DNA single-strand breaks in kidneys of Syrian hamsters treated with steroidal estrogens: hormone-induced free radical damage preceding renal malignancy

The chronic administration of estradiol by subcutaneous (s.c.) implantation into male Syrian hamsters induces kidney tumors. Free radicals generated by redox cycling between catecholestrogens and their quinones have been proposed to damage DNA and to thus mediate renal hormone-induced carcinogenesis. As part of an examination of this postulate, we assayed by a filter elution technique DNA single-strand breaks in livers and kidneys of male hamsters treated with estrogen by single intraperitoneal (i.p.) injection, by s.c. implant or by continuous infusion and compared values to those in untreated controls. The DNAs of hamster liver and kidney were not affected by one i.p. injection of 5, 15 or 150 mg/kg estradiol. However, treatment of hamsters with one 25 mg estradiol implant/animal for 2 weeks elevated by 10% the levels of DNA single-strand breaks in kidney, but only to a minor extent in liver, which is not a target of estrogen-induced carcinogenesis. An infusion of 250 micrograms/day/animal of estradiol or 4-hydroxyestradiol for one week by osmotic pumps into hamsters resulted in a comparable increase of single-strand breaks in kidney DNA, whereas 2-hydroxyestradiol under these conditions had a negligible effect. It is concluded that the induction of DNA single-strand breakage by either estradiol or 4-hydroxyestradiol in hamster kidney supports a mechanism of estrogen-induced carcinogenesis by free radical generation via redox cycling between 4-hydroxyestradiol and its corresponding quinone.     

Lysyl oxidase (ras recision gene) expression in human amnion: ontogeny and cellular localization

Certain human heritable forms of colon cancer have characteristically high frequencies of microsatellite alterations. These microsatellite changes are markers of genomic instability and the direct consequence of mutations in genes involved with DNA mismatch repair processes, which are in part responsible for maintaining the sequence integrity of the genome. Given that the B6C3F1 mouse is genetically predisposed to develop liver tumors we were interested in determining whether tumors derived in this strain of mouse may contain alterations in microsatellite sequences. The analysis of 48 tumors at 24 different microsatellite loci revealed that microsatellite alterations were detected in 12 of 48 tumors (25%). Although this frequency is relatively high, 11 of the 12 tumors exhibited only a single alteration and in 10 of those tumors this change was at the same microsatellite locus. Microsatellite alterations were also detected in the DNA isolated from 6 of 22 (27%) normal liver tissues with 4 of the 6 occurring at the same locus where the majority of changes were observed in the tumors. Based on these results, we conclude that the microsatellite alterations present in the mouse liver tumor tissue are most likely the result of spontaneous mutational events. Consequently, the genomic instability operational in a particular type of hereditary human colon cancer does not appear to be operational in the genetically predisposed B6C3F1 mouse liver. In addition, we demonstrated that the activation of the H-ras gene, which causes some forms of genetic instability in vitro, does not contribute to genetic instability within liver tumors as measured by microsatellite alterations.     

Differential display of genome subsets containing specific interspersed repeats

A genomic differential display method was developed that analyzes many restriction fragment length polymorphisms simultaneously. Interspersed repeat sequences were used to reduce DNA sample complexity and to target genomic subsets of interest. This work focused on trinucleotide repeats because of their importance in human inherited diseases. Immobilized repeat-containing oligonucleotides were used to capture genomic DNA fragments containing sequences complementary to the oligonucleotide. Captured fragments were amplified by PCR and fluorescently labeled using primers complementary to the repeat sequence and/or to the known sequences ligated to the ends of the restriction fragments. The labeled PCR fragments were displayed by size on a high-resolution automated fluorescent DNA sequencing instrument. Although there was a conservation in the overall pattern of displayed genome subsets, many clear and reproducible differences were detected when genomes from different individuals were compared. Fewer differences were detected within, than between, monozygotic twin pair genomes. In control experiments, the method distinguished between Huntington disease alleles with normal and expanded CAG repeat lengths.     

