DNA损伤谱的模拟和分析

电离辐射可以导致DNA的简单损伤或复杂损伤。复杂损伤可能引起细胞的死亡和基因突变,损伤的复杂程度对DNA的修复有很大的影响。研究DNA损伤谱对于细胞的修复、凋亡以及放射治疗等有重要意义。利用国际上现有的少量DNA损伤谱的计算结果,用一个简单模拟电离辐射致DNA损伤谱的算法模拟计算并分析了DNA损伤谱,分别给出了电子、质子和a粒子的参数,再现了径迹结构计算的结果。     

Attempted base excision repair of ionizing radiation damage in human lymphoblastoid cells produces lethal and mutagenic double strand breaks

A significant proportion of cellular DNA damages induced by ionizing radiation are produced in clusters, also called multiply damaged sites. It has been demonstrated by in vitro studies and in bacteria that clustered damage sites can be converted to lethal double strand breaks by oxidative DNA glycosylases during attempted base excision repair. To determine whether DNA glycosylases could produce double strand breaks at radiation-induced clustered damages in human cells, stably transformed human lymphoblastoid TK6 cells that inducibly overexpress the oxidative DNA glycosylases/AP lyases, hNTH1 and hOGG1, were assessed for their radiation responses, including survival, mutation induction and the enzymatic production of double strand breaks post-irradiation. We found that additional double strand breaks were generated during post-irradiation incubation in uninduced TK6 control cells. Moreover, overproduction of either DNA glycosylase resulted in significantly increased double strand break formation, which correlated with an elevated sensitivity to the cytotoxic and mutagenic effects of ionizing radiation. These data show that attempted repair of radiation damage, presumably at clustered damage sites, by the oxidative DNA glycosylases can lead to the formation of potentially lethal and mutagenic double strand breaks in human cells.     

Monte carlo simulation of base and nucleotide excision repair of clustered DNA damage sites. II. Comparisons of model predictions to measured data

Clustered damage sites other than double-strand breaks (DSBs) have the potential to contribute to deleterious effects of ionizing radiation, such as cell killing and mutagenesis. In the companion article (Semenenko et al., Radiat. Res. 164, 180-193, 2005), a general Monte Carlo framework to simulate key steps in the base and nucleotide excision repair of DNA damage other than DSBs is proposed. In this article, model predictions are compared to measured data for selected low-and high-LET radiations. The Monte Carlo model reproduces experimental observations for the formation of enzymatic DSBs in Escherichia coli and cells of two Chinese hamster cell lines (V79 and xrs5). Comparisons of model predictions with experimental values for low-LET radiation suggest that an inhibition of DNA backbone incision at the sites of base damage by opposing strand breaks is active over longer distances between the damaged base and the strand break in hamster cells (8 bp) compared to E. coli (3 bp). Model estimates for the induction of point mutations in the human hypoxanthine guanine phosphoribosyl transferase (HPRT) gene by ionizing radiation are of the same order of magnitude as the measured mutation frequencies. Trends in the mutation frequency for low- and high-LET radiation are predicted correctly by the model. The agreement between selected experimental data sets and simulation results provides some confidence in postulated mechanisms for excision repair of DNA damage other than DSBs and suggests that the proposed Monte Carlo scheme is useful for predicting repair outcomes.     

Saccharomyces cerevisiae-based system for studying clustered DNA damages

DNA-damaging agents can induce clustered lesions or multiply damaged sites (MDSs) on the same or opposing DNA strands. In the latter, attempts to repair MDS can generate closely opposed single-strand break intermediates that may convert non-lethal or mutagenic base damage into double-strand breaks (DSBs). We constructed a diploid S. cerevisiae yeast strain with a chromosomal context targeted by integrative DNA fragments carrying different damages to determine whether closely opposed base damages are converted to DSBs following the outcomes of the homologous recombination repair pathway. As a model of MDS, we studied clustered uracil DNA damages with a known location and a defined distance separating the lesions. The system we describe might well be extended to assessing the repair of MDSs with different compositions, and to most of the complex DNA lesions induced by physical and chemical agents.     

A new calculation on spectrum of direct DNA damage induced by low-energy electrons

In this work, direct DNA damage induced by low-energy electrons (<5 keV) is simulated using Monte Carlo methods, and the resulting yield of various strand breaks and base damages in cellular environment is presented. The simulation is based on a new inelastic cross section for the production of electron track structure in liquid water, and on ionization cross sections of DNA bases to generate base radical. Especially, a systematic approach of simulating detailed base damage is suggested. This approach includes improvement of a volume model of DNA, generation of the DNA base sequence, conversion of ionization events in liquid water at hit site to the ionization interaction of electrons with DNA bases and development of an algorithm to convert a base radical to a damage. The results obtained in terms of strand breaks are compared with those of experiments and other theoretical calculations, and good agreement was obtained. The yield of detailed base damages and clustered DNA damages caused by the combination of various strand breaks and base damages is presented, and the corresponding distribution characteristics are analyzed. The influence of the relative content of base pairs A-T and G-C in a DNA segment on the yield of both strand breaks and base damages is also explored. The present work provides fundamental information on DNA damage and represents the first effort toward the goal of obtaining the spectrum of clustered DNA damage including detailed base damages, for the mechanistic interpretation and prediction of radiation effects.     

Induction of homologous recombination in the hprt gene of V79 Chinese hamster cells in response to low- and high-LET irradiation

Dense ionization tracks from high linear energy transfer (LET) radiations form multiple damaged sites (MDS), which involve several types of DNA lesions in close vicinity. The primary DNA damage triggers sensor proteins that activate repair processes, cell cycle control or eventually apoptosis in subsequent cellular responses. The question how homologous recombination (HR) and non-homologous end joining (NHEJ) interact in the repair of radiation-induced DNA damage of MDS type has been addressed in different model systems but several questions remain to be answered. We have therefore challenged cells with treatments of ionizing radiation of different qualities to investigate whether primary DNA damages of different complexity are reflected in the processes of repair by HR as well as cell survival. We used the V79 derived SPD8 cell line to determine the induction of HR in the hprt exon 7 and clonogenic assay for survival in response to radiation. SPD8 cells were irradiated with gamma-rays (137Cs 0.5 keV/microm), boron ions (40 and 80 keV/microm) and nitrogen ions (140 keV/microm), with doses up to 5 Gy. Analysis of clonogenic survival showed that B-ions (80 keV/microm) and N-ions were more toxic than gamma-rays, 4.1 and 5.0 times respectively, while B-ions at 40 keV/microm were 2.0 times as toxic as gamma-rays. Homologous recombination in the cells exposed to B-ions (80 keV/microm) increased 2.9 times, a significant response as compared to cells exposed to gamma-rays, while for B-ions (40 keV/microm) and N-ions a nonsignificant increase in HR of 1.2 and 1.4, respectively, was observed. We hypothesize that the high-LET generated formation of MDS is responsible for the enhanced cytotoxicity as well as for the mobilization of the HR machinery.     

DNA repair of clustered uracils in HeLa cells

Two or more base damages, abasic sites or single-strand breaks (SSBs) within two helical turns of the DNA form a multiply damaged site (MDS) or clustered lesion. Studies in vitro and in bacteria indicate that attempts to repair two closely opposed base lesions can potentially form a lethal double-strand break (DSB). Ionizing radiation and chemotherapeutic agents introduce complex lesions, and the inability of a cell to repair MDSs is believed to contribute to the lethality of these treatments. The goal of this work was to extend the in vitro studies by examining MDS repair in mammalian cells under physiological conditions. Here, two opposing uracil residues separated by 3, 5, 7, 13 or 29 base-pairs were chosen as model DNA lesions. Double-stranded oligonucleotides containing no damage, a single uracil residue or the MDS were introduced into a non-replicating mammalian construct within the firefly luciferase open reading frame, or at the 5' or 3' end of the luciferase expression cassette. Following transient transfection into HeLa cells, luciferase activity was measured or plasmid DNA was re-isolated from the cells. Formation of a DSB was expected to decrease luciferase expression. However, certain single uracil residues as well as the MDSs decreased luciferase activity, which suggested that the reduction in activity was not due to DSB formation. In fact, Southern analysis of the re-isolated plasmid did not show the presence of linear DNA and demonstrated that none of the constructs was destroyed during repair. Further analysis of the re-isolated DNA demonstrated that only a small percentage of molecules originally carrying a single lesion or an MDS contained deletions. This work indicates that the majority of the clustered lesions were not converted to DSBs and that repair systems in mammalian cells may have established mechanisms to avoid the accumulation of SSB-repair intermediates.     

