Håkan Cederberg

Somatic recombination, gene amplification and cancer

The principle objective of this research programme, to analyse chemical induction of somatic recombination and related endpoints, i.e., mobilization of transposing elements and gene amplification, has been approached by means of several assay systems. These have included Drosophila, Saccharomyces and mammalian cell cultures. 6.1. Screening assays for mitotic recombination. A large number of chemicals have been investigated in the three Drosophila assay systems employed--the multiple wing hair/flare wing spot system developed by Graf et al., 1984, the white-ivory system developed by Green et al., 1986 and the white/white+ eye spot assay developed by Vogel (Vogel and Nivard, 1993). Particularly the screening of 181 chemicals, covering a wide array of chemical classes, by the last mentioned assay has shown that measurement of somatic recombination in Drosophila constitutes a sensitive and efficient short-term test which shows a remarkably good correlation with the agent score of 83 short-term tests analysed by ICPEMC (Mendelsohn et al., 1992; Table 2) as well as the assay performance in international collaborative programmes measuring carcinogen/non-carcinogens (de Serres and Ashby, 1981; Ashby et al., 1985, 1988). Also the wing spot assay has gained wide international recognition as a similarly sensitive test. These two assay systems in Drosophila measure both intrachromosomal events and interchromosomal recombination. The white-ivory system on the other hand is based on the loss of a tandem duplication in the white locus, the mechanism of which is less known, but probably involves intrachromosomal recombination. The difference in the mechanism between this assay and the former two was indicated by the lack of response to methotrexate in the white-ivory assay, while this compound was strongly recombinogenic in both the wing spot and white/white+ assays. The use of different strains of Drosophila with the white/white+ assay demonstrated the importance of the background genotype for the outcome of the test. Up to a 60-fold variation was found between the different genotypes in the response to procarcinogens, evidently dependent on differences in the metabolic activation of procarcinogens. In 1989 Schiestl presented results on intrachromosomal recombination in the strain RS112 of Saccharomyces, which indicated a capability to detect a range of chemical carcinogens, which gave negative results in Ames Salmonella assay. Such a test system, which could identify a larger range of potential carcinogens than conventional short-term tests evidently would be of great value and it therefore seemed of importance to follow up the observations by Schiestl. However, studies within this programme on the same strain of Saccharomyces, as well as the strains D7 (measuring intragenic recombination, intergenic recombination, and point mutation) and JD1 (measuring intragenic recombination at two loci) could not support the observations and interpretation by Schiestl (1989). The Drosophila white-ivory system, which presumably responds primarily by intrachromosomal recombination, did not give positive results with these Salmonella-negative agents either. One system to measure mitotic recombination in mammalian cell cultures was developed in the present programme. It was based on heterozygous mutations in both alleles of the adenosine deaminase gene (ADA). The system selects for proficient recombinants generated by the deficient cells. So far only pilot experiments, indicating that this experimental system operates as planned, have been performed. 6.2 Mechanisms of mitotic recombination The induction of mosaic spots in the wing spot and the white/white+ assays is predominantly dependent on interchromosomal recombination. This is evident from the fact that heterozygous inversions reduce the frequency of spots. A relationship between the length of inversions and the reduction of spots was demonstrated in the white/white+ assay--the long inversion ln(l)sc4L

Induction of germline‐length mutations at the minisatellites PC‐1 and PC‐2 in male mice exposed to polychlorinated biphenyls and diesel exhaust emissions