Microsatellite mutation (CAG24-->18) in the androgen receptor gene in human prostate cancer

The androgen receptor (AR) gene contains a polymorphic CAG microsatellite that codes for a variable length of glutamine repeats in the AR protein. Microsatellite DNA sequences may be potential sites of genetic instability. Using the polymerase chain reaction (PCR), we screened 40 human prostate cancer specimens for expansions or deletions of this microsatellite. In one patient, nontumor DNA yielded a single PCR product, as expected for the AR, but the tumor DNA yielded two discrete products, one identical to normal, and a second smaller one. Direct sequencing revealed that the nontumor tissue contained 24 CAGs, whereas the tumor contained one fragment with 24 CAGs (wild-type) and a second fragment with 18 CAGs (mutant), representing a somatic contraction of the AR CAG repeat (CAG24-->CAG18) in the tumor. Interestingly, this patient manifested a paradoxical agonistic response to hormonal therapy with the antiandrogen flutamide.     

Detection of microsatellite instability in cancers by arbitrarily primed-PCR fingerprinting using a fluorescently labeled primer (FAP-PCR)

The microsatellite mutator phenotype (MMP), detected as a change in the number of repeating units in hundreds of thousands of microsatellite sequences in the tumor cell genome, underlies the carcinogenesis of a variety of tumors including sporadic and hereditary nonpolyposis colon cancers. This enhanced microsatellite instability was discovered using arbitrarily primed polymerase chain reaction (AP-PCR) fingerprinting of DNA from colon cancers. In this study, we found an arbitrary primer that can amplify multiple DNA fragments containing repeated sequences, including the poly A tracts found in the Alu repeats of the human genome. The combined use of primer labeling with fluorescence and an automated DNA sequencing analysis of AP-PCR products (FAP-PCR) detected alterations in fingerprint bands in all DNA samples previously determined to belong to the MMP. Fluorescent AP-PCR fingerprinting using this single arbitrary primer provides a convenient and efficient method for detecting tumor specific fingerprint alterations that are usually undetectable by conventional fingerprinting.     

Cloning, characterization, and properties of seven triplet repeat DNA sequences

Several neuromuscular and neurodegenerative diseases are caused by genetically unstable triplet repeat sequences (CTG.CAG, CGG.CCG, or AAG.CTT) in or near the responsible genes. We implemented novel cloning strategies with chemically synthesized oligonucleotides to clone seven of the triplet repeat sequences (GTA.TAC, GAT.ATC, GTT.AAC, CAC.GTG, AGG.CCT, TCG.CGA, and AAG.CTT), and the adjoining paper (Ohshima, K., Kang, S., Larson, J. E., and Wells, R. D.(1996) J. Biol. Chem. 271, 16784-16791) describes studies on TTA.TAA. This approach in conjunction with in vivo expansion studies in Escherichia coli enabled the preparation of at least 81 plasmids containing the repeat sequences with lengths of approximately 16 up to 158 triplets in both orientations with varying extents of polymorphisms. The inserts were characterized by DNA sequencing as well as DNA polymerase pausings, two-dimensional agarose gel electrophoresis, and chemical probe analyses to evaluate the capacity to adopt negative supercoil induced non-B DNA conformations. AAG.CTT and AGG.CCT form intramolecular triplexes, and the other five repeat sequences do not form any previously characterized non-B structures. However, long tracts of TCG.CGA showed strong inhibition of DNA synthesis at specific loci in the repeats as seen in the cases of CTG.CAG and CGG.CCG (Kang, S., Ohshima, K., Shimizu, M., Amirhaeri, S., and Wells, R. D.(1995) J. Biol. Chem. 270, 27014-27021). This work along with other studies (Wells, R. D.(1996) J. Biol. Chem. 271, 2875-2878) on CTG.CAG, CGG.CCG, and TTA.TAA makes available long inserts of all 10 triplet repeat sequences for a variety of physical, molecular biological, genetic, and medical investigations. A model to explain the reduction in mRNA abundance in Friedreich's ataxia based on intermolecular triplex formation is proposed.     

Variation in severity of cardiac disease in Holt-Oram syndrome

Dinucleotide microsatellites are useful for gene mapping projects. Depending upon definition of conservation, published estimates of dinucleotide microsatellite conservation levels vary dramatically (30% to 100%). This study focused on well-characterized genes that contain microsatellites in the human genome. The objective was to examine the feasibility of developing microsatellite markers within genes on the basis of the assumption of microsatellite conservation across distantly related species. Eight genes (Gamma-actin, carcinoembryonic antigen, apolipoprotein A-II, cardiac beta myosin heavy chain, laminin B2 chain, MHC class I CD8 alpha chain, c-reactive protein, and retinoblastoma susceptibility protein) containing large dinucleotide repeat units (N > or = 15), complete genomic structure information, and homologous gene sequences in a second species were selected. Heterologous primers were designed from conserved exon sequences flanking a microsatellite motif. PCR products from bovine and porcine genomic DNA were tested for the presence of microsatellite sequences by Southern blot hybridization with biotin-labeled (CA)12 oligonucleotides. Fragments containing microsatellites were cloned and sequenced. Homology was verified by sequence comparisons between human and corresponding bovine or porcine fragments. Four of sixteen (25%) cross-amplified PCR products contained dinucleotide repetitive sequences with repeat unit lengths of 5 to 23. Two dinucleotide repetitive sequences showed microsatellite length polymorphism, and an additional sequence displayed single-strand conformational polymorphism. Results from this study suggest that exploitation of conserved microsatellite sequences is a useful approach for developing specific genetic markers for comparative mapping purposes.     

A novel missense mutation and frameshift mutations in the type II receptor of transforming growth factor-beta gene in sporadic colon cancer with microsatellite instability

Microsatellite instability of DNA samples of 79 sporadic colon cancer patients were analyzed. These samples were also screened to search mutations in the repeat sequences in the gene for the type II receptor of transforming growth factor-beta (TGF-beta RII) using polymerase chain reaction (PCR), electrophoresis with urea gel, and PCR-single strand conformation polymorphism (PCR-SSCP) method. The incidence of microsatellite instability, defined as severe replication error phenotype (RER) with microsatellite alterations in more than three loci, was 6%. Deletion and insertion of an A residue in the (A)10 region, which cause frameshift mutation, were found in four samples and their incidence in the samples with microsatellite instability was 80%. A novel nucleotide substitution of T for G at 1918, which causes missense mutation of arginine to leucine at codon 528, was found in a sample with microsatellite instability. The mutation at 1918 was in highly conservative amino acid residue.     

Stabilization of microsatellite sequences by variant repeats in the yeast Saccharomyces cerevisiae

We examined the effect of a single variant repeat on the stability of a 51-base pair (bp) microsatellite (poly GT). We found that the insertion stabilizes the microsatellite about fivefold in wild-type strains. The stabilizing effect of the variant base was also observed in strains with mutations in the DNA mismatch repair genes pms1, msh2 and msh3, indicating that this effect does not require a functional DNA mismatch repair system. Most of the microsatellite alterations in the pms1, msh2 and msh3 strains were additions or deletions of single GT repeats, but about half of the alterations in the wild-type and msh6 strains were large (> 8 bp) deletions or additions.     

Detection of loss of heterozygosityat microsatellite loci in esophageal squamous-cell carcinoma

Microsatellite alterations at 3 genetic loci (chromosomes 2p, 3p and 17p) were analyzed in 25 tumors (20 primary tumors and 5 metastatic lymph nodes) from 20 patients after surgical treatment for esophageal cancer. DNA samples from tumors were compared with control DNA from lymphocytes obtained from the peripheral blood of the individual patients. Microsatellite alterations [microsatellite instability (MSI) and loss of heterozygosity (LOH)] were detected in 15% of 20 primary tumors with marker D2S123 (chromosome 2p), 55% with marker D3S1067 (chromosome 3p) and 50% with marker TP53 (chromosome 17p). The 3-year disease-free survival rate of the 10 patients who had tumors without alterations or with an alteration at only 1 of 3 microsatellite loci was 75% and it was better than that of the 10 patients who had tumors with alterations at 2 or 3 microsatellite loci (48%, p = 0.049). This finding suggests that esophageal cancer with alterations at multiple microsatellite loci might have strong malignant potential. However, MSI was only detected in one of 20 patients, which suggests that MSI might not play an important role in the development of this cancer. Three of 5 metastatic lymph nodes showed no LOH even though primary tumors of these patients exhibited LOH with 1 or 2 markers, and 1 metastatic lymph node had LOH that was detected with D3S1067 even though the primary tumor of this patient had no LOH with all markers. Thus, clonal heterogeneity might exist in esophageal squamous-cell carcinomas.     

Analysis of the evolutionarily conserved repeat motifs in the genome of the highly endangered central Indian swamp deer Cervus duvauceli branderi

We have analyzed the genome of central Indian swamp deer Cervus duvauceli branderi, an inhabitant of the Kanha National Park, a wildlife conservatory in Central India, with a view to provide a genetic basis for their extinction. Evolutionarily conserved repeat sequence motifs (GATA)3.75, TA(GATA)4, (GACA)3.75, (TGG)6 and a set of mouse beta-actin primers were used to uncover the sequence variation within and between related species by employing techniques of hybridization and AP-PCR amplification. The oligo probe carrying the GACA and TGG repeat motifs was found to be positive with Cervus genome, whereas (GATA)3.75, TA(GATA)4 and beta-actin probes did not cross-hybridize with the same. AP-PCR amplification with (GACA)3.75, unlike the (TGG)6 primer, generated distinct bands in the range of 0. 37-2.10kb amongst different genomes including Cervus. A comparative genome analysis of other species using the AP-PCR approach with (GACA)3.75 primer revealed the phylogenetic status of Cervus duvauceli branderi. From the analysis of a very limited number of Cervus DNA samples, we observed a high level of genetic homogeneity that may be a prime reason for the extinction of this species. This study has implications in the context of conservation of this endangered Cervus duvauceli branderi species.     

Human MSH2 binds to trinucleotide repeat DNA structures associated with neurodegenerative diseases

The expansion of trinucleotide repeat sequences is associated with several neurodegenerative diseases. The mechanism of this expansion is unknown but may involve slipped-strand structures where adjacent rather than perfect complementary sequences of a trinucleotide repeat become paired. Here, we have studied the interaction of the human mismatch repair protein MSH2 with slipped-strand structures formed from a triplet repeat sequence in order to address the possible role of MSH2 in trinucleotide expansion. Genomic clones of the myotonic dystrophy locus containing disease-relevant lengths of (CTG)n x (CAG)n triplet repeats were examined. We have constructed two types of slipped-strand structures by annealing complementary strands of DNA containing: (i) equal numbers of trinucleotide repeats (homoduplex slipped structures or S-DNA) or (ii) different numbers of repeats (heteroduplex slipped intermediates or SI-DNA). SI-DNAs having an excess of either CTG or CAG repeats were structurally distinct and could be separated electrophoretically and studied individually. Using a band-shift assay, the MSH2 was shown to bind to both S-DNA and SI-DNA in a structure-specific manner. The affinity of MSH2 increased with the length of the repeat sequence. Furthermore, MSH2 bound preferentially to looped-out CAG repeat sequences, implicating a strand asymmetry in MSH2 recognition. Our results are consistent with the idea that MSH2 may participate in trinucleotide repeat expansion via its role in repair and/or recombination.     

Microsatellite enrichment in organisms with large genomes (Allium cepa L.)

To exploit the polymorphism of repeat numbers in short tandem repeat (STR) sequences (microsatellites) as molecular markers, STRs must be isolated and PCR primers must be developed in flanking sequences. In species with large genomes such as Allium cepa L. (onion and shallot), an efficient selection procedure for genomic fragments containing STRs is a crucial step. Here we describe a nonradioactive method for microsatellite isolation based on affinity capture of single-stranded restriction fragments annealed to biotinylated microsatellite oligonucleotides (CA)10, (GAA)8 and (AAC)8 followed by adapter-mediated genomic PCR. Cloning of the products in E. coli and plasmid sequencing revealed more than 60% positive clones. Primers were designed in STR-flanking regions, and one or two bands were amplified in 13 diploid onion and five shallot accessions. Allelism of the bands was confirmed by product sequencing.     