Low efficiency of repair of critical DNA damage induced by low doses of radiation

This study provides an analysis of the development of cellular response to the critical DNA damage and the mechanisms for limiting the efficiency of repairing such damages induced by low doses of ionizing radiation exposure. Based on the data of many studies, one can conclude that the majority of damages occurring in the DNA of the cells after exposure to ionizing radiation significantly differ in their chemical nature from the endogenous ones. The most important characteristic of radiation-induced DNA damages is their complexity and clustering. Double strand breaks, interstrand crosslinks or destruction of the replication fork and formation of long single-stranded gaps in DNA are considered to be critical damages for the fate of cells. The occurrence of such lesions in DNA may be a key event in the etiology and the therapy of cancer. The appearance in the cells of the critical DNA damage induces a rapid development of a complex and ramified network of molecular and biochemical reactions which are called the cellular response to DNA damage. Induction of the cellular response to DNA damage involves the activation of the systems of cell cycle checkpoints, DNA repair, changes in the expression of many genes, reconstruction of the chromatin or apoptosis. However, the efficiency of repair of the complex DNA damage in cells after exposure to low doses of radiation remains at low levels. The development of the cell response to DNA damages after exposure to low doses of radiation does not reach the desired result due to a small amount of damage, with the progression of the phase cell cycle being ahead of the processes of DNA repair. This is primarily due to the failure of signalization to activate the checkpoint of the cell cycle for its arrest in the case of a small number of critical DNA lesions. In the absence of the arrest of the phase cell cycle progression, especially during the G2/M transition, the reparation mechanisms fail to completely restore DNA, and cells pass into mitosis with a damaged DNA. It is assumed that another reason for the low efficiency of DNA repair in the cells after exposure to low doses of radiation is the existence of a restricted access for the repair system components to the complex damages at the DNA sites of highly compacted chromatin.     

Repair of clustered uracil DNA damages in Escherichia coli

Multiply damaged sites (MDS) are defined as greater than/equal to two lesions within 10–15 bp and are generated in DNA by ionizing radiation. In vitro repair of closely opposed base damages ≥2 bp apart results in a double strand break (DSB). This work extends the in vitro studies by utilizing clusters of uracil DNA damage as model lesions to determine whether MDS are converted to DSBs in bacteria. Lesions were positioned within the firefly luciferase coding region, transformed into bacteria (wild-type, uracil DNA glycosylase-deficient, ung^–, or exonuclease III and endonuclease IV-deficient, xth^–nfo^–) and luciferase activity measured following repair. DSB formation was expected to decrease activity. Two closely opposed uracils separated by ≤7 bp decreased luciferase activity in wild-type and xth^–nfo^–, but not ung^– bacteria. Growth of bacteria to obtain plasmid-containing colonies demonstrated that the plasmid was destroyed following the mis-repair of two uracils positioned 7 bp apart. This study indicates a DSB is formed when uracil DNA glycosylase initiates repair of two closely opposed uracils ≤7 bp apart, even in the absence of the major apurinic endonucleases. This work supports the in vitro studies and demonstrates that DNA repair is not always advantageous to cells.     

Delayed repair of radiation induced clustered DNA damage: friend or foe?

A signature of ionizing radiation exposure is the induction of DNA clustered damaged sites, defined as two or more lesions within one to two helical turns of DNA by passage of a single radiation track. Clustered damage is made up of double strand breaks (DSB) with associated base lesions or abasic (AP) sites, and non-DSB clusters comprised of base lesions, AP sites and single strand breaks. This review will concentrate on the experimental findings of the processing of non-DSB clustered damaged sites. It has been shown that non-DSB clustered damaged sites compromise the base excision repair pathway leading to the lifetime extension of the lesions within the cluster, compared to isolated lesions, thus the likelihood that the lesions persist to replication and induce mutation is increased. In addition certain non-DSB clustered damaged sites are processed within the cell to form additional DSB. The use of E. coli to demonstrate that clustering of DNA lesions is the major cause of the detrimental consequences of ionizing radiation is also discussed. The delayed repair of non-DSB clustered damaged sites in humans can be seen as a "friend", leading to cell killing in tumour cells or as a "foe", resulting in the formation of mutations and genetic instability in normal tissue.     

Repair of HZE-particle-induced DNA double-strand breaks in normal human fibroblasts

DNA damage generated by high-energy and high-Z (HZE) particles is more skewed toward multiply damaged sites or clustered DNA damage than damage induced by low-linear energy transfer (LET) X and gamma rays. Clustered DNA damage includes abasic sites, base damages and single- (SSBs) and double-strand breaks (DSBs). This complex DNA damage is difficult to repair and may require coordinated recruitment of multiple DNA repair factors. As a consequence of the production of irreparable clustered lesions, a greater biological effectiveness is observed for HZE-particle radiation than for low-LET radiation. To understand how the inability of cells to rejoin DSBs contributes to the greater biological effectiveness of HZE particles, the kinetics of DSB rejoining and cell survival after exposure of normal human skin fibroblasts to a spectrum of HZE particles was examined. Using gamma-H2AX as a surrogate marker for DSB formation and rejoining, the ability of cells to rejoin DSBs was found to decrease with increasing Z; specifically, iron-ion-induced DSBs were repaired at a rate similar to those induced by silicon ions, oxygen ions and gamma radiation, but a larger fraction of iron-ion-induced damage was irreparable. Furthermore, both DNA-PKcs (DSB repair factor) and 53BP1 (DSB sensing protein) co-localized with gamma-H2AX along the track of dense ionization produced by iron and silicon ions and their focus dissolution kinetics was similar to that of gamma-H2AX. Spatial co-localization analysis showed that unlike gamma-H2AX and 53BP1, phosphorylated DNA-PKcs was localized only at very specific regions, presumably representing the sites of DSBs within the tracks. Examination of cell survival by clonogenic assay indicated that cell killing was greater for iron ions than for silicon and oxygen ions and gamma rays. Collectively, these data demonstrate that the inability of cells to rejoin DSBs within clustered DNA lesions likely contributes to the greater biological effectiveness of HZE particles.     

Interplay between DNA N-glycosylases/AP lyases at multiply damaged sites and biological consequences

Evidence has emerged that repair of clustered DNA lesions may be compromised, possibly leading to the formation of double-strand breaks (DSB) and, thus, to deleterious events. The first repair event occurring at a multiply damaged site (MDS) is of major importance and will largely contribute to the hazardousness of MDS. Here, using protein extracts from wild type or hOGG1-overexpressing Chinese hamster ovary cells, we investigated the initial incision rate at base damage and the formation of repair intermediates in various complex MDS. These MDS comprise a 1nt gap and 3–4 base damage, including 8-oxoguanine (oG) and 5-hydroxyuracil (hU). We report a hierarchy in base excision that mainly depends on the nature and the distribution of the damage. We also show that excision at both oG and hU, and consequently DSB formation, can be modulated by hOGG1 overexpression. Anyhow, for all the MDS analyzed, DSB formation is limited, due to impaired base excision. Interestingly, repair intermediates contain a short single-stranded region carrying a potentially mutagenic base damage. This in vitro study provides new insight into the processing of MDS and suggests that repair intermediates resulting from the processing of such MDS are rather mutagenic than toxic.     

In vitro repair of synthetic ionizing radiation-induced multiply damaged DNA sites.

When ionizing radiation traverses a DNA molecule, a combination of two or more base damages, sites of base loss or single strand breaks can be produced within 1-4 nm on opposite DNA strands, forming a multiply damaged site (MDS). In this study, we reconstituted the base excision repair system to examine the processing of a simple MDS containing the base damage, 8-oxoguanine (8-oxoG), or an abasic (AP) site, situated in close opposition to a single strand break, and asked if a double strand break could be formed. The single strand break, a nucleotide gap containing 3' and 5' phosphate groups, was positioned one, three or six nucleotides 5' or 3' to the damage in the complementary DNA strand. Escherichia coli formamidopyrimidine DNA glycosylase (Fpg), which recognizes both 8-oxoG and AP sites, was able to cleave the 8-oxoG or AP site-containing strand when the strand break was positioned three or six nucleotides away 5' or 3' on the opposing strand. When the strand break was positioned one nucleotide away, the target lesion was a poor substrate for Fpg. Binding studies using a reduced AP (rAP) site in the strand opposite the gap, indicated that Fpg binding was greatly inhibited when the gap was one nucleotide 5' or 3' to the rAP site.To complete the repair of the MDS containing 8-oxoG opposite a single strand break, endonuclease IV DNA polymerase I and Escherichia coli DNA ligase are required to remove 3' phosphate termini, insert the "missing" nucleotide, and ligate the nicks, respectively. In the absence of Fpg, repair of the single strand break by endonuclease IV, DNA polymerase I and DNA ligase occurred and was not greatly affected by the 8-oxoG on the opposite strand. However, the DNA strand containing the single strand break was not ligated if Fpg was present and removed the opposing 8-oxoG. Examination of the complete repair reaction products from this reaction following electrophoresis through a non-denaturing gel, indicated that a double strand break was produced. Repair of the single strand break did occur in the presence of Fpg if the gap was one nucleotide away. Hence, in the in vitro reconstituted system, repair of the MDS did not occur prior to cleavage of the 8-oxoG by Fpg if the opposing single strand break was situated three or six nucleotides away, converting these otherwise repairable lesions into a potentially lethal double strand break.     

Clustered DNA lesion repair in eukaryotes: relevance to mutagenesis and cell survival

A clustered DNA lesion, also known as a multiply damaged site, is defined as ≥ 2 damages in the DNA within 1-2 helical turns. Only ionizing radiation and certain chemicals introduce DNA damage in the genome in this non-random way. What is now clear is that the lethality of a damaging agent is not just related to the types of DNA lesions introduced, but also to how the damage is distributed in the DNA. Clustered DNA lesions were first hypothesized to exist in the 1990s, and work has progressed where these complex lesions have been characterized and measured in irradiated as well as in non-irradiated cells. A clustered lesion can consist of single as well as double strand breaks, base damage and abasic sites, and the damages can be situated on the same strand or opposing strands. They include tandem lesions, double strand break (DSB) clusters and non-DSB clusters, and base excision repair as well as the DSB repair pathways can be required to remove these complex lesions. Due to the plethora of oxidative damage induced by ionizing radiation, and the repair proteins involved in their removal from the DNA, it has been necessary to study how repair systems handle these lesions using synthetic DNA damage. This review focuses on the repair process and mutagenic consequences of clustered lesions in yeast and mammalian cells. By examining the studies on synthetic clustered lesions, and the effects of low vs high LET radiation on mammalian cells or tissues, it is possible to extrapolate the potential biological relevance of these clustered lesions to the killing of tumor cells by radiotherapy and chemotherapy, and to the risk of cancer in non-tumor cells, and this will be discussed.     

Condensation of DNA—A putative obstruction for repair process in abasic clustered DNA damage

Clustered DNA damages are defined as two or more closely located DNA damage lesions that may be present within a few helical turns of the DNA double strand. These damages are potential signatures of ionizing radiation and are often found to be repair resistant. Types of damaged lesions frequently found inside clustered DNA damage sites include oxidized bases, abasic sites, nucleotide dimers, strand breaks or their complex combinations. In this study, we used a bistranded two-lesion abasic cluster DNA damage model to access the repair process of DNA in condensate form.Oligomer DNA duplexes (47 bp) were designed to have two deoxyuridine in the middle of the sequences, three bases apart in opposite strands. The deoxyuridine residues were converted into abasic sites by treatment with UDG enzyme creating an abasic clustered damage site in a precise position in each of the single strand of the DNA duplex. This oligomer duplex having compatible cohesive ends was ligated to pUC19 plasmid, linearized with HindIII restriction endonuclease. The plasmid–oligomer conjugate was transformed into condensates by treating them with spermidine. The efficiency of strand cleavage action of ApeI enzyme on the abasic sites was determined by denaturing PAGE after timed incubation of the oligomer duplex and the oligomer–plasmid conjugate in presence and absence of spermidine. The efficiency of double strand breaks was determined similarly by native PAGE. Quantitative gel analysis revealed that rate of abasic site cleavage is reduced in the DNA condensates as compared to the oligomer DNA duplex or the linear ligated oligomer–plasmid conjugates. Generation of double strand break is significantly reduced also, suggesting that their creation is not proportionate to the number of abasic sites cleaved in the condensate model. All these suggest that the ApeI enzyme have difficulty to access the abasic sites located deep into the condensates leading to repair refractivity of the damages. In addition, we found that presence of a polyamine such as spermidine has no notable effect in the incision activity of ApeI enzyme in linear oligomer DNA duplexes in our experimental concentration.     

Closely opposed apurinic/apyrimidinic sites are converted to double strand breaks in Escherichia coli even in the absence of exonuclease III, endonuclease IV, nucleotide excision repair and AP lyase cleavage

Multiply damaged sites (MDSs) consist of two or more damages within 20 base pairs (bps) and are introduced into DNA by ionizing radiation. Using a plasmid assay, we previously demonstrated that repair in Escherichia coli generated a double strand break (DSB) from two closely opposed uracils when uracil DNA glycosylase initiated repair. To identify the enzymes that converted the resulting apurinic/apyrimidinic (AP) sites to DSBs, repair was examined in bacteria deficient in AP site cleavage. Since exonuclease III (xth) and endonuclease IV (nfo) mutant bacteria were able to introduce DSBs at the MDSs, we generated unique bacterial mutants deficient in UvrA, Xth and Nfo. However, the additional disruption of nucleotide excision repair (NER) did not prevent DSB formation. xth- nfo- nfi- bacteria also converted the MDSs to DSBs, ruling out endonuclease V as the candidate AP endonuclease. By using MDSs containing tetrahydrofuran (an AP site analog), it was determined that even in the absence of Xth, Nfo, NER and AP lyase cleavage, DSBs were formed from closely opposed AP sites. This finding implies that there is an unknown enzyme/repair pathway for MDSs, and multiple underlying repair systems in cells that can process closely opposed DNA damage into lethal lesions following exposure to ionizing radiation.     

A Stochastic Model of DNA Fragments Rejoining

When cells are exposed to ionizing radiation, DNA damages in the form of single strand breaks (SSBs), double strand breaks (DSBs), base damage or their combinations are frequent events. It is known that the complexity and severity of DNA damage depends on the quality of radiation, and the microscopic dose deposited in small segments of DNA, which is often related to the linear transfer energy (LET) of the radiation. Experimental studies have suggested that under the same dose, high LET radiation induces more small DNA fragments than low-LET radiation, which affects Ku efficiently binding with DNA end and might be a main reason for high-LET radiation induced RBE [1] since DNA DSB is a major cause for radiation-induced cell death. In this work, we proposed a mathematical model of DNA fragments rejoining according to non-homologous end joining (NHEJ) mechanism. By conducting Gillespie''s stochastic simulation, we found several factors that impact the efficiency of DNA fragments rejoining. Our results demonstrated that aberrant DNA damage repair can result predominantly from the occurrence of a spatial distribution of DSBs leading to short DNA fragments. Because of the low efficiency that short DNA fragments recruit repair protein and release the protein residue after fragments rejoining, Ku-dependent NHEJ is significantly interfered with short fragments. Overall, our work suggests that inhibiting the Ku-dependent NHEJ may significantly contribute to the increased efficiency for cell death and mutation observed for high LET radiation.     

Substrate specificity of a mammalian DNA repair endonuclease that recognizes oxidative base damage.

The substrate specificity of a calf thymus endonuclease on DNA damaged by UV ligh, ionizing radiation, and oxidizing agents was investigated. End-labeled DNA fragments of defined sequence were used as substrates, and the enzyme-generated scission products were analyzed by using DNA sequencing methodologies. The enzyme was shown to incise damaged DNA at pyrimidine sites. The enzyme incised DNA damaged with UV light, ionizing radiation, osmium tetroxide, potassium permanganate, and hydrogen peroxide at cytosine and thymine sites. The substrate specificity of the calf thymus endonuclease was compared to that of Escherichia coli endonuclease III. Similar pyrimidine base damage specificities were found for both enzymes. These results define a highly conserved class of enzymes present in both procaryotes and eucaryotes that may mediate an important role in the repair of oxidative DNA damage.     

DNA Repair and the Evolution of Transformation in Bacillus Subtilis. III. Sex with Damaged DNA

Natural genetic transformation in the bacterium Bacillus subtilis provides an experimental system for studying the evolutionary function of sexual recombination. The repair hypothesis proposes that during transformation the exogenous DNA taken up by cells is used as template for recombinational repair of damages in the recipient cell's genome. Earlier results demonstrated that the population density of transformed cells (i.e., sexual cells) increases, relative to nontransformed cells (primarily asexual cells), with increasing dosage of ultraviolet irradiation, provided that the cells are transformed with undamaged homologous DNA after they have become damaged. In nature, however, donor DNA for transformation is likely to come from cells that are as damaged as the recipient cells. In order to better simulate the effects of transformation in natural populations we conducted similar experiments as those just described using damaged donor DNA. We document in this report that transformants continue to increase in relative density even if they are transformed with damaged donor DNA. These results suggest that sites of transformation are often damaged sites in the recipient cell's genome.