DNA ligase I deficiency in Bloom's syndrome

Etiology of Acute Leukemia: A Review

Simple Summary

Acute leukemias are some of the most common cancers affecting all age groups. Despite a significant improvement made in the treatment of acute leukemias, their cause remains unknown. A number of genetic and environmental factors for the development of acute leukemias have been proposed, but none have been proven. Undoubtedly, genetics have a major role in the development of these diseases. The effects of a variety of environmental factors, occupations and hobbies have been explored. A recent “two-hit” theory” for the development of acute lymphoblastic leukemia has been proposed. This combines genetic factors and exposure to infections for the development of this disease. Several genetic factors are suggested. Most recently, for the infection portion, exposure to a virus containing Aspergillus Flavus has been proposed. This review summarizes what is currently known about the factors that are proposed for the development of acute leukemias.

Abstract

Acute leukemias constitute some of the most common malignant disorders. Despite significant progress made in the treatment of these disorders, their etiology remains unknown. A large and diverse group of genetic and environmental variables have been proposed. The role of a variety of factors, including pre-existing and acquired genetic mutations, exposure to radiation and various chemicals during preconception, pregnancy and throughout life, have been explored. The effects of inherited genetic variations and disorders, pre-existing diseases, infectious agents, hobbies, occupations, prior treatments, and a host of other factors have been proposed, but none is universally applicable to all cases. Variation in the incidence and prognosis based on the age, sex, race, type of the disease, geographic area of residence and other factors are intriguing but remain unexplained. Advances in genomic profiling, including genome-wide gene expression, DNA copy number and single nucleotide polymorphism (SNP) genotype, may shed some light on the role of genetics in these disparities. Separate two-hit hypotheses for the development of acute myeloblastic and lymphoblastic leukemia have been proposed. The latter combines genetics and infection factors resulting in leukemogenesis. A number of pre- and post-natal environmental conditions and exposure to infections, including a mycovirus infected Aspergillus flavus, have been suggested. The exact nature, timing, sequence of the events and mechanisms resulting in the occurrence of leukemia requires further investigations. This review summarizes some of the above factors in acute lymphoblastic and myeloblastic leukemias and the direction for future research on the etiology of these disorders.

DNA ligase I variants fail in the ligation of mutagenic repair intermediates with mismatches and oxidative DNA damage

DNA ligase I (LIG1) joins DNA strand breaks during DNA replication and repair transactions and contributes to genome integrity. The mutations (P529L, E566K, R641L and R771W) in LIG1 gene are described in patients with LIG1-deficiency syndrome that exhibit immunodeficiency. LIG1 senses 3'-DNA ends with a mismatch or oxidative DNA base inserted by a repair DNA polymerase. However, the ligation efficiency of the LIG1 variants for DNA polymerase-promoted mutagenesis products with 3'-DNA mismatches or 8-oxo-2'-deoxyguanosine (8-oxodG) remains undefined. Here, we report that R641L and R771W fail in the ligation of nicked DNA with 3'-8-oxodG, leading to an accumulation of 5'-AMP-DNA intermediates in vitro. Moreover, we found that the presence of all possible 12 non-canonical base pairs variously impacts the ligation efficiency by P529L and R771W depending on the architecture at the DNA end, whereas E566K exhibits no activity against all substrates tested. Our results contribute to the understanding of the substrate specificity and mismatch discrimination of LIG1 for mutagenic repair intermediates and the effect of non-synonymous mutations on ligase fidelity.

MIF-173G/C (rs755622) polymorphism as a risk factor for acute lymphoblastic leukemia development in children

BACKGROUND

Macrophage inhibitory factor (MIF) is a pro-inflammatory cytokine modulating monocyte motility and a pleiotropic regulator of different biological and cellular processes. The MIF-173G/C (rs755622) polymorphism is found in the promoter region and affects its activity. The present study investigated the MIF polymorphism as a risk factor for the development of acute lymphoblastic leukemia (ALL) in Egyptian children.

METHODS

We analyzed the MIF-173G/C (rs755622) polymorphism in 180 ALL cases and 150 healthy control children by amplification of the gene using a polymerase chain reaction followed by restriction endonuclease digestion and running on an agarose gel for visualization of the product.

RESULTS

We found a significant incidence of the homozygous polymorphic (CC) genotype and the combined polymorphic genotypes (GC + CC) in ALL patients compared to healthy controls (p = 0.001 and p = 0.007, respectively), whereas the wild-type genotype (GG) was more common in healthy controls (p = 0.006). Multivariate logistic regression analysis adjustment for MIF different genotypes and other potential risk factors such as age, sex and parental smoking indicated that the CC genotype is the only significant risk factor for the test (p = 0.02). We also noted that, by increasing the C-allele representation within the gene [GC, CC], there was an increase in total leukocytic count (p = 0.09 and p = 0.001, respectively) that may reflect the bad prognostic impact of the polymorphic allele, although further studies are needed.

CONCLUSIONS

The results of the present study indicate that the MIF-173G/C (rs755622) polymorphism is a risk factor for childhood ALL development with respect to both homozygous and combined polymorphic genotypes. In addition, the increased leukocytic count in synchronization with the increased representation of the polymorphic C-allele may reflect its bad prognostic impact.

Molecular diagnosis of genodermatoses

The progress of molecular genetics helps clinicians to prove or exclude a suspected diagnosis for a vast and yet increasing number of genodermatoses. This leads to precise genetic counselling, prenatal diagnosis and preimplantation genetic haplotyping for many inherited skin conditions. It is also helpful in such occasions as phenocopy, late onset and incomplete penetrance, uniparental disomy, mitochondrial inheritance and pigmentary mosaicism. Molecular methods of two genodermatoses are explained in detail, i.e. genodermatoses with skin fragility and neurofibromatosis type 1.

A multidimensional strategy to detect polypharmacological targets in the absence of structural and sequence homology

Conventional drug design embraces the “one gene, one drug, one disease” philosophy. Polypharmacology, which focuses on multi-target drugs, has emerged as a new paradigm in drug discovery. The rational design of drugs that act via polypharmacological mechanisms can produce compounds that exhibit increased therapeutic potency and against which resistance is less likely to develop. Additionally, identifying multiple protein targets is also critical for side-effect prediction. One third of potential therapeutic compounds fail in clinical trials or are later removed from the market due to unacceptable side effects often caused by off-target binding. In the current work, we introduce a multidimensional strategy for the identification of secondary targets of known small-molecule inhibitors in the absence of global structural and sequence homology with the primary target protein. To demonstrate the utility of the strategy, we identify several targets of 4,5-dihydroxy-3-(1-naphthyldiazenyl)-2,7-naphthalenedisulfonic acid, a known micromolar inhibitor of Trypanosoma brucei RNA editing ligase 1. As it is capable of identifying potential secondary targets, the strategy described here may play a useful role in future efforts to reduce drug side effects and/or to increase polypharmacology.

Proteins play a critical role in human disease; bacteria, viruses, and parasites have unique proteins that can interfere with human health, and dysfunctional human proteins can likewise lead to illness. In order to find cures, scientists often try to identify small molecules (drugs) that can inhibit disease-causing proteins. The goal is to identify a molecule that can fit snugly into the pockets and grooves, or “active sites,” on the protein's surface. Unfortunately, drugs that inhibit a single disease-causing protein are problematic. A single protein can evolve to evade drug action. Additionally, when only one protein is targeted, drug potency is often diminished. Single drugs that simultaneously target multiple disease-causing proteins are much more effective. On the other hand, if scientists are not careful, the drugs they design might inhibit essential human proteins in addition to inhibiting their intended targets, leading to unexpected side effects. In our current work, we have developed a computer-based procedure that can be used to identify proteins with similar active sites. Once unexpected protein targets have been identified, scientists can modify drugs under development in order to increase the simultaneous inhibition of multiple disease-causing proteins while avoiding potential side effects by decreasing the inhibition of useful human proteins.

Risk factors for acute leukemia in children: a review

Although overall incidence is rare, leukemia is the most common type of childhood cancer. It accounts for 30% of all cancers diagnosed in children younger than 15 years. Within this population, acute lymphocytic leukemia (ALL) occurs approximately five times more frequently than acute myelogenous leukemia (AML) and accounts for approximately 78% of all childhood leukemia diagnoses. Epidemiologic studies of acute leukemias in children have examined possible risk factors, including genetic, infectious, and environmental, in an attempt to determine etiology. Only one environmental risk factor (ionizing radiation) has been significantly linked to ALL or AML. Most environmental risk factors have been found to be weakly and inconsistently associated with either form of acute childhood leukemia. Our review focuses on the demographics of childhood leukemia and the risk factors that have been associated with the development of childhood ALL or AML. The environmental risk factors discussed include ionizing radiation, non-ionizing radiation, hydrocarbons, pesticides, alcohol use, cigarette smoking, and illicit drug use. Knowledge of these particular risk factors can be used to support measures to reduce potentially harmful exposures and decrease the risk of disease. We also review genetic and infectious risk factors and other variables, including maternal reproductive history and birth characteristics.

No association of DNA ligase-I polymorphism with the risk of lung cancer in north-Indian population

DNA ligases play an essential role in repair, replication, and recombination of DNA, and catalyzes the formation of a phosphodiester bond at a nick junction on single- and double-strand breaks. We have conducted a hospital-based case-control study to examine the role of polymorphism of DNA repair gene ligase I (LIGI) in the context of lung cancer risk for north Indian population. One hundred, fifty-one primary lung cancer cases and an equal number of matching hospital controls were collected. The LIGI polymorphism was determined by using the PCR-RFLP method. The association between polymorphisms in the LIGI gene with the risk of lung cancer was estimated by computing odds ratios (ORs) and a 95% confidence interval (CI) using a Multivariate Logistic Regression Analysis. The risk for lung cancer was not associated for individuals featuring LIGI (AC) (OR -0.8, 95% CI = 0.44-1.40) and (AA) (OR -0.8, 95% CI = 0.41-1.80) genotypes. The DNA repair gene (LIGI) may not be playing an important role in modulating the risk of lung cancer in the north Indian population.

Polymorphism of DNA ligase I and risk of lung cancer--a case-control analysis

DNA ligases catalyze the joining of single and double-strand DNA breaks, which is an essential step in DNA replication, recombination and repair. Recently, a common single nucleotide polymorphism (A-->C) in exon 6 of DNA ligase I (LIG1) was identified, but its functional relevance remains to be determined. Because LIG1 participates in DNA repair and reduced DNA repair capacity is associated with risk of lung cancer, we evaluated in a non-population-based case-control study of 530 lung cancer cases and 570 cancer-free controls the role of this polymorphism in susceptibility to lung cancer. All of the subjects were non-Hispanic whites and the controls were frequency-matched to cases on age, sex and smoking status. Using the polymerase chain reaction-restriction fragment length polymorphism method, we found that this LIGI A-->C substitution was very common in healthy controls and that the A and C allele frequencies were close to 0.5. However, there was no significant difference in the frequency distributions of LIGI genotypes between lung cancer cases and controls (25.7, 49.8 and 24.5% in cases and 26.1, 49.7 and 24.2% in controls for the AA, AC and CC genotypes, respectively). Therefore, there was no evidence to support an association between this polymorphism and the risk of lung cancer (adjusted odds ratio (OR)=1.06, 95% confidence interval (CI)=0.76-1.49 for AC versus CC and OR=0.93, 95% CI=0.64-1.36 for AA versus CC) neither in all cases nor in different histopathologic types. The results of this large case-control study suggest that this LIG1 polymorphism may not play an important role in susceptibility to lung cancer.

DNA ligases in the repair and replication of DNA

DNA ligases are critical enzymes of DNA metabolism. The reaction they catalyse (the joining of nicked DNA) is required in DNA replication and in DNA repair pathways that require the re-synthesis of DNA. Most organisms express DNA ligases powered by ATP, but eubacteria appear to be unique in having ligases driven by NAD(+). Interestingly, despite protein sequence and biochemical differences between the two classes of ligase, the structure of the adenylation domain is remarkably similar. Higher organisms express a variety of different ligases, which appear to be targetted to specific functions. DNA ligase I is required for Okazaki fragment joining and some repair pathways; DNA ligase II appears to be a degradation product of ligase III; DNA ligase III has several isoforms, which are involved in repair and recombination and DNA ligase IV is necessary for V(D)J recombination and non-homologous end-joining. Sequence and structural analysis of DNA ligases has shown that these enzymes are built around a common catalytic core, which is likely to be similar in three-dimensional structure to that of T7-bacteriophage ligase. The differences between the various ligases are likely to be mediated by regions outside of this common core, the structures of which are not known. Therefore, the determination of these structures, along with the structures of ligases bound to substrate DNAs and partner proteins ought to be seen as a priority.

