the efficacy of DNA-damaging cancer therapeutics such as cisplatin. Recent studies demonstrate the inverse relationship between DNA repair capacity and efficacy of platinum-based chemotherapeutics: increased DNA repair capacity leads to resistance, while decreased capacity leads to increased sensitivities. Cisplatin's cytotoxic effects are mediated by formation of intrastrand DNA crosslinks, which are predominantly repaired via the nucleotide excision repair (NER) pathway. In an effort to personalize the treatment of cancers based on DNA repair capacity, we developed an ELISA-based assay to measure NER activity accurately and reproducibly as a prognostic for platinum-based treatments. Here we present an overview of DNA repair and its link to cancer and therapeutics. We also present data demonstrating the ability to detect the proteins of the pre-incision complex within the NER pathway from cell and tissue extracts.

Identification of novel small molecule inhibitors of the XPA protein using in silico based screening

The nucleotide excision repair pathway catalyzes the removal of bulky adduct damage from DNA and requires the activity of more than 30 individual proteins and complexes. A diverse array of damage can be recognized and removed by the NER pathway including UV-induced adducts and intrastrand adducts induced by the chemotherapeutic compound cisplatin. The recognition of DNA damage is complex and involves a series of proteins including the xeroderma pigmentosum group A and C proteins and the UV-damage DNA binding protein. The xeroderma pigmentosum group A protein is unique in the sense that it is required for both transcription coupled and global genomic nucleotide excision repair. In addition, xeroderma pigmentosum group A protein is required for the removal of all types of DNA lesions repaired by nucleotide excision repair. Considering its importance in the damage recognition process, the minimal information available on the mechanism of DNA binding, and the potential that inhibition of xeroderma pigmentosum group A protein could enhance the therapeutic efficacy of platinum based anticancer drugs, we sought to identify and characterize small molecule inhibitors of the DNA binding activity of the xeroderma pigmentosum group A protein. In silico screening of a virtual small molecule library resulted in the identification of a class of molecules confirmed to inhibit the xeroderma pigmentosum group A protein-DNA interaction. Biochemical analysis of inhibition with varying DNA substrates revealed a common mechanism of xeroderma pigmentosum group A protein DNA binding to single-stranded DNA and cisplatin-damaged DNA.

Ser 524 is a phosphorylation site in MUTYH and Ser 524 mutations alter 8-oxoguanine (OG): a mismatch recognition

MUTYH-associated polyposis (MAP) is a colorectal cancer predisposition syndrome that is caused by inherited biallelic mutations in the base excision repair (BER) gene, MUTYH. MUTYH is a DNA glycosylase that removes adenine (A) misinserted opposite 8-oxo-7,8-dihydro-2'-deoxyguanosine (OG). In this work, wild type (WT) MUTYH overexpressed using a baculovirus-driven insect cell expression system (BEVS) provided significantly higher levels of enzyme compared to bacterial overexpression. The isolated MUTYH enzyme was analyzed for potential post-translational modifications using mass spectrometry. An in vivo phosphorylation site was validated at Serine 524, which is located in the C-terminal OG recognition domain within the proliferating cell nuclear antigen (PCNA) binding region. Characterization of the phosphomimetic (S524D) and phosphoablating (S524A) mutants together with the observation that Ser 524 can be phosphorylated suggest that this residue may play an important regulatory role in vivo by altering stability and OG:A mismatch affinity.

