Microinjected photoreactivating enzymes from Anacystis and Saccharomyces monomerize dimers in chromatin of human cells

UV Protection in the Cornea: Failure and Rescue

Simple Summary

The sun is a deadly laser, and its damaging rays harm exposed tissues such as our skin and eyes. The skin’s protection and repair mechanisms are well understood and utilized in therapeutic approaches while the eye lacks such complete understanding of its defenses and therefore often lacks therapeutic support in most cases. The aim here was to document the similarities and differences between the two tissues as well as understand where current research stands on ocular, particularly corneal, ultraviolet protection. The objective is to identify what mechanisms may be best suited for future investigation and valuable therapeutic approaches.

Abstract

Ultraviolet (UV) irradiation induces DNA lesions in all directly exposed tissues. In the human body, two tissues are chronically exposed to UV: the skin and the cornea. The most frequent UV-induced DNA lesions are cyclobutane pyrimidine dimers (CPDs) that can lead to apoptosis or induce tumorigenesis. Lacking the protective pigmentation of the skin, the transparent cornea is particularly dependent on nucleotide excision repair (NER) to remove UV-induced DNA lesions. The DNA damage response also triggers intracellular autophagy mechanisms to remove damaged material in the cornea; these mechanisms are poorly understood despite their noted involvement in UV-related diseases. Therapeutic solutions involving xenogenic DNA-repair enzymes such as T4 endonuclease V or photolyases exist and are widely distributed for dermatological use. The corneal field lacks a similar set of tools to address DNA-lesions in photovulnerable patients, such as those with genetic disorders or recently transplanted tissue.

50 years thymine dimer

Fifty years ago thymine dimer was discovered in the Biochemical and Biophysical Laboratory of Delft Technological University, The Netherlands, by one of the authors of this review (Beukers) as the first environmentally induced DNA lesion. It is one of the photoproducts formed between adjacent pyrimidine bases in DNA by UV irradiation, currently known as cyclobutane pyrimidine dimers (CPDs) and (6-4) photoproducts. Major lesions found in DNA after in vitro or in vivo UV irradiation are the cis-syn cyclobutane thymine dimer and the thymine-cytosine (6-4) photoproduct. Even after 50 years the study of photo-induced DNA lesions is still going on as is illustrated by the hundreds of papers published every year and the millions hits when browsing the internet for dimer-related information. Living organisms possess efficient and different mechanisms to repair detrimental lesions in their DNA. A unique mechanism to repair CPDs is reversion by either direct interaction with light of short wavelength or by enzymatic photoreactivation. Photophysical mechanisms that induce and reverse molecular bonds in biological macromolecules have been a main focus of research of the group in Delft in the middle of the last century. This review describes the break-through results of these studies which were the result of intense interactions between scientists in the fields of physics, organic chemistry and biochemistry. Philosophically, the "view" of the group in Delft was very appealing: since in nature photolesions are induced in DNA by the sun, how is it possible that repair of these lesions could be accomplished by the same energy source. Evolutionary, it is hardly possible to think of a more efficient repair mechanism.

Enhanced repair of cyclobutane pyrimidine dimers and improved UV resistance in photolyase transgenic mice

During evolution, placental mammals appear to have lost cyclobutane pyrimidine dimer (CPD) photolyase, an enzyme that efficiently removes UV-induced CPDs from DNA in a light-dependent manner. As a consequence, they have to rely solely on the more complex, and for this lesion less efficient, nucleotide excision repair pathway. To assess the contribution of poor repair of CPDs to various biological effects of UV, we generated mice expressing a marsupial CPD photolyase transgene. Expression from the ubiquitous beta-actin promoter allowed rapid repair of CPDs in epidermis and dermis. UV-exposed cultured dermal fibroblasts from these mice displayed superior survival when treated with photoreactivating light. Moreover, photoreactivation of CPDs in intact skin dramatically reduced acute UV effects like erythema (sunburn), hyperplasia and apoptosis. Mice expressing the photolyase from keratin 14 promoter photo reactivate CPDs in basal and early differentiating keratinocytes only. Strikingly, in these animals, the anti-apoptotic effect appears to extend to other skin compartments, suggesting the presence of intercellular apoptotic signals. Thus, providing mice with CPD photolyase significantly improves repair and uncovers the biological effects of CPD lesions.