Stage-specific apoptosis, developmental delay, and embryonic lethality in mice homozygous for a targeted disruption in the murine Bloom's syndrome gene

Bloom's syndrome is a human autosomal genetic disorder characterized at the cellular level by genome instability and increased sister chomatid exchanges (SCEs). Clinical features of the disease include proportional dwarfism and a predisposition to develop a wide variety of malignancies. The human BLM gene has been cloned recently and encodes a DNA helicase. Mouse embryos homozygous for a targeted mutation in the murine Bloom's syndrome gene (Blm) are developmentally delayed and die by embryonic day 13.5. The fact that the interrupted gene is the homolog of the human BLM gene was confirmed by its homologous sequence, its chromosomal location, and by demonstrating high numbers of SCEs in cultured murine Blm-/- fibroblasts. The proportional dwarfism seen in the human is consistent with the small size and developmental delay (12-24 hr) seen during mid-gestation in murine Blm-/- embryos. Interestingly, the growth retardation in mutant embryos can be accounted for by a wave of increased apoptosis in the epiblast restricted to early post-implantation embryogenesis. Mutant embryos do not survive past day 13.5, and at this time exhibit severe anemia. Red blood cells and their precursors from Blm-/- embryos are heterogeneous in appearance and have increased numbers of macrocytes and micronuclei. Both the apoptotic wave and the appearance of micronuclei in red blood cells are likely cellular consequences of damaged DNA caused by effects on replicating or segregating chromosomes.

A human severe combined immunodeficiency (SCID) condition with increased sensitivity to ionizing radiations and impaired V(D)J rearrangements defines a new DNA recombination/repair deficiency

The products of recombination activating gene (RAG)1 and RAG2 initiate the lymphoid-specific phase of the V(D)J recombination by creating a DNA double-strand break (dsb), leaving hairpin-sealed coding ends. The next step uses the general DNA repair machinery of the cells to resolve this dsb. Several genes involved in both V(D)J recombination and DNA repair have been identified through the analysis of in vitro mutants (Chinese hamster ovary cells) and in vivo situations of murine and equine severe combined immunodeficiency (scid). These studies lead to the description of the Ku-DNA-dependent protein kinase complex and the XRCC4 factor. A human SCID condition is characterized by an absence of B and T lymphocytes. One subset of these patients also demonstrates an increased sensitivity to the ionizing radiation of their fibroblasts and bone marrow precursor cells. This phenotype is accompanied by a profound defect in V(D)J recombination with a lack of coding joint formation, whereas signal joints are normal. Functional and genetic analyses distinguish these patients from the other recombination/repair mutants, and thus define a new group of mutants whose affected gene(s) is involved in sensitivity to ionizing radiation and V(D)J recombination.

Histopathologic and ultrastructural study of lupus-like skin lesions in a patient with Bloom syndrome

The histopathology of the lupus-like skin lesions associated with Bloom syndrome has been sporadically described. Skin biopsies from a 2-year-old boy with the classical features of Bloom syndrome, including lupus-like skin lesions, demonstrated marked interface changes with basal liquefaction degeneration, a moderate superficial mononuclear infiltrate, pigmentary incontinence, and capillary dilation in the papillary dermis. Immunophenotyping of the dermal infiltrate revealed predominance of T-cells. Basement membrane thickening on periodic acid-Schiff examination was not seen. Direct immunofluorescence failed to demonstrate deposits of immunoglobulin other than nonspecific IgM deposition along the basement membrane zone of lesional skin. Ultrastructurally, the most striking findings were disintegration of basal cell cytoplasm and tubuloreticular inclusions in vascular endothelia. Taken together, the histologic and ultrastructural features of lupus-like lesions associated with Bloom syndrome mimic those of cutaneous lupus erythematosus, with the exception of paucity of immune deposits at the dermoepidermal junction.

MNNG-transformed Bloom syndrome B-lymphoblastoids for the detection of Hodgkin's lymphoma-associated antigen in 2D Westerns

Twenty-four hour MNNG-exposed Bloom syndrome (BS) B-lymphoblastoid cells with the potential to form single cell colonies in soft agar and nude mouse tumour (2/6 (33%) showed a simultaneous increase in the Ras-expressing cells (using monoclonal antibody to p21 transforming protein) from 20% (at 24 h) to 85% (on day 30). In contrast, there was an absence of Ras-positive cells in MNNG-exposed fresh lymphocytes (PBMCs) from a healthy subject and a presence of only 11-18% of Ras-positive cells in normal (GA3) and unexposed BS B-lymphoblastoid cells. The Western blot analysis using sera samples from Hodgkin's lymphoma patients showed the presence of proteins of 102 and 68 kDa which in 2D Westerns were observed to be unique to BS-MNNG cells with approximate pIs of 5.3 and 5.7, respectively. It is proposed that BS-MNNG cells provide an interesting in vitro human cell model to generate unique cancer-associated antigen(s) in addition to using this system to understand the primary events associated with neoplastic transformation.

A high yield of translocations parallels the high yield of sister chromatid exchanges in the CHO mutant EM9

The fluorescence plus Giemsa (FPG) and fluorescence in situ hybridization (FISH) techniques have been used to determine, respectively, the frequencies of sister chromatid exchanges (SCEs) and stable chromosome aberrations (translocations) induced by different concentrations of BrdU in the Chinese hamster ovary cell mutant EM9 and its parental line AA8. The results indicate that BrdU induced a high frequency of SCEs and translocations in EM9 as compared with AA8, and that the translocation/dicentric ratio was also higher in the mutant cell line than in the parental cell line in both untreated and BrdU-treated cultures. These observations may indicate a possible relationship between the molecular mechanisms involved in the formation of SCEs and translocations.

Role of Schizosaccharomyces pombe RecQ homolog, recombination, and checkpoint genes in UV damage tolerance

The cellular responses to DNA damage are complex and include direct DNA repair pathways that remove the damage and indirect damage responses which allow cells to survive DNA damage that has not been, or cannot be, removed. We have identified the gene mutated in the rad12.502 strain as a Schizosaccharomyces pombe recQ homolog. The same gene (designated rqh1) is also mutated in the hus2.22 mutant. We show that Rqhl is involved in a DNA damage survival mechanism which prevents cell death when UV-induced DNA damage cannot be removed. This pathway also requires the correct functioning of the recombination machinery and the six checkpoint rad gene products plus the Cdsl kinase. Our data suggest that Rqh1 operates during S phase as part of a mechanism which prevents DNA damage causing cell lethality. This process may involve the bypass of DNA damage sites by the replication fork. Finally, in contrast with the reported literature, we do not find that rqh1 (rad12) mutant cells are defective in UV dimer endonuclease activity.

Creation and removal of embedded ribonucleotides in chromosomal DNA during mammalian Okazaki fragment processing

Mammalian RNase HI has been shown to specifically cleave the initiator RNA of Okazaki fragments at the RNA-DNA junction, leaving a single ribonucleotide attached to the 5'-end of the downstream DNA segment. This monoribonucleotide can then be removed by the mammalian 5'- to 3'-exo-/endonuclease, a RAD2 homolog-1 (RTH-1) class nuclease, also known as flap endonuclease-1 (FEN-1). Although FEN-1/RTH-1 nuclease often requires an upstream primer for efficient activity, the presence of an upstream primer is usually inhibitory or neutral for removal of this 5'-monoribonucleotide. Using model Okazaki fragment substrates, we found that DNA ligase I can seal a 5'-monoribonucleotide into DNA. When both ligase and FEN-1/RTH-1 were present simultaneously, some of the 5'-monoribonucleotides were ligated into DNA, while others were released. Thus, a 5'-monoribonucleotide, particularly one that is made resistant to FEN-1/RTH-1-directed cleavage by extension of an inhibitory upstream primer, can be ligated into the chromosome, despite the presence of FEN-1/RTH-1 nuclease. DNA ligase I was able to seal different monoribonucleotides into the DNA for all substrates tested, with an efficiency of 1-13% that of ligating DNA. These embedded monoribonucleotides can be removed by the combined action of RNase HI, cutting on the 5'-side, and FEN-1/RTH-1 nuclease, cleaving on the 3'-side. After FEN-1/RTH-1 action and extension by polymerization, DNA ligase I can join the entirely DNA strands to complete repair.

A case of Bloom syndrome with conjunctival telangiectasia

Bloom syndrome is a rare genodermatosis characterized by photosensitivity, telangiectasias, growth retardation and malignancies. Eye findings have rarely been mentioned in case reports of this syndrome. We report a child with Bloom syndrome who had pronounced bulbar conjunctival telangiectasia originally diagnosed as episcleritis. Bulbar telangiectasia are frequently described in other genodermatoses such as ataxia telangiectasia and hereditary hemorrhagic telangiectasia, but are infrequently noted in Bloom syndrome. Previously described eye findings in Bloom syndrome are reviewed and the differential diagnosis of bulbar telangiectasia is discussed.

Stability of microsatellites and minisatellites in Bloom syndrome, a human syndrome of genetic instability

Bloom syndrome (BS) is a human cancer-prone genetic disorder essentially characterized by a generalized genetic instability including a high level of sister chromatid exchanges (SCEs). Although mutator and hyper-Rec phenotypes of BS cells present analogies with those of bacteria and yeast defective in DNA mismatch repair, we report that (CA)(n) microsatellite alterations are undetectable in BS cells. Thus, our results suggest that the origin of BS mutator phenotype is not a major defect in DNA mismatch repair, allowing us to eliminate an attractive hypothesis for the pleiotropy of BS. We previously suggested that at least some of the intra-allelic rearrangements occurring in minisatellites could result from unequal SCEs. Although SCEs are abnormally frequent in BS cells, the present study failed to show any significant variation of the mutation rates of the two hypermutable minisatellites we analyzed. Thus, our results show that, in spite of an overall genetic instability, alterations in structural motifs known to be predisposed to instability by different mechanisms are undetectable in BS cells.

Characterization of the XRCC1-DNA ligase III complex in vitro and its absence from mutant hamster cells

The human DNA repair protein XRCC1 was overexpressed as a histidine-tagged polypeptide (denoted XRCC1-His) in Escherichia coli and purified in milligram quantities by affinity chromatography. XRCC1-His complemented the mutant Chinese hamster ovary cell line EM9 when constitutively expressed from a plasmid or when introduced by electroporation. XRCC1-His directly interacted with human DNA ligase III in vitro to form a complex that was resistant to 2 M NaCl. XRCC1-His interacted equally well with DNA ligase III from Bloom syndrome, HeLa and MRC5 cells, indicating that Bloom syndrome DNA ligase III is normal in this respect. Detection of DNA ligase III on far Western blots by radiolabelled XRCC1-His indicated that the level of the DNA ligase polypeptide was reduced approximately 4-fold in the mutant EM9 and also in EM-C11, a second member of the XRCC1 complementation group. Decreased levels of polypeptide thus account for most of the approximately 6-fold reduced DNA ligase III activity observed previously in EM9. Immunodetection of XRCC1 on Western blots revealed that the level of this polypeptide was also decreased in EM9 and EM-C11 (> 10-fold), indicating that the XRCC1-DNA ligase III complex is much reduced in the two CHO mutants.

The Bloom's syndrome gene product is homologous to RecQ helicases

The Bloom's syndrome (BS) gene, BLM, plays an important role in the maintenance of genomic stability in somatic cells. A candidate for BLM was identified by direct selection of a cDNA derived from a 250 kb segment of the genome to which BLM had been assigned by somatic crossover point mapping. In this novel mapping method, cells were used from persons with BS that had undergone intragenic recombination within BLM. cDNA analysis of the candidate gene identified a 4437 bp cDNA that encodes a 1417 amino acid peptide with homology to the RecQ helicases, a subfamily of DExH box-containing DNA and RNA helicases. The presence of chain-terminating mutations in the candidate gene in persons with BS proved that it was BLM.

Mammalian DNA ligase III: molecular cloning, chromosomal localization, and expression in spermatocytes undergoing meiotic recombination

Three biochemically distinct DNA ligase activities have been identified in mammalian cell extracts. We have recently purified DNA ligase II and DNA ligase III to near homogeneity from bovine liver and testis tissue, respectively. Amino acid sequencing studies indicated that these enzymes are encoded by the same gene. In the present study, human and murine cDNA clones encoding DNA ligase III were isolated with probes based on the peptide sequences. The human DNA ligase III cDNA encodes a polypeptide of 862 amino acids, whose sequence is more closely related to those of the DNA ligases encoded by poxviruses than to replicative DNA ligases, such as human DNA ligase I. In vitro transcription and translation of the cDNA produced a catalytically active DNA ligase similar in size and substrate specificity to the purified bovine enzyme. The DNA ligase III gene was localized to human chromosome 17, which eliminated this gene as a candidate for the cancer-prone disease Bloom syndrome that is associated with DNA joining abnormalities. DNA ligase III is ubiquitously expressed at low levels, except in the testes, in which the steady-state levels of DNA ligase III mRNA are at least 10-fold higher than those detected in other tissues and cells. Since DNA ligase I mRNA is also present at high levels in the testes, we examined the expression of the DNA ligase genes during spermatogenesis. DNA ligase I mRNA expression correlated with the contribution of proliferating spermatogonia cells to the testes, in agreement with the previously defined role of this enzyme in DNA replication. In contrast, elevated levels of DNA ligase III mRNA were observed in primary spermatocytes undergoing recombination prior to the first meiotic division. Therefore, we suggest that DNA ligase III seals DNA strand breaks that arise during the process of meiotic recombination in germ cells and as a consequence of DNA damage in somatic cells.

DNA ligase I mediates essential functions in mammalian cells

DNA replication, repair, and recombination are essential processes in mammalian cells. Hence, the application of gene targeting to the study of these DNA metabolic pathways requires the creation of nonnull mutations. We have developed a method for introducing partially defective mutants in murine embryonic stem cells that circumvents the problem of cellular lethality of targeted mutations at essential loci. Using this approach, we have determined that mammalian DNA ligase I is essential for cell viability. Thus, DNA ligases II and III are not redundant with DNA ligase I for the function(s) associated with cell proliferation. Partial complementation of the lethal DNA ligase I null mutation allowed the creation of deficient embryonic stem cell lines. We found that a wild-type DNA ligase I cDNA, as well as a variant DNA ligase I cDNA, was able to rescue the lethality of the homozygous null mutation, whereas an N-terminal deletion mutant consisting of the minimal DNA ligase I catalytic domain was not. This observation demonstrates that sequences outside the DNA ligase I catalytic domain are essential for DNA ligase I function in vivo.

Diagnosis of Bloom's syndrome by sister chromatid exchange evaluation in chorionic villus cultures

Cultures of a chorion biopsy taken from a pregnancy at risk of Bloom's syndrome revealed the high sister chromatid exchange frequency diagnostic of this rare disorder. To obtain the result, cultures were grown under standard conditions, with the addition of 10 microM 5'-bromodeoxyuridine for the final 48 h of incubation. This result demonstrates the feasibility of early prenatal diagnosis of Bloom's syndrome.

Bloom syndrome: an analysis of consanguineous families assigns the locus mutated to chromosome band 15q26.1

By the principle of identity by descent, parental consanguinity in individuals with rare recessively transmitted disorders dictates homozygosity not just at the mutated disease-associated locus but also at sequences that flank that locus closely. In 25 of 26 individuals with Bloom syndrome examined whose parents were related, a polymorphic tetranucleotide repeat in an intron of the protooncogene FES was homozygous, far more often than expected (P < 0.0001 by chi 2). Therefore, BLM, the gene that when mutated gives rise to Bloom syndrome, is tightly linked to FES, a gene whose chromosome position is known to be 15q26.1. This successful approach to the assignment of the Bloom syndrome locus to one short segment of the human genome simultaneously (i) demonstrates the power of homozygosity mapping and (ii) becomes the first step in a "reverse" genetics definition of the primary defect in Bloom syndrome.

Increased rate of spontaneous mitotic recombination in T lymphocytes from a Bloom's syndrome patient using a flow-cytometric assay at HLA-A locus

Bloom's syndrome (BS) is an autosomal recessive disorder conferring high propensity for cancer and displaying a high degree of genetic instability; the frequency of sister chromatid exchange is characteristically 10 times above background. The symmetrical four-armed chromatid interchanges are much more readily detected in peripheral blood lymphocytes of BS patients, suggesting that the frequency of somatic recombination is also increased. In the present study, the rate of spontaneous loss of HLA-A allele expression was estimated following fluctuation analysis in cultured T lymphocytes using a flow-cytometric assay. It was found to be 10 times or more higher than normal in lymphocytes from a BS patient. Molecular and chromosome analyses showed that all 13 independent variants from the patient were most likely derived from somatic recombinations. Further tests for loss of heterozygosity at a closely linked proximal locus, HLA-DQA1, showed that as many as half of the recombinants retained heterozygosity irrespective of the donor. The results suggest that the HLA region is hyperrecombinogenic in somatic cells and that the elevated recombination rate in BS cells results from the general increase at ordinary sites and not from random creation of unusual sites for recombination.

Gene-specific DNA repair of UV-induced cyclobutane pyrimidine dimers in some cancer-prone and premature-aging human syndromes

We have examined the gene-specific DNA repair of UV-induced cyclobutane pyrimidine dimers (CPDs) in fibroblasts from the following cancer prone syndromes: familial dysplastic nevus syndrome (DNS), Gardner's syndrome (GS), and Bloom's syndrome (BS). These heritable human syndromes are associated with DNA damage hypersensitivity and have been considered as potentially DNA repair deficient. Previous determinations of DNA repair in these cell strains have been done solely at the level of the overall genome. That approach is not sensitive enough to detect deficiencies in repair at the level of the gene. Defective preferential repair of active genes may impair survival and affect genomic stability. This is exemplified by the disorder Cockayne's syndrome (CS) which is associated with a selective deficiency in the preferential repair of active genes. In this study, we have used a Cockayne's syndrome cell strain and also a normal human fibroblast cell line as a control. Repair was studied in the transcriptionally active gene dihydrofolate reductase (DHFR), the inactive delta globin gene, and in the c-myc protooncogene. In the DNS, GS and BS cell lines, we find preferential repair similar to that in normal cells. In Cockayne's syndrome cells, there is no preferential repair of the DHFR gene.

Altered DNA ligase III activity in the CHO EM9 mutant

Delayed joining of DNA strand breaks and a high spontaneous level of sister-chromatid exchanges (SCEs) are characteristics of the mutant cell strain EM9 of Chinese hamster ovary (CHO) cells. The introduction of the human gene XRCC1 into EM9 cells reverts the phenotypic properties of EM9 to those of the wild type. We have investigated both DNA ligase activities and a protein which stimulates DNA ligase activity in mutant EM9 cells, XRCC1-transfectant H9T3-7-1 cells and wild-type AA8 cells. Our results, which demonstrate both a decreased DNA ligase activity in EM9 cells using poly(rA).oligo(dT) as substrate and a decreased ability of DNA ligase III to form a covalent DNA ligase III-adenylate intermediate with AMP, clearly indicate an altered DNA ligase III activity in the mutant. Furthermore, the AMP-binding capacity of DNA ligase III and its enzymatic activity with the synthetic polymer were restored after transfection of EM9 with the human XRCC1 gene. Immunoblotting data suggest that the XRCC1 gene does not code for DNA ligase III. In conclusion, the data indicate that the EM9 cell strain has an altered DNA ligase III activity that can be restored by the XRCC1 gene product.

An interaction between the mammalian DNA repair protein XRCC1 and DNA ligase III

XRCC1, the human gene that fully corrects the Chinese hamster ovary DNA repair mutant EM9, encodes a protein involved in the rejoining of DNA single-strand breaks that arise following treatment with alkylating agents or ionizing radiation. In this study, a cDNA minigene encoding oligohistidine-tagged XRCC1 was constructed to facilitate affinity purification of the recombinant protein. This construct, designated pcD2EHX, fully corrected the EM9 phenotype of high sister chromatid exchange, indicating that the histidine tag was not detrimental to XRCC1 activity. Affinity chromatography of extract from EM9 cells transfected with pcD2EHX resulted in the copurification of histidine-tagged XRCC1 and DNA ligase III activity. Neither XRCC1 or DNA ligase III activity was purified during affinity chromatography of extract from EM9 cells transfected with pcD2EX, a cDNA minigene that encodes untagged XRCC1, or extract from wild-type AA8 or untransfected EM9 cells. The copurification of DNA ligase III activity with histidine-tagged XRCC1 suggests that the two proteins are present in the cell as a complex. Furthermore, DNA ligase III activity was present at lower levels in EM9 cells than in AA8 cells and was returned to normal levels in EM9 cells transfected with pcD2EHX or pcD2EX. These findings indicate that XRCC1 is required for normal levels of DNA ligase III activity, and they implicate a major role for this DNA ligase in DNA base excision repair in mammalian cells.

Hypermutable ligation of plasmid DNA ends in cells from patients with Werner syndrome

Werner Syndrome is a rare autosomal recessive disorder characterized by an increased cancer risk and by symptoms suggestive of premature aging. Cells from these patients demonstrate a typical pattern of chromosomal instability and a spontaneous hypermutability with a high rate of unusually large deletions. We have studied the in vivo DNA ligation in three lymphoblast cell lines from Werner syndrome patients and three from normal donors. In our host cell ligation assay we transfected linearized plasmid pZ189 and measured the amount of plasmid DNA ends rejoined by these host cells as the ability of the recovered plasmid to transform bacteria. A mutagenesis marker gene close to the ligation site allowed screening for mutations. Subsequent mutation analysis provided information about the accuracy of the ligation process. The cells from Werner syndrome patients were as effective as normal cells in ligating DNA ends. However, mutation analysis revealed that the three Werner syndrome cell lines introduced 2.4-4.6 times more mutations (p < 0.001) than the normal cell lines during ligation of the DNA ends: the mutation rates were 69.4, 97.2, and 58.7%, as compared to 23.6, 21.7, and 24.4% in the normal cell lines. These increased mutation frequencies in plasmids ligated during passage through Werner syndrome cells were mainly due to a significant (p < 0.001) increase in deletions. This error-prone DNA ligation might be responsible for the spontaneous hypermutability and the genomic instability in Werner syndrome cells and related to the apparently accelerated aging and high cancer risk in affected patients.

An interaction between the mammalian DNA repair protein XRCC1 and DNA ligase III

XRCC1, the human gene that fully corrects the Chinese hamster ovary DNA repair mutant EM9, encodes a protein involved in the rejoining of DNA single-strand breaks that arise following treatment with alkylating agents or ionizing radiation. In this study, a cDNA minigene encoding oligohistidine-tagged XRCC1 was constructed to facilitate affinity purification of the recombinant protein. This construct, designated pcD2EHX, fully corrected the EM9 phenotype of high sister chromatid exchange, indicating that the histidine tag was not detrimental to XRCC1 activity. Affinity chromatography of extract from EM9 cells transfected with pcD2EHX resulted in the copurification of histidine-tagged XRCC1 and DNA ligase III activity. Neither XRCC1 or DNA ligase III activity was purified during affinity chromatography of extract from EM9 cells transfected with pcD2EX, a cDNA minigene that encodes untagged XRCC1, or extract from wild-type AA8 or untransfected EM9 cells. The copurification of DNA ligase III activity with histidine-tagged XRCC1 suggests that the two proteins are present in the cell as a complex. Furthermore, DNA ligase III activity was present at lower levels in EM9 cells than in AA8 cells and was returned to normal levels in EM9 cells transfected with pcD2EHX or pcD2EX. These findings indicate that XRCC1 is required for normal levels of DNA ligase III activity, and they implicate a major role for this DNA ligase in DNA base excision repair in mammalian cells.

DNA ligase III is the major high molecular weight DNA joining activity in SV40-transformed human fibroblasts: normal levels of DNA ligase III activity in Bloom syndrome cells

The phenotypes of cultured cell lines established from individuals with Bloom syndrome (BLM), including an elevated spontaneous frequency of sister chromatid exchanges (SCEs), are consistent with a defect in DNA joining. We have investigated the levels of DNA ligase I and DNA ligase III in an SV40-transformed control and BLM fibroblast cell line, as well as clonal derivatives of the BLM cell line complemented or not for the elevated SCE phenotype. No differences in either DNA ligase I or DNA ligase III were detected in extracts from these cell lines. Furthermore, the data indicate that in dividing cultures of SV40-transformed fibroblasts, DNA ligase III contributes > 85% of high molecular weight DNA joining activity. This observation contrasts with previous studies in which DNA ligase I was reported to be the major DNA joining activity in extracts from proliferating mammalian cells.

Response of radiation-sensitive human cells to defined DNA breaks

We have investigated the response of four human cell lines, representing a range of sensitivities to ionizing radiation, to enzymes which induce defined DNA double-strand breaks (dsbs). Cell lines were derived from a normal individual, from the cancer-prone disorders ataxia-telangiectasia (AT) and Bloom's syndrome (BS), and from an immunodeficient individual (46BR). The molecular defects in AT and BS are unknown, while 46BR is known to be DNA ligase I deficient. We assayed the clonogenic survival of the cell lines following in vivo scission of the DNA by the restriction endonucleases PvuII and BanI. These two enzymes differ in their action; PvuII gives rise to dsbs with blunt termini, while BanI generates staggered ends with a 4 bp overhang. We found a correlation between the sensitivity of the cell lines to X-rays and to the blunt-end cutter PvuII, but not to the cohesive-end cutter BanI.

Analysis of mutations caused by DNA double-strand breaks produced by a restriction enzyme in shuttle vector plasmids propagated in ataxia telangiectasia cells

Rejoining of DNA double-strand breaks (DSB) produced by a restriction endonuclease AvaI in the supF gene in a plasmid pZ189Ava, and mutations presumably due to the altered rejoinings were analyzed. After allowing the rejoining and replication of the plasmids in human cells originating from normal subjects and ataxia telangiectasia (AT) patients, the plasmids were retrieved and those containing mutated supF were screened in an indicator strain of Escherichia coli. The proportion of correctly rejoined plasmids was significantly lower in AT cells than in normal cells, suggesting that AT cells have lower fidelity in rejoining DSB. DNA sequencing of the mutated supF genes revealed that all mutations were deletions or insertions occurring exactly or closely at the rejoining site in both normal and AT cells. In AT cells, the majority of mutations were deletions, while deletions and insertions were evenly formed in normal cells. AT cells may be deficient in the mechanism to protect the broken ends of DNA strands from the exonucleolytic digestion.

Chromosomal breakage, endomitosis, endoreduplication, and hypersensitivity toward radiomimetric and alkylating agents: a possible new autosomal recessive mutation in a girl with craniosynostosis and microcephaly

A high frequency of spontaneous chromosomal breakage, endomitosis, endoreduplication and hypersensitivity toward both the alkylating agent Trenimon and the radiomimetric drug bleomycin was observed in phytohemagglutinin-stimulated peripheral lymphocytes from a girl with craniosynostosis, microcephaly, ptosis, bird-like facies, and moderate mental retardation. We also observed abnormal chromosomal spiralization and some aspects of abnormal cellular division. Several fruitless attempts were made to establish a cell line. The parents were consanguineous, supporting the existence of a new, rare, autosomal, recessive condition in man. The mutation might involve a gene involved in DNA repair and/or regulation of the mitotic cycle.

No relationship between genetic instability in Bloom's syndrome and DNA hypomethylation of some major repetitive sequences

Bloom's syndrome (BS) is an autosomal recessive disorder, characterized by a high incidence of cancer at a young age. Cytogenetically, BS cells exhibit a high frequency of chromosomal damage and sister chromatid exchange (SCE). Thus, BS provides a human model of a genetic disorder exhibiting both chromosomal instability and a high incidence of cancer. In addition to its involvement in gene regulation, CpG methylation has recently been suggested to play an important role in the evolution and stability of chromosome structure. We have examined DNA methylation profiles of total DNA and some selected repeated sequences in normal and BS cells. No specific DNA hypomethylation in either total blood or lymphoblastoid cell lines from BS patients has been detected, suggesting that the genomic instability observed in BS is not directly related to a major DNA demethylation of the total CCGG sites, or of Alu or chromosome 1 satellite 2 repeated sequences.

Non-endemic Burkitt's lymphoma in a patient with Bloom's syndrome

Bloom's syndrome is an autosomal recessive disorder characterized by intrauterine growth retardation, typical physical signs, immunodeficiency and an increased risk of developing neoplasms at a young age, compared to the general population. Factors possibly involved in the pathogenesis of non-endemic Burkitt's lymphoma in a five year old girl with Bloom's syndrome are discussed. These include immunodeficiency, upregulated c-myc expression and an Epstein-Barr viral infection.

Phenotypic correction of a human cell line (46BR) with aberrant DNA ligase I activity

Ligation of DNA after replication and repair is a prerequisite for the preservation of DNA and chromosome structure and function. Biochemical studies with Bloom's syndrome cells have revealed an abnormal DNA ligase I activity. However, genetic analysis has not revealed any differences in transcript levels or in the cDNA sequences of DNA ligase I between Bloom's syndrome and normal cells. Another human cell line, 46BR, derived from an immunodeficient patient, also has an abnormal DNA ligase I. This cell line has recently been demonstrated to harbour two different missense mutations, one at each allele of DNA ligase I. These mutations resulted in a decreased ability of partially purified cell extracts to form an enzyme-adenylate reaction intermediate. We show that 46BR hypersensitivity to an alkylating agent, ethyl methanesulphonate, and to the polyADP-ribose polymerase inhibitor 3-aminobenzamide, is rescued by transfection of wild-type DNA ligase I sequences. This provides additional genetic evidence that the defect in 46BR is at the DNA ligase I locus.

Mammalian DNA-repair genes

The sequence and functional homology of certain genes between mammalian and non-mammalian eukaryotes has facilitated significant advances in our understanding of mammalian DNA repair. Several novel DNA damage and repair genes have been identified by using a variety of approaches. Study of these genes will lead to an increased understanding of the biological consequences of aberrant DNA maintenance in humans and other species.

DNA topoisomerases and the DNA lesion in human genetic instability syndromes

Genetically determined chromosomal instability entails, among other sequelae, a condition of elevated cancer risk. Patients with the autosomal recessive disorder Fanconi's anemia (FA) often develop leukemias of the monocytic lineage together with pancytopenia, whereas the Bloom's syndrome (BS) mutation confers an early and elevated incidence of neoplasia of no particular type. Cultured cells from FA patients show spontaneously elevated rates of chromosome aberrations and a hypersensitivity to DNA cross-linking agents. Cytogenetic evaluation of cells from BS patients revealed elevated rates of sister chromatid exchanges, which were sensitive to the bromodeoxyuridine (BrdU) concentration used in the assay. Such a BrdU sensitivity was also found in cultured cells from healthy subjects exposed to the intracellular superoxide generator paraquat or to bleomycin. Skin fibroblasts from FA and BS patients show poor growth, which in the case of FA could be mitigated by lowering the oxygen concentration to 5%. Lymphoblastoid B-cell lines derived from peripheral blood samples from FA and BS patients show elevated numbers of cells arrested in the G2 phase of the cell cycle. This phenomenon could also be provoked by exposing cell lines from healthy subjects to compounds interfering with the function of DNA topoisomerase I (camptothecin) or II (m-AMSA). To test for a putative deficiency of either DNA topoisomerase, B-cell cultures from FA and BS patients were compared with cell cultures from healthy subjects regarding their sensitivity towards camptothecin and m-AMSA. No difference in sensitivity to these agents was found in patient vs. control cell lines, thus ruling out a deficiency in DNA topoisomerase I or II as the prime defect in these conditions of elevated cancer risk. The similarity between the cell cycle kinetic patterns found in untreated FA cell lines and in normal cell lines exposed to camptothecin or m-AMSA suggest that the DNA lesion in FA, presumably being caused by an oxygen-related mechanism, may interfere with DNA topoisomerase function.