Purification and characterization of exonuclease-free Artemis: Implications for DNA-PK-dependent processing of DNA termini in NHEJ-catalyzed DSB repair

Artemis is a member of the beta-CASP family of nucleases in the metallo-beta-lactamase superfamily of hydrolases. Artemis has been demonstrated to be involved in V(D)J-recombination and in the NHEJ-catalyzed repair of DNA DSBs. In vitro, both DNA-PK independent 5'-3' exonuclease activities and DNA-PK dependent endonuclease activity have been attributed to Artemis, though mutational analysis of the Artemis active site only disrupts endonuclease activity. This suggests that either the enzyme contains two different active sites, or the exonuclease activity is not intrinsic to the Artemis polypeptide. To distinguish between these possibilities, we sought to determine if it was possible to biochemically separate Artemis endonuclease activity from exonuclease activity. Recombinant [His](6)-Artemis was expressed in a Baculovirus insect-cell expression system and isolated using a three-column purification methodology. Exonuclease and endonuclease activities, the ability to be phosphorylated by DNA-PK, and Artemis antibody reactivity was monitored throughout the purification and to characterize final pools of protein preparation. Results demonstrated the co-elution of exonuclease and endonuclease activities on a Ni-agarose affinity column but separation of the two enzymatic activities upon fractionation on a hydroxyapatite column. An exonuclease-free fraction of Artemis was obtained that retained DNA-PK dependent endonuclease activity, was phosphorylated by DNA-PK and reacted with an Artemis specific antibody. These data demonstrate that the exonuclease activity thought to be intrinsic to Artemis can be biochemically separated from the Artemis endonuclease.

Molecular analysis of Ku redox regulation

BACKGROUND

DNA double-strand breaks (DSBs) can occur in response to ionizing radiation (IR), radiomimetic agents and from endogenous DNA-damaging reactive oxygen metabolites. Unrepaired or improperly repaired DSBs are potentially the most lethal form of DNA damage and can result in chromosomal translocations and contribute to the development of cancer. The principal mechanism for the repair of DSBs in humans is non-homologous end-joining (NHEJ). Ku is a key member of the NHEJ pathway and plays an important role in the recognition step when it binds to free DNA termini. Ku then stimulates the assembly and activation of other NHEJ components. DNA binding of Ku is regulated by redox conditions and evidence from our laboratory has demonstrated that Ku undergoes structural changes when oxidized that results in a reduction in DNA binding activity. The C-terminal domain and cysteine 493 of Ku80 were investigated for their contribution to redox regulation of Ku.

RESULTS

We effectively removed the C-terminal domain of Ku80 generating a truncation mutant and co-expressed this variant with wild type Ku70 in an insect cell system to create a Ku70/80DeltaC heterodimer. We also generated two single amino acid variants of Cys493, replacing this amino acid with either an alanine (C493A) or a serine (C493S), and over-expressed the variant proteins in SF9 insect cells in complex with wild type Ku70. Neither the truncation nor the amino acid substitutions alters protein expression or stability as determined by SDS-PAGE and Western blot analysis. We show that the C493 mutations do not alter the ability of Ku to bind duplex DNA in vitro under reduced conditions while truncation of the Ku80 C-terminus slightly reduced DNA binding affinity. Diamide oxidation of cysteines was shown to inhibit DNA binding similarly for both the wild-type and all variant proteins. Interestingly, differential DNA binding activity following re-reduction was observed for the Ku70/80DeltaC truncation mutant.

CONCLUSION

Together, these results suggest that the C-terminal domain and C493 of Ku80 play at most a minor role in the redox regulation of Ku, and that other cysteines are likely involved, either alone or in conjunction with these regions of Ku80.

The human Tim/Tipin complex coordinates an Intra-S checkpoint response to UV that slows replication fork displacement

UV-induced DNA damage stalls DNA replication forks and activates the intra-S checkpoint to inhibit replicon initiation. In response to stalled replication forks, ATR phosphorylates and activates the transducer kinase Chk1 through interactions with the mediator proteins TopBP1, Claspin, and Timeless (Tim). Murine Tim recently was shown to form a complex with Tim-interacting protein (Tipin), and a similar complex was shown to exist in human cells. Knockdown of Tipin using small interfering RNA reduced the expression of Tim and reversed the intra-S checkpoint response to UVC. Tipin interacted with replication protein A (RPA) and RPA-coated DNA, and RPA promoted the loading of Tipin onto RPA-free DNA. Immunofluorescence analysis of spread DNA fibers showed that treating HeLa cells with 2.5 J/m(2) UVC not only inhibited the initiation of new replicons but also reduced the rate of chain elongation at active replication forks. The depletion of Tim and Tipin reversed the UV-induced inhibition of replicon initiation but affected the rate of DNA synthesis at replication forks in different ways. In undamaged cells depleted of Tim, the apparent rate of replication fork progression was 52% of the control. In contrast, Tipin depletion had little or no effect on fork progression in unirradiated cells but significantly attenuated the UV-induced inhibition of DNA chain elongation. Together, these findings indicate that the Tim-Tipin complex mediates the UV-induced intra-S checkpoint, Tim is needed to maintain DNA replication fork movement in the absence of damage, Tipin interacts with RPA on DNA and, in UV-damaged cells, Tipin slows DNA chain elongation in active replicons.

DNA damage induced hyperphosphorylation of replication protein A. 2. Characterization of DNA binding activity, protein interactions, and activity in DNA replication and repair

Replication protein A (RPA) is a heterotrimeric protein consisting of 70-, 34-, and 14- kDa subunits that is required for many DNA metabolic processes including DNA replication and DNA repair. Using a purified hyperphosphorylated form of RPA protein prepared in vitro, we have addressed the effects of hyperphosphorylation on steady-state and pre-steady-state DNA binding activity, the ability to support DNA repair and replication reactions, and the effect on the interaction with partner proteins. Equilibrium DNA binding activity measured by fluorescence polarization reveals no difference in ssDNA binding to pyrimidine-rich DNA sequences. However, RPA hyperphosphorylation results in a decreased affinity for purine-rich ssDNA and duplex DNA substrates. Pre-steady-state kinetic analysis is consistent with the equilibrium DNA binding and demonstrates a contribution from both the k(on) and k(off) to achieve these differences. The hyperphosphorylated form of RPA retains damage-specific DNA binding, and, importantly, the affinity of hyperphosphorylated RPA for damaged duplex DNA is 3-fold greater than the affinity of unmodified RPA for undamaged duplex DNA. The ability of hyperphosphorylated RPA to support DNA repair showed minor differences in the ability to support nucleotide excision repair (NER). Interestingly, under reaction conditions in which RPA is maintained in a hyperphosphorylated form, we also observed inhibition of in vitro DNA replication. Analyses of protein-protein interactions bear out the effects of hyperphosphorylated RPA on DNA metabolic pathways. Specifically, phosphorylation of RPA disrupts the interaction with DNA polymerase alpha but has no significant effect on the interaction with XPA. These results demonstrate that the effects of DNA damage induced hyperphosphorylation of RPA on DNA replication and DNA repair are mediated through alterations in DNA binding activity and protein-protein interactions.

Cooperative interaction of human XPA stabilizes and enhances specific binding of XPA to DNA damage

Human xeroderma pigmentosum group A (XPA) is an essential protein for nucleotide excision repair (NER). We have previously reported that XPA forms a homodimer in the absence of DNA. However, what oligomeric forms of XPA are involved in DNA damage recognition and how the interaction occurs in terms of biochemical understanding remain unclear. Using the homogeneous XPA protein purified from baculovirus-infected Sf21 insect cells and the methods of gel mobility shift assays, gel filtration chromatography, and UV-cross-linking, we demonstrated that both monomeric and dimeric XPA bound to the DNA adduct of N-acetyl-2-aminofluorene (AAF), while showing little affinity for nondamaged DNA. The binding occurred in a sequential and protein concentration-dependent manner. At relatively low-protein concentrations, XPA formed a complex with DNA adduct as a monomer, while at the higher concentrations, an XPA dimer was involved in the specific binding. Results from fluorescence spectroscopic and competitive binding analyses indicated that the specific binding of XPA to the adduct was significantly facilitated and stabilized by the presence of the second XPA in a positive cooperative manner. This cooperative binding exhibited a Hill coefficient of 1.9 and the step binding constants of K(1) = 1.4 x 10(6) M(-)(1) and K(2) = 1.8 x 10(7) M(-)(1). When interaction of XPA and RPA with DNA was studied, even though binding of RPA-XPA complex to adducted DNA was observed, the presence of RPA had little effect on the overall binding efficiency. Our results suggest that the dominant form for XPA to efficiently bind to DNA damage is the XPA dimer. We hypothesized that the concentration-dependent formation of different types of XPA-damaged DNA complex may play a role in cellular regulation of XPA activity.