Chromatin structure modulates DNA repair by photolyase in vivo

Yeast and many other organisms use nucleotide excision repair (NER) and photolyase in the presence of light (photoreactivation) to repair cyclobutane pyrimidine dimers (CPDs), a major class of DNA lesions generated by UV light. To study the role of photoreactivation at the chromatin level in vivo, we used yeast strains which contained minichromosomes (YRpTRURAP, YRpCS1) with well-characterized chromatin structures. The strains were either proficient (RAD1) or deficient (rad1 delta) in NER. In contrast to NER, photolyase rapidly repairs CPDs in non-nucleosomal regions, including promoters of active genes (URA3, HIS3, DED1) and in linker DNA between nucleosomes. CPDs in nucleosomes are much more resistant to photoreactivation. These results demonstrate a direct role of chromatin in modulation of a DNA repair process and an important role of photolyase in repair of damaged promoters with presumptive effects on gene regulation. In addition, photoreactivation provides an in vivo test for chromatin structure and stability. In active genes (URA3, HIS3), photolyase repairs the non-transcribed strand faster than the transcribed strand and can match fast removal of lesions from the transcribed strand by NER (transcription-coupled repair). Thus, the combination of both repair pathways ensures efficient repair of active genes.

Use of in vivo and in vitro assays for the characterization of mammalian excision repair and isolation of repair proteins

Elucidation of the molecular mechanism of mammalian nucleotide excision repair requires the availability of purified proteins, DNA substrates with defined lesions and suitable repair assays. Repair assays introduced in recent years vary from testing individual steps and successions of steps in vitro to systems that closely reflect the entire process in vivo. In the first part of this review, an in vivo microinjection system is discussed. The second part of the article reviews an in vitro system for study of repair synthesis promoted by cell extracts. Both systems can be utilized as assays during the purification of protein factors that complement repair-defective xeroderma pigmentosum cells. The effect of purified repair proteins from other organisms on mammalian repair is also considered.

Cloning and characterization of a photolyase gene from the cyanobacterium Anacystis nidulans

A 2 kb fragment was isolated from an Anacystis nidulans genomic DNA library by hybridization with synthetic oligonucleotide probes derived from the N-terminal amino acid sequence of Anacystis photolyase. This fragment contains a 1452 bp-long open reading frame encoding a polypeptide of 484 amino acids (Mr 54475). Antibodies raised against purified Anacystis photolyase reacted with extracts of cells harboring fused genes between lacZ of Escherichia coli and this gene. A 40.7% similarity was found between the deduced amino acid sequences of Anacystis and E. coli photolyases, notwithstanding the difference in chromophore structure.

Evaluation of homology between cloned Escherichia coli and yeast DNA photolyase genes and higher eukaryotic genomes

Repair of ultraviolet-induced pyrimidine dimers by photoreactivation is catalyzed by a single enzyme, DNA photolyase. However, the process of photoreactivation is difficult to detect reproducibly in cultured mammalian cells. We have used clones containing yeast and Escherichia coli DNA photolyase genes to determine whether their sequences are conserved and whether there is homology between either cloned sequence and chick or human genomic DNA and mRNA sequences. The cloned sequences failed to hybridize to each other even under nonstringent conditions, indicating little conservation of sequence between the yeast and E. coli genes. Furthermore, only weak hybridization under nonstringent conditions was found between the cloned photoreactivating genes and human or chick genomic DNA or mRNA. This indicates that there is negligible homology between the cloned probes and mammalian DNA, but we are unable to conclude whether this indicates sequence divergence for prokaryotic and eukaryotic photoreactivation genes or the absence of such genes from the mammalian genome.

The use of recombinant DNA techniques to study radiation-induced damage, repair and genetic change in mammalian cells

A brief Introduction is given to appropriate elements of recombinant DNA techniques and applications to problems in radiobiology are reviewed with illustrative detail. Examples are included of studies with both 254 nm ultraviolet light (u.v.) and ionizing radiation (i.r.) and the review progresses from the molecular analysis of DNA damage in vitro through to the nature of consequent cellular responses. The section on the Molecular distribution of DNA damage (section 2) focuses on the use of defined DNA molecules to assess the nature, sites and frequency of radiation damage. Recombinant DNA techniques have also been used in the study of enzyme-DNA interactions, to comment upon the rôle of specific types and sites of damage in producing cellular responses. The use of DNA-mediated gene transfer to assess damage and repair (section 3) indicates that recombinant DNA molecules can be used to implicate (or reject) specific types of DNA damage in gene inactivation. Some gene-transfer assays may also be able to confirm the presence of specific repair functions in mammalian cells. Restriction endonucleases are essential for the construction of recombinant DNA molecules, but their ability to cut DNA at specific sequences is also being exploited to implicate the double-strand break as an important type of damage leading to the well-characterized responses of irradiated cells. The DNA double strand break: use of restriction endonucleases to model radiation damage (section 4) documents experiments showing that blunt-ended cuts introduced into cellular DNA are able to produce chromosome aberrations and cell death. Assays based upon the introduction of restriction endonuclease-cut plasmids into radiosensitive and normal cells suggest that sensitivity is in some instances, e.g. the radiosensitive disorder ataxia-telangiectasia, a result of excessive degradation of DNA around broken ends. Identification and cloning of DNA repair genes (section 5) reviews the successful cloning of one human repair gene and the putative identification of others, as well as the lack of success in identifying genes complementing radiosensitive human disorders. Analysis of radiation-induced genetic change (section 6) links the types of DNA damage observed in defined DNA molecules with the types of mutations occurring in irradiated prokaryotes. In mammalian cells recombinant DNA techniques have allowed the nature of mutational changes to be determined for the first time: to date it seems that u.v. produces mainly small (point) mutations while i.r. produces mainly large changes (deletions/rearrangements).(ABSTRACT TRUNCATED AT 400 WORDS)

Microinjection of Escherichia coli UvrA, B, C and D proteins into fibroblasts of xeroderma pigmentosum complementation groups A and C does not result in restoration of UV-induced unscheduled DNA synthesis

The UV-induced unscheduled DNA synthesis (UDS) in cultured human fibroblasts of repair-deficient xeroderma pigmentosum complementation groups A and C was assayed after injection of identical activities of either Uvr excinuclease (UvrA, B, C and D) from Escherichia coli or endonuclease V from phage T4. Under conditions where the T4 enzyme was able to induce repair synthesis in both XP complementation groups in agreement with earlier observations (de Jonge et al., 1985), no effect of the UvrABCD excinuclease could be observed either when the enzymatic complex was injected into the cytoplasm, or when it was delivered directly into the nucleus. In addition, no effect of the E. coli excinuclease was found on the repair ability of normal repair-proficient human fibroblasts. We conclude that the UvrABCD excinuclease may not work on DNA lesions in human chromatin.

Unscheduled DNA synthesis in xeroderma pigmentosum cells after microinjection of yeast photoreactivating enzyme

Photoreactivating enzyme (PRE) from yeast causes a light-dependent reduction of UV-induced unscheduled DNA synthesis (UDS) when injected into the cytoplasm of repair-proficient human fibroblasts (Zwetsloot et al., 1985). This result indicates that the exogenous PRE monomerizes UV-induced dimers in these cells competing with the endogenous excision repair. In this paper we present the results of the injection of yeast PRE on (residual) UDS in fibroblasts from different excision-deficient XP-strains representing complementation groups A, C, D, E, F, H and I (all displaying more than 10% of the UDS of wild-type cells) and in fibroblasts from two excision-proficient XP-variant strains. In fibroblasts belonging to complementation groups C, F and I and in fibroblasts from the XP-variant strains UDS was significantly reduced, indicating that pyrimidine dimers in these cells are accessible to and can be monomerized by the injected yeast PRE. The UDS reduction in the XP-variant strains is comparable with the effect in wild-type cells. In cells from complementation groups C, F and I the reduction is less than in wild-type and XP-variant cells. Fibroblasts belonging to groups A, D, E and H did not show any reduction in UDS level after PRE injection and illumination with photoreactivating light. These results give evidence that the genetic repair defect in some XP-strains is probably due to an altered accessibility of the UV-damaged sites.

Sequence of the Saccharomyces cerevisiae PHR1 gene and homology of the PHR1 photolyase to E. coli photolyase

The nucleotide sequence of a 2301 base pair region of Saccharomyces cerevisiae DNA containing the PHR1 gene is reported. Within this region a single open reading frame of 1695 base pairs was found; using the insertional inactivation technique it was shown that part or all of this open reading frame specifies the PHR1-encoded photolyase. The amino acid sequence of the 565 amino acid long polypeptide predicted from the PHR1 nucleotide sequence was compared to the amino acid sequence of E. coli photolyase. Overall the sequence homology was 36.5%; however, two short regions near the amino terminus as well as the carboxy-terminal 150 amino acids display significantly greater sequence homology. The presence of these strongly conserved regions suggests that the yeast and E. coli photolyase possess common structural and functional domains involved in substrate and/or chromophore binding.