In-vivo assessment of DNA ligation efficiency and fidelity in cells from patients with Fanconi's anemia and other cancer-prone hereditary disorders

We developed a host cell DNA ligation assay, in which we transfected linearized plasmid pZ189 into human lymphoblasts or fibroblasts in order to assess the efficiency and accuracy of DNA ligation within these host cells. We used cell lines from patients with Fanconi's anemia and other chromosome breakage or instability syndromes (Bloom's syndrome, ataxia telangiectasia, Werner's syndrome). With the Fanconi's anemia lymphoblast line GM8010 we did not find a reduced, but a slightly hypermutable DNA ligation. Mutation analysis revealed a unique 7.9-12.5-fold increase in insertions or complex mutations. With cells from the other chromosome breakage/instability syndromes we also found a hypermutable and/or reduced DNA ligation. An impaired DNA ligation might be a common molecular mechanism of genetic instability in these disorders.

Human genetic instability syndromes: single gene defects with increased risk of cancer

The experimental findings of the last 5 years are reviewed for the genetic instability syndromes: Xeroderma pigmentosum, Fanconi's anaemia, Ataxia telangiectasia and Bloom's syndrome. In these autosomal recessive genetic diseases, single gene defects lead to genetic instability, increased mutation rates and cancer. Deficiencies in the ability to effectively repair DNA lesions have been suggested for all of these syndromes. The status of characterization of these DNA repair defects is presented and the possible mechanisms of lesion fixation as mutation are discussed. The four known human genes whose mutation leads to inherited genetic instability are described.

DNA repair and repair fidelity in metastatic variants of the B16 murine melanoma

We have examined the concept of genomic instability in relation to the metastatic progression of low (F1) and high metastasis (BL6, ML8) clones of the B16 mouse melanoma, by using a mutation assay, and DNA strand break repair and repair fidelity assays. The frequency of induced ouabain resistant colonies between the variant cell lines was consistent with the difference between their metastatic properties. Survival data for X-irradiation and bleomycin were similar among the 3 cell lines. When X-rays or bleomycin were used to induce strand breakage, no difference was detectable in either the rate or extent of DNA repair using the techniques of alkaline unwinding and alkaline elution for total strand breaks, and neutral elution for double strand breaks. DNA repair fidelity was measured using the PMH16 plasmid. A Kpn I restriction site was used to introduce a break within the gpt gene of the plasmid, prior to transfection. We found that approximately 100% and approximately 65% of the highly metastatic ML8 and Bl6 clones, respectively, religated the gene with the required fidelity, compared with only approximately 25% of the low metastasis F1 clones. In summary, the metastatic variants show similar sensitivities to X-irradiation and bleomycin, but a differential response to EMS. This difference is not reflected in any subsequent DNA strand break religation, but the variants do differ in their fidelity of repair. However, although the fidelity of DNA religation is related to metastatic potential, it is not consistent with the mutation frequency data.

Abnormal processing of transfected plasmid DNA in cells from patients with ataxia telangiectasia

In order to assess spontaneous mutability and accuracy of DNA joining in ataxia telangiectasia, a disorder with spontaneous chromosome breakage, the replicating shuttle vector plasmid, pZ189, was transfected into SV40 virus-transformed fibroblasts from ataxia telangiectasia patients. The ataxia telangiectasia fibroblasts showed elevated frequency of micronuclei, a measure of chromosome breakage. The spontaneous mutation frequency was normal with circular plasmids passed through the ataxia telangiectasia line. These results were compared to those with transformed fibroblasts from a patient with xeroderma pigmentosum, and from a normal donor. Mutation analysis revealed spontaneous point mutations and deletions in the plasmids with all 3 cell lines, however, insertions or complex mutations were only detectable with the ataxia telangiectasia line. To assess DNA-joining ability, linear plasmids which require joining of the DNA ends by host cell enzymes for survival, were transfected into the cells. We found a 2.4-fold less efficient DNA joining in ataxia telangiectasia fibroblasts (p = 0.04) and a 2.0-fold higher mutation frequency (p less than 0.01) in the recircularized plasmids than with the normal line. Plasmid DNA joining and mutation frequency were normal with the xeroderma pigmentosum fibroblasts. These findings with the ataxia telangiectasia fibroblasts of abnormal types of spontaneous mutations in the transfected plasmid and inefficient, error-prone DNA joining may be related to the increased chromosome breakage in these cells. In contrast, an EB virus-transformed ataxia telangiectasia lymphoblast line with normal frequency of micronuclei showed normal types of spontaneous mutations in the transfected plasmid and normal frequency of DNA joining which was error-prone. These data indicate that mechanisms that produce chromosome breakage in ataxia telangiectasia cells can be reflected in processing of plasmid vectors.

Elevated sister chromatid exchange phenotype of Bloom syndrome cells is complemented by human chromosome 15

Bloom syndrome (BSx) is a rare autosomal-recessive chromosome-instability disorder manifested by a constellation of clinical features including a significant predisposition to early onset of neoplasia. BSx cells display cytogenetic abnormalities, the pathognomonic feature being an increased rate of spontaneous sister chromatid exchanges (SCEs), 10- to 15-fold more frequent than SCEs seen in control cells. Identification of the primary biochemical defect in BSx and its relationship to SCE frequency and neoplasia have been complicated by reports that BSx cell lines exhibit defects in the structure and/or activity of a number of different enzymes. The rare occurrence of the disorder and lack of informative families have precluded mapping of the primary defect by standard linkage analysis. We have utilized BSx cells as recipients for microcell-mediated chromosome transfer to map a locus that renders complementation of the elevated SCE phenotype. Studies with the BSx cell line GM08505 demonstrated a stable frequency of SCEs 10-fold higher than control values, offering a phenotype suitable for complementation studies. Transfer of different independent human chromosomes from somatic cell hybrids into BSx cells permitted identification of a single chromosome that dramatically reduced the SCE frequency to a level near that seen in control cells. Detailed characterization revealed this complementing element to be human chromosome 15.