PC‐1 and PC‐2 are hypervariable mouse minisatellites. The rates of spontaneous germline‐length mutation have been shown to vary between different mouse strains. PC‐1 is composed of GGCAG repeat units and PC‐2 of GGCAGGA. Minisatellites frequently mutate by gaining or losing repeat units. Such length mutations in mini‐ and microsatellites have been associated with human disease and may therefore be an important endpoint in genetic toxicity testing. Carcinogenic activity of many chemicals is associated with their ability to induce heritable mutations. Since minisatellites are highly prone to mutate to new lengths, which can be assayed by Southern analysis, we used this method to detect heritable genetic effects in mice. Male mice exposed to diesel exhausts and/or polychlorinted biphenyls (PCB) were investigated for effects on the germline mutation frequenallele lengths in parents and offspring. For PC‐1 significantly higher mutation frequencies were found in males treated with diesel exhausts + PCB (6 of 35 alleles) and with PCB alone (6 of 51 alleles) as compared to the males in the control group (0 of 43 alleles). The mutation frequency in the diesel exhaust group was not significantly increased (2 of 43 alleles). For PC‐2 the only mutation found occurred in the PCB group (1 of 51 alleles). This in vivo study demonstrates—for the first time—chemically induced minisatellite mutations in the germline. Environ. Mol. Mutagen. 30:254–259, 1997

Mutations at the human minisatellite MS32 integrated in yeast occur with high frequency in meiosis and involve complex recombination events

Abstract Minisatellites are composed of tandem repetitive DNA sequences and are present at many positions in the human genome. They frequently mutate to new length alleles in the germline, by complex and incompletely understood recombination mechanisms which may operate during meiosis. In several minisatellites the mutation events are restricted to one end of the repeat array, indicating a possible association with elements that act in cis. Mutant alleles do not show exchange of flanking regions. To construct a model system suitable for further investigations of the mutation process, we have integrated the human minisatellite MS32, flanked by synthetic markers, in the vicinity of a meiotic recombination hot spot upstream of the LEU2 locus in the yeast Saccharomyces cerevisiae. Here we provide direct evidence for a meiotic origin of MS32 mutations. Mutation events were polarised towards both ends of the minisatellite and varied from simple duplications and deletions to complex intra- and interallelic events. Interallelic events were frequently accompanied by exchange of regions flanking the minisatellite. The results also support the notion that cis-acting elements are involved in the mutational process. The fact that MS32 mutant structures are similar in yeast and human shows that meiotic recombination plays a crucial role in both organisms and emphasises the usefulness of yeast strains harbouring minisatellites as a model system for the study of minisatellite mutation.

Genotoxic activity of 1,3-butadiene and nitrogen dioxide and their photochemical reaction products in Drosophila and in the mouse bone marrow micronucleus assay

The genotoxic activity of a photochemical reaction mixture of 1,3-butadiene and nitrogen dioxide was investigated in vivo in the mouse bone marrow micronucleus assay and the somatic mutation and recombination test in Drosophila (the wing spot test). Butadiene alone was not mutagenic in Drosophila, but induced micronuclei in mice at 10 ppm after 23 h of exposure. Nitrogen dioxide was not genotoxic in either test system. The photochemical reaction products were toxic but probably not mutagenic in Drosophila and not genotoxic in mouse bone marrow. The in vivo results do not confirm earlier in vitro results that demonstrated a strong direct-acting mutagenic activity of the photochemical products in Salmonella.

Two Modes of Germline Instability at Human Minisatellite MS1 (Locus D1S7): Complex Rearrangements and Paradoxical Hyperdeletion

Minisatellite MS1 (locus D1S7) is one of the most unstable minisatellites identified in humans. It is unusual in having a short repeat unit of 9 bp and in showing somatic instability in colorectal carcinomas, suggesting that mitotic replication or repair errors may contribute to repeat-DNA mutation. We have therefore used single-molecule polymerase chain reaction to characterize mutation events in sperm and somatic DNA. As with other minisatellites, high levels of instability are seen only in the germline and generate two distinct classes of structural change. The first involves large and frequently complex rearrangements that most likely arise by recombinational processes, as is seen at other minisatellites. The second pathway generates primarily, if not exclusively, single-repeat changes restricted to sequence-homogeneous regions of alleles. Their frequency is dependent on the length of uninterrupted repeats, with evidence of a hyperinstability threshold similar in length to that observed at triplet-repeat loci showing expansions driven by dynamic mutation. In contrast to triplet loci, however, the single-repeat changes at MS1 exclusively involve repeat deletion, and can be so frequent--as many as 0.7-1.3 mutation events per sperