XPA is susceptible to proteolytic cleavage by cathepsin L during lysis of quiescent cells.

The xeroderma pigmentosum group A (XPA) protein plays an essential role in the removal of UV photoproducts and other bulky lesions from DNA as a component of the nucleotide excision repair (NER) machinery. Using cell lysates prepared from confluent cultures of human cells and from human skin epidermis, we observed an additional XPA antibody-reactive band on immunoblots that was approximately 3-4 kDa smaller than the native, full-length XPA protein. Biochemical studies revealed this smaller molecular weight XPA species to be due to proteolysis at the C-terminus of the protein, which negatively impacted the ability of XPA to interact with the NER protein TFIIH. Further work identified the endopeptidase cathepsin L, which is expressed at higher levels in quiescent cells, as the protease responsible for cleaving XPA during cell lysis. These results suggest that supplementation of lysis buffers with inhibitors of cathepsin L is important to prevent cleavage of XPA during lysis of confluent cells.

Activation of multiple DNA repair pathways by sub-nuclear damage induction methods.

Live cell studies of DNA repair mechanisms are greatly enhanced by new developments in real-time visualization of repair factors in living cells. Combined with recent advances in local sub-nuclear DNA damage induction procedures these methods have yielded detailed information on the dynamics of damage recognition and repair. Here we analyze and discuss the various types of DNA damage induced in cells by three different local damage induction methods: pulsed 800 nm laser irradiation, Hoechst 33342 treatment combined with 405 nm laser irradiation and UV-C (266 nm) laser irradiation. A wide variety of damage was detected with the first two methods, including pyrimidine dimers and single- and double-strand breaks. However, many aspects of the cellular response to presensitization by Hoechst 33342 and subsequent 405 nm irradiation were aberrant from those to every other DNA damaging method described here or in the literature. Whereas, application of low-dose 266 nm laser irradiation induced only UV-specific DNA photo-lesions allowing the study of the UV-C-induced DNA damage response in a user-defined area in cultured cells.

Crosslinking of the NER damage recognition proteins XPC-HR23B, XPA and RPA to photoreactive probes that mimic DNA damages.

A new assay to probe the mechanism of mammalian nucleotide excision repair (NER) was developed. Photoreactive arylazido analogues of dNMP in DNA were shown to be substrates for the human NER system. Oligonucleotides carrying photoreactive "damages" were prepared using the multi-stage protocol including one-nucleotide gap filling by DNA polymerase beta using photoreactive dCTP or dUTP analogues followed by ligation of the resulting nick. Photoreactive 60-mers were annealed with single-stranded pBluescript II SK (+) and subsequently primer extension reactions were performed. Incubation of HeLa extracts with the plasmids containing photoreactive moieties resulted in an excision pattern typical of NER. DNA duplexes containing photoreactive analogues were used to analyze the interaction of XPC-HR23B, RPA, and XPA with damaged DNA using the photocrosslinking assay. Crosslinking of the XPC-HR23B complex with photoreactive 60-mers resulted in modification of its XPC subunit. RPA crosslinked to ssDNA or mismatched dsDNA more efficiently than to dsDNA, whereas XPA did not show a preference for any of the DNA species. XPC and XPA photocrosslinking to DNA decreased in the presence of Mg(2+) whereas RPA crosslinking to DNA was not sensitive to this cofactor. Our data establish a photocrosslinking assay for the investigation of the damage recognition step in human nucleotide excision repair.

Purification and characterization of Escherichia coli and human nucleotide excision repair enzyme systems.

Nucleotide excision repair is a multicomponent, multistep enzymatic system that removes a wide spectrum of DNA damage by dual incisions in the damaged strand on both sides of the lesion. The basic steps are damage recognition, dual incisions, resynthesis to replace the excised DNA, and ligation. Each step has been studied in vitro using cell extracts or highly purified repair factors and radiolabeled DNA of known sequence with DNA damage at a defined site. This chapter describes procedures for preparation of DNA substrates designed for analysis of damage recognition, either the 5' or the 3' incision event, excision (resulting from concerted dual incisions), and repair synthesis. Excision in Escherichia coli is accomplished by the three-subunit Uvr(A)BC excision nuclease and in humans by six repair factors: XPA, RPA, XPChR23B, TFIIH, XPFERCC1, and XPG. This chapter outlines methods for expression and purification of these essential repair factors and provides protocols for performing each of the in vitro repair assays with either the E. coli or the human excision nuclease.