Removal of poly-histidine fusion tags from recombinant proteins purified by expanded bed adsorption

Enzymatic methods have been used to cleave the C- or N-terminus polyhistidine tags from histidine tagged proteins following expanded bed purification using immobilized metal affinity chromatography (IMAC). This study assesses the use of Factor Xa and a genetically engineered exopeptidase dipeptidyl aminopeptidase-1 (DAPase-1) for the removal of C-terminus and N-terminus polyhistidine tags, respectively. Model proteins consisting of maltose binding protein (MBP) having a C- or N-terminal polyhistidine tag were used. Digestion of the hexahistidine tag of MBP-His(6) by Factor Xa and HT15-MBP by DAPase-1 was successful. The time taken to complete the conversion of MBP-His(6) to MBP was 16 h, as judged by SDS-PAGE and Western blots against anti-His antibody. When the detagged protein was purified using subtractive IMAC, the yield was moderate at 71% although the overall recovery was high at 95%. Likewise, a yield of 79% and a recovery of 97% was obtained when digestion was performed with using "on-column" tag digestion. On-column tag digestion involves cleavage of histidine tag from polyhistidine tagged proteins that are still bound to the IMAC column. Digestion of an N-terminal polyhistidine tag from HT15-MBP (1 mg/mL) by the DAPase-I system was superior to the results obtained with Factor Xa with a higher yield and recovery of 99% and 95%, respectively. The digestion by DAPase-I system was faster and was complete at 5 h as opposed to 16 h for Factor Xa. The detagged MBP proteins were isolated from the digestion mixtures using a simple subtractive IMAC column procedure with the detagged protein appearing in the flowthrough and washing fractions while residual dipeptides and DAPase-I (which was engineered to exhibit a poly-His tail) were adsorbed to the column. FPLC analysis using a MonoS cation exchanger was performed to understand and monitor the progress and time course of DAPase-I digestion of HT15-MBP to MBP. Optimization of process variables such as temperature, protein concentration, and enzyme activity was developed for the DAPase-I digesting system on HT15-MBP to MBP. In short, this study proved that the use of either Factor Xa or DAPase-I for the digestion of polyhistidine tags is simple and efficient and can be carried out under mild reaction conditions.

Development of a high-throughput screen for inhibitors of replication protein A and its role in nucleotide excision repair

The heterotrimeric protein, replication protein A (RPA), is essential for DNA repair and replication. RPA is a viable target in the treatment of cancer as many chemotherapeutic agents act by blocking DNA replication. Furthermore, inhibition of RPA could prove useful in treating cancers that have acquired resistance to DNA damaging agents through enhanced DNA repair mechanisms as has been observed with certain platinum-resistant carcinomas. In an effort to identify inhibitors of RPA, we employed a novel fluorescent reporter and established a homogeneous high-throughput screening assay to measure RPA's DNA binding activity. Using this assay, we have screened a collection of small molecules and determined the effect they have on the RPA-DNA interaction. Of the 2000 compounds screened, 79 scored positive for inhibition of RPA binding activity. Secondary screenings were performed using an electrophoretic mobility shift assay; of the 79 compounds, 9 scored positive and were further characterized in titration experiments to determine the most potent inhibitor, resulting in several compounds showing an IC50 in the low micromolar range. Fluorescence polarization analyses were also performed to determine the mechanism of inhibition for each compound. Validation of the inhibitory activity of selected compounds was verified using in vitro nucleotide excision repair (NER) catalyzed excision of a single cisplatin lesion in a duplex DNA. The identification and use of RPA inhibitors may aid in inhibiting NER activity that could potentially circumvent resistance to certain chemotherapeutic agents as well as be useful in the characterization of RPA and its interaction with DNA.

RPA phosphorylation in mitosis alters DNA binding and protein-protein interactions

The heterotrimeric DNA-binding protein, replication protein A (RPA), consists of 70-, 34-, and 14-kDa subunits and is involved in maintaining genomic stability by playing key roles in DNA replication, repair, and recombination. RPA participates in these processes through its interaction with other proteins and its strong affinity for single-stranded DNA (ssDNA). RPA-p34 is phosphorylated in a cell-cycle-dependent fashion primarily at Ser-29 and Ser-23, which are consensus sites for Cdc2 cyclin-dependent kinase. By systematically examining RPA-p34 phosphorylation throughout the cell cycle, we have found there are distinct phosphorylated forms of RPA-p34 in different cell-cycle stages. We have isolated and purified a unique phosphorylated form of RPA that is specifically associated with the mitotic phase of the cell cycle. The mitotic form of RPA (m-hRPA) shows no difference in ssDNA binding activity as compared with recombinant RPA (r-hRPA), yet binds less efficiently to double-stranded DNA (dsDNA). These data suggest that mitotic phosphorylation of RPA-p34 inhibits the destabilization of dsDNA by RPA complex, thereby decreasing the binding affinity for dsDNA. The m-hRPA also exhibits altered interactions with certain DNA replication and repair proteins. Using highly purified proteins, m-hRPA exhibited decreased binding to ATM, DNA pol alpha, and DNA-PK as compared to unphosphorylated recombinant RPA (r-hRPA). Dephosphorylation of m-hRPA was able to restore the interaction with each of these proteins. Interestingly, the interaction of RPA with XPA was not altered by RPA phosphorylation. These data suggest that phosphorylation of RPA-p34 plays an important role in regulating RPA functions in DNA metabolism by altering specific protein-protein interactions.

Dimerization of human XPA and formation of XPA2-RPA protein complex

XPA plays an important role in the DNA damage recognition during human nucleotide excision repair. Here we report that the XPA is a homodimer either in the free state or as a complex with human RPA in solution under normal conditions. The human XPA protein purified from baculovirus-infected sf21 insect cells has a molecular mass of 36 317 Da, as determined by mass spectroscopy. However, the apparent molecular mass of XPA determined by the native gel filtration chromatography was about 71 kDa, suggesting that XPA is a dimer. This observation was supported by a native PFO-PAGE and fluorescence spectroscopy analysis. XPA formed a dimer (XPA2) in a broad range of XPA and NaCl concentrations, and the dimerization was not due to the disulfide bond formation. Furthermore, a titration analysis of the binding of XPA to the human RPA indicated that it was the XPA2 that formed the complex with RPA. Finally, the difference between the mass spectrometric and the calculated masses of XPA implies that the protein contains posttranslational modifications. Taken together, our data suggest that the dimerization of XPA may play an important role in the DNA damage recognition of nucleotide excision repair.

Xeroderma pigmentosum complementation group A protein (XPA) modulates RPA-DNA interactions via enhanced complex stability and inhibition of strand separation activity

Replication protein A (RPA) participates in many cellular functions including DNA replication and nucleotide excision repair. A direct interaction between RPA and the xeroderma pigmentosum group A protein (XPA) facilitates the assembly of a preincision complex during the processing of DNA damage by the nucleotide excision repair pathway. We demonstrate here the formation of a ternary RPA, XPA, and duplex cisplatin-damaged DNA complex as is evident by electrophoretic supershift analysis. The RPA-XPA complex displays modest specificity for damaged versus undamaged duplex DNA, and the RPA-XPA complex displays a greater affinity for binding duplex cisplatin-damaged DNA when compared with the RPA or XPA proteins alone, consistent with previous results. Using DNA denaturation assays, we demonstrate that the role of XPA is in the stabilization of the duplex DNA structure via inhibition of the strand separation activity of RPA. Rapid kinetic analysis indicates that the bimolecular k(on) of the RPA-XPA complex is 2.5-fold faster than RPA alone for binding a duplex cisplatin-damaged DNA. The dissociation rate, k(off), of the RPA-XPA complex is slower than that of the RPA protein alone, suggesting that the XPA protein stabilizes the initial binding of RPA to duplex DNA as well as maintaining the integrity of the duplex DNA. Interestingly, XPA has no effect on the k(on) of RPA for a single-stranded 40-mer DNA.

Strand-specific binding of RPA and XPA to damaged duplex DNA

The nucleotide excision repair (NER) pathway is a major pathway used to repair bulky adduct DNA damage. Two proteins, xeroderma pigmentosum group A protein (XPA) and replication protein A (RPA), have been implicated in the role of DNA damage recognition in the NER pathway. The particular manner in which these two damage recognition proteins align themselves with respect to a damaged DNA site was assessed using photoreactive base analogues within specific DNA substrates to allow site-specific cross-linking of the damage recognition proteins. Results of these studies demonstrate that both RPA and XPA are in close proximity to the adduct as measured by cross-linking of each protein directly to the platinum moiety. Additional studies demonstrate that XPA contacts both the damaged and undamaged strands of the duplex DNA. Direct evidence is presented demonstrating preferential binding of RPA to the undamaged strand of a duplex damaged DNA molecule.

Applications of novel affinity cassette methods: use of peptide fusion handles for the purification of recombinant proteins

In this article, recent progress related to the use of different types of polypeptide fusion handles or 'tags' for the purification of recombinant proteins are critically discussed. In addition, novel aspects of the molecular cassette concept are elaborated, together with areas of potential application of these fundamental principles in molecular recognition. As evident from this review, the use of these concepts provides a powerful strategy for the high throughput isolation and purification of recombinant proteins and their derived domains, generated from functional genomic or zeomic studies, as part of the bioprocess technology leading to their commercial development, and in the study of molecular recognition phenomena per se. In addition, similar concepts can be exploited for high sensitivity analysis and detection, for the characterisation of protein bait/prey interactions at the molecular level, and for the immobilisation and directed orientation of proteins for use as biocatalysts/biosensors.

Cisplatin-DNA adducts inhibit translocation of the Ku subunits of DNA-PK

We have determined the effect of cisplatin-DNA damage on the ability of the DNA-dependent protein kinase (DNA-PK) to interact with duplex DNA molecules in vitro. The Ku DNA binding subunits of DNA-PK display a reduced ability to translocate on duplex DNA containing cisplatin-DNA adducts compared to control, undamaged duplex DNA. The decreased rates of translocation resulted in a decrease in the association of the p460 catalytic subunit of DNA-PK (DNA-PKcs) with the Ku-DNA complex. In addition to a decrease in DNA-PKcs association, the DNA-PKcs that is bound with Ku at a DNA end containing cisplatin-DNA adducts has a reduced catalytic rate compared to heterotrimeric DNA-PK assembled on undamaged DNA. The position of the cisplatin-DNA lesion from the terminus also effects kinase activation, with maximal inhibition occurring when the lesion is closer to the terminus. These results are consistent with a model for DNA-PK activation where the Ku dimer translocates away from the DNA terminus and facilitates the association of DNA-PKcs which interacts with both Ku and DNA resulting in kinase activation. The presence of cisplatin adducts decreases the ability to translocate away from the terminus and results in the formation of inactive kinase complexes at the DNA terminus. The results are discussed with respect to the ability of cisplatin to sensitize cells to DNA damage induced by ionizing radiation and the ability to repair DNA double-strand breaks.