Hanspeter Naegeli

Recognition of DNA adducts by human nucleotide excision repair. Evidence for a thermodynamic probing mechanism.

The mechanism by which mammalian nucleotide excision repair (NER) detects a wide range of base lesions is poorly understood. Here, we tested the ability of human NER to recognize bulky modifications that either destabilize the DNA double helix (acetylaminofluorene (AAF) and benzo[a]pyrene diol-epoxide (BPDE) adducts, UV radiation products) or induce opposite effects by stabilizing the double helix (8-methoxypsoralen (8-MOP), anthramycin, and CC-1065 adducts). We constructed plasmid DNA carrying a defined number of each of these adducts and determined their potential to sequester NER factors contained in a human cell-free extract. For that purpose, we measured the capacity of damaged plasmids to compete with excision repair of a site-directed NER substrate. This novel approach showed differences of more than 3 orders of magnitude in the efficiency by which helix-destabilizing and helix-stabilizing adducts sequester NER factors. For example, AAF modifications were able to compete with the NER substrate ∼1740 times more effectively than 8-MOP adducts. The sequestration potency decreased with the following order of adducts, AAF > UV ≥ BPDE > 8-MOP > anthramycin, CC-1065. A strong preference for helix-destabilizing lesions was confirmed by monitoring the formation of NER patches at site-specific adducts with either AAF or CC-1065. This comparison based on factor sequestration and repair synthesis indicates that human NER is primarily targeted to sites at which the secondary structure of DNA is destabilized. Thus, an early step of DNA damage recognition involves thermodynamic probing of the duplex.

Double‐check probing of DNA bending and unwinding by XPA–RPA: an architectural function in DNA repair

The multiprotein factor composed of XPA and replication protein A (RPA) is an essential subunit of the mammalian nucleotide excision repair system. Although XPA–RPA has been implicated in damage recognition, its activity in the DNA repair pathway remains controversial. By replacing DNA adducts with mispaired bases or non‐hybridizing analogues, we found that the weak preference of XPA and RPA for damaged substrates is entirely mediated by indirect readout of DNA helix conformations. Further screening with artificially distorted substrates revealed that XPA binds most efficiently to rigidly bent duplexes but not to single‐stranded DNA. Conversely, RPA recognizes single‐stranded sites but not backbone bending. Thus, the association of XPA with RPA generates a double‐check sensor that detects, simultaneously, backbone and base pair distortion of DNA. The affinity of XPA for sharply bent duplexes, characteristic of architectural proteins, is not compatible with a direct function during recognition of nucleotide lesions. Instead, XPA in conjunction with RPA may constitute a regulatory factor that monitors DNA bending and unwinding to verify the damage‐specific localization of repair complexes or control their correct three‐dimensional assembly.

Base pair conformation-dependent excision of benzo[a]pyrene diol epoxide-guanine adducts by human nucleotide excision repair enzymes.

Human nucleotide excision repair processes carcinogen-DNA adducts at highly variable rates, even at adjacent sites along individual genes. Here, we identify conformational determinants of fast or slow repair by testing excision of N2-guanine adducts formed by benzo[a]pyrene diol epoxide (BPDE), a potent and ubiquitous mutagen that induces mainly G x C-->T x A transversions and frameshift deletions. We found that human nucleotide excision repair processes the predominant (+)-trans-BPDE-N2-dG adduct 15 times less efficiently than a standard acetylaminofluorene-C8-dG lesion in the same sequence. No difference was observed between (+)-trans- and (-)-trans-BPDE-N2-dG, but excision was enhanced about 10-fold by changing the adduct configurations to either (+)-cis- or (-)-cis-BPDE-N2-dG. Conversely, excision of (+)-cis- and (-)-cis- but not (+)-trans-BPDE-N2-dG was reduced about 10-fold when the complementary cytosine was replaced by adenine, and excision of these BPDE lesions was essentially abolished when the complementary deoxyribonucleotide was missing. Thus, a set of chemically identical BPDE adducts yielded a greater-than-100-fold range of repair rates, demonstrating that nucleotide excision repair activity is entirely dictated by local DNA conformation. In particular, this unique comparison between structurally highly defined substrates shows that fast excision of BPDE-N2-dG lesions is correlated with displacement of both the modified guanine and its partner base in the complementary strand from their normal intrahelical positions. The very slow excision of carcinogen-DNA adducts located opposite deletion sites reveals a cellular strategy that minimizes the fixation of frameshifts after mutagenic translesion synthesis.

Thermodynamic and structural factors in the removal of bulky DNA adducts by the nucleotide excision repair machinery

The function of the human nucleotide excision repair (NER) apparatus is to remove bulky adducts from damaged DNA. In an effort to gain insights into the molecular mechanisms involved in the recognition and excision of bulky lesions, we investigated a series of site specifically modified oligonucleotides containing single, well‐defined polycyclic aromatic hydrocarbon (PAH) diol epoxide‐adenine adducts. Covalent adducts derived from the bay region PAH, benzo[a]pyrene, are removed by human NER enzymes in vitro. In contrast, the stereochemically analogous N6‐dA adducts derived from the topologically different fjord region PAH, benzo[c]phenanthrene, are resistant to repair. The evasion of DNA repair may play a role in the observed higher tumorigenicity of the fjord region PAH diol epoxides. We are elucidating the structural and thermodynamic features of these adducts that may underlie their marked distinction in biologic function, employing high‐resolution nuclear magnetic resonance studies, measurements of thermal stabilities of the PAH diol epoxide‐modified oligonucleotide duplexes, and molecular dynamics simulations with free energy calculations. Our combined findings suggest that differences in the thermodynamic properties and thermal stabilities are associated with differences in distortions to the DNA induced by the lesions. These structural effects correlate with the differential NER susceptibilities and stem from the intrinsically distinct shapes of the fjord and bay region PAH diol epoxide‐N6‐adenine adducts.

The xeroderma pigmentosum pathway: decision tree analysis of DNA quality.

The nucleotide excision repair (NER) system is a fundamental cellular stress response that uses only a handful of DNA binding factors, mutated in the cancer-prone syndrome xeroderma pigmentosum (XP), to detect an astounding diversity of bulky base lesions, including those induced by ultraviolet light, electrophilic chemicals, oxygen radicals and further genetic insults. Several of these XP proteins are characterized by a mediocre preference for damaged substrates over the native double helix but, intriguingly, none of them recognizes injured bases with sufficient selectivity to account for the very high precision of bulky lesion excision. Instead, substrate versatility as well as damage specificity and strand selectivity are achieved by a multistage quality control strategy whereby different subunits of the XP pathway, in succession, interrogate the DNA double helix for a distinct abnormality in its structural or dynamic parameters. Through this step-by-step filtering procedure, the XP proteins operate like a systematic decision making tool, generally known as decision tree analysis, to sort out rare damaged bases embedded in a vast excess of native DNA. The present review is focused on the mechanisms by which multiple XP subunits of the NER pathway contribute to the proposed decision tree analysis of DNA quality in eukaryotic cells.

Recognition of helical kinks by xeroderma pigmentosum group A protein triggers DNA excision repair

The function of human XPA protein, a key subunit of the nucleotide excision repair pathway, has been examined with site-directed substitutions in its putative DNA-binding cleft. After screening for repair activity in a host-cell reactivation assay, we analyzed mutants by comparing their affinities for different substrate architectures, including DNA junctions that provide a surrogate for distorted reaction intermediates, and by testing their ability to recruit the downstream endonuclease partner. Normal repair proficiency was retained when XPA mutations abolished only the simple interaction with linear DNA molecules. By contrast, results from a K141E K179E double mutant revealed that excision is crucially dependent on the assembly of XPA protein with a sharp bending angle in the DNA substrate. These findings show how an increased deformability of damaged sites, leading to helical kinks recognized by XPA, contributes to target selectivity in DNA repair.

Biliary excretion of biochemically active cyanobacteria (blue-green algae) hepatotoxins in fish

Previous reports demonstrated that microcystin and related cyanobacteria polypeptides are rapidly cleared from plasma and accumulate in liver tissue. In the present study, we have used their ability to inhibit protein phosphatases to show that these cyanobacteria hepatotoxins are excreted into the bile of experimentally poisoned rainbow trout. At various times after oral administration of hepatotoxic Microcystis aeruginosa, bile samples were analysed for microcystin content by methanol extraction and protein phosphatase assays. An inhibitory principle that specifically suppressed protein phosphatase activity was detected in all bile samples removed between 1 and 72 h after oral exposure to toxic algae. These results indicate that biochemically active microcystin molecules are excreted into the biliary tract of poisoned fish.

An Aromatic Sensor with Aversion to Damaged Strands Confers Versatility to DNA Repair

It was not known how xeroderma pigmentosum group C (XPC) protein, the primary initiator of global nucleotide excision repair, achieves its outstanding substrate versatility. Here, we analyzed the molecular pathology of a unique Trp690Ser substitution, which is the only reported missense mutation in xeroderma patients mapping to the evolutionary conserved region of XPC protein. The function of this critical residue and neighboring conserved aromatics was tested by site-directed mutagenesis followed by screening for excision activity and DNA binding. This comparison demonstrated that Trp690 and Phe733 drive the preferential recruitment of XPC protein to repair substrates by mediating an exquisite affinity for single-stranded sites. Such a dual deployment of aromatic side chains is the distinctive feature of functional oligonucleotide/oligosaccharide-binding folds and, indeed, sequence homologies with replication protein A and breast cancer susceptibility 2 protein indicate that XPC displays a monomeric variant of this recurrent interaction motif. An aversion to associate with damaged oligonucleotides implies that XPC protein avoids direct contacts with base adducts. These results reveal for the first time, to our knowledge, an entirely inverted mechanism of substrate recognition that relies on the detection of single-stranded configurations in the undamaged complementary sequence of the double helix.

Strand- and site-specific DNA lesion demarcation by the xeroderma pigmentosum group D helicase.

The most detrimental responses of the UV-exposed skin are triggered by cyclobutane pyrimidine dimers (CPDs). Although placental mammals rely solely on nucleotide excision repair (NER) to eliminate CPDs, none of the core NER factors are apparently able to distinguish this hazardous lesion from native DNA, raising the question of how CPDs are circumscribed to define correct excision boundaries. A key NER intermediate involves unwinding of the damaged duplex by transcription factor TFIIH, a reaction that requires xeroderma pigmentosum group D (XPD) protein. This study was prompted by the observation that the ATPase/helicase activity of XPD is necessary for an effective anchoring of this subunit to UV lesions in mammalian nuclei. The underlying mechanism by which XPD impinges on damaged DNA has been probed with a monomeric archaeal homolog, thus revealing that the collision with a single CPD inhibits the helicase but stimulates its ATPase activity. Restriction and glycosylase protection assays show that the XPD helicase remains firmly bound to a CPD situated in the translocated strand along which the enzyme moves with 5′–3′ polarity. Competition assays confirm that a stable complex is formed when the XPD helicase encounters a CPD in the translocated strand. Instead, the enzyme dissociates from the substrate after running into a CPD in the complementary 3′–5′ strand. These results disclose a damage verification and demarcation process that takes place by strand-selective immobilization of the XPD helicase and its conversion to a site-specific ATPase at DNA lesions.

HISTONE SHUTTLING BY POLY ADP-RIBOSYLATION

The enzymes poly(ADP-ribose)polymerase and poly(ADP-ribose) glycohydrolase may cooperate to drive a histone shuttle mechanism in chromatin. The mechanism is triggered by binding of the N-terminal zinc-finger domain of the polymerase to DNA strand breaks, which activates the catalytic activities residing in the C-terminal domain. The polymerase converts into a protein carrying multiple ADP-ribose polymers which displace histones from DNA by specifically targeting the histone tails responsible for DNA condensation. As a result, the domains surrounding DNA strand breaks become accessible to other proteins. Poly(ADP0ribose) glycohydrolase attacks ADP-ribose polymers in a specific order and thereby releases histones for reassociation with DNA. Increasing evidence from different model systems suggests that histone shuttling participates in DNA repairin vivo as a catalyst for nucleosomal unfolding.