Microsatellite analysis of plasma DNA from patients with clear cell renal carcinoma

Deletions of DNA sequences on chromosome 3p [loss of heterozygosity (LOH)] are characteristic of clear cell renal carcinoma, which accounts for about 80% of all renal malignancies. Comparing tumor DNA to DNA from normal cells, LOH analysis of microsatellite sequences has aided in molecular diagnosis of renal carcinoma. Because clinically useful tumor markers do not exist for this cancer entity, the aim of the present study was to detect chromosome 3p microsatellite alterations (LOH and microsatellite instability) in plasma DNA from patients with clear cell renal carcinoma. Four chromosome 3p microsatellites (D3S1307, D3S1560, D3S1289, and D3S1300) were amplified by fluorescent PCR using DNA isolated from normal blood cells and plasma of 40 patients. Corresponding tumor DNA was available from 21 patients. Analyzing PCR products on an automated DNA sequencer, we found LOH in at least one locus in 25 plasma samples (63%), and 14 plasma samples (35%) exhibited LOH at more than one locus. Microsatellite instability of plasma DNA was detectable in one patient (3%). No significant association of advanced (>T2N0M0) tumor stages with LOH in plasma DNA could be demonstrated. If present, modifications of plasma DNA and tumor DNA were identical. No alterations of plasma DNA were found in healthy controls. Analysis of plasma DNA from patients with clear cell renal carcinoma reveals tumor-specific microsatellite alterations and may therefore have diagnostic potential as a molecular tumor marker.     

Episodic ataxia type 2 (EA2) and spinocerebellar ataxia type 6 (SCA6) due to CAG repeat expansion in the CACNA1A gene on chromosome 19p

Point mutations of the CACNA1A gene coding for the alpha 1A voltage-dependent calcium channel subunit are responsible for familial hemiplegic migraine (FHM) and episodic ataxia type 2 (EA2). In addition, expansions of the CAG repeat motif at the 3' end of the gene, smaller than those responsible for dynamic mutation disorders, were found in patients with a progressive spinocerebellar ataxia, named SCA6. In the present work, the analysis of two new families with small CAG expansions of the CACNA1A gene is presented. In one family, with a clinical diagnosis of EA2, a CAG23 repeat allele segregated in patients showing different interictal symptoms, ranging from nystagmus only to severe progressive cerebellar ataxia. No additional mutations in coding and intron-exon junction sequences in disequilibrium with the CAG expansion were found. In the second family, initially classified as autosomal dominant cerebellar ataxia of unknown type, an inter-generational allele size change showed that a CAG20 allele was associated with an EA2 phenotype and a CAG25 allele with progressive cerebellar ataxia. These results show that EA2 and SCA6 are the same disorder with a high phenotypic variability, at least partly related to the number of repeats, and suggest that the small expansions may not be as stable as previously reported. A refinement of the coding and intron-exon junction sequences of the CACNA1A gene is also provided.     

Small slipped register genetic instabilities in Escherichia coli in triplet repeat sequences associated with hereditary neurological diseases

Genetic instability investigations on three triplet repeat sequences (TRS) involved in human hereditary neurological diseases (CTG.CAG, CGG.CCG, and GAA.TTC) revealed a high frequency of small expansions or deletions in 3-base pair registers in Escherichia coli. The presence of G to A polymorphisms in the CTG.CAG sequences served as reporters for the size and location of these instabilities. For the other two repeat sequences, length determinations confirmed the conclusions found for CTG.CAG. These studies were conducted in strains deficient in methyl-directed mismatch repair or nucleotide excision repair in order to investigate the involvement of these postreplicative processes in the genetic instabilities of these TRS. The observation that small and large instabilities for (CTG.CAG)175 fall into distinct size classes (1-8 repeats and approximate multiples of 41 repeats, respectively) leads to the conclusion that more than one DNA instability process is involved. The slippage of the complementary strands of the TRS is probably responsible for the small deletions and expansions in methyl-directed mismatch repair-deficient and nucleotide excision repair-deficient cells. A model is proposed to explain the observed instabilities via strand misalignment, incision, or excision, followed by DNA synthesis and ligation. This slippage-repair mechanism may be responsible for the small expansions in type 1 hereditary neurological diseases involving polyglutamine expansions. Furthermore, these observations may relate to the high frequency of small deletions versus a lower frequency of large instabilities observed in lymphoblastoid cells from myotonic dystrophy patients.     

Mutation of hMSH3 and hMSH6 mismatch repair genes in genetically unstable human colorectal and gastric carcinomas

Mutations within microsatellite sequences, consisting of additions or deletions of repeat units, are known as the replication/repair error positive (RER+) phenotype or micorsatellite instability (MI). Microsatellite instability has been demonstrated in hereditary and sporadic colorectal carcinomas and is usually observed in noncoding regions of genomic DNA. However, relatively few coding region targets of MI have been identified thus far. Using PCR, we amplified regions encompassing (A)8 and (C)8 microsatellite tracts within hMSH3 and hMSH6 from 31 RER+ sporadic colorectal tumors, 8 hereditary colon cancers, 23 RER+ gastric carcinomas, and 32 RER- gastric tumors. Mutations were found in 11 (36%) of 31 sporadic colon carcinomas, 4 (50%) of 8 hereditary colorectal cancers, and 5 (22%) of 23 RER+ gastric carcinomas, but in only 2 (6%) of 32 RER- gastric carcinomas. These frameshift mutations cause premature stop codons downstream that are predicted to abolish normal protein function. Our results and those of others suggest that DNA mismatch repair genes, such as hMSH3 and hMSH6, are targets for the mutagenic activity of upstream mismatch repair gene mutations and that this enhanced genomic instability may accelerate the accumulation of mutations in RER+ tumors.     

Expansion and deletion of triplet repeat sequences in Escherichia coli occur on the leading strand of DNA replication

Expansions and deletions of triplet repeat sequences that cause human hereditary neurological diseases were previously suggested to be mediated by the formation of DNA hairpins on the lagging strand during replication. The replication properties of CTG.CAG, CGG.CCG, and TTC.GAA repeats were studied in Escherichia coli using an in vivo phagemid system as a model for continuous leading strand synthesis. The repeats were substantially deleted when the CTG, CGG, and GAA repeats were the templates for rolling circle replication from the f1 phage origin. The deletions may be mediated by hairpins formed by these repeat tracts. The distributions of the deletion products of the CTG.CAG and CGG.CCG tracts indicated that hairpins of discrete sizes mediate deletions during complementary strand synthesis. Deletions during rolling circle synthesis are caused by larger hairpins of specific sizes. Thus, most deletion products were of defined lengths, suggesting a preference for specific hairpin intermediates. Small expansions of the CTG.CAG and CGG.CCG repeats were also observed, presumably due to the formation of CTG and CGG hairpins on the nascent complementary strand. Since rolling circle replication has been established in vitro as a model for leading strand synthesis, we conclude that triplet repeat instability can also occur on the leading strand of DNA replication.     

Analysis of germline mutation spectra at the Huntington's disease locus supports a mitotic mutation mechanism

Trinucleotide repeat disease alleles can undergo 'dynamic' mutations in which repeat number may change when a gene is transmitted from parent to offspring. By typing >3500 sperm, we determined the size distribution of Huntington's disease (HD) germline mutations produced by 26 individuals from the Venezuelan cohort with CAG/CTG repeat numbers ranging from 37 to 62. Both the mutation frequency and mean change in allele size increased with increasing somatic repeat number. The mutation frequencies averaged 82% and, for individuals with at least 50 repeats, 98%. The extraordinarily high mutation frequency levels are most consistent with a mutation process that occurs throughout germline mitotic divisions, rather than resulting from a single meiotic event. In several cases, the mean change in repeat number differed significantly among individuals with similar somatic allele sizes. This individual variation could not be attributed to age in a simple way or to ' cis ' sequences, suggesting the influence of genetic background or other factors. A familial effect is suggested in one family where both the father and son gave highly unusual spectra compared with other individuals matched for age and repeat number. A statistical model based on incomplete processing of Okazaki fragments during DNA replication was found to provide an excellent fit to the data but variation in parameter values among individuals suggests that the molecular mechanism might be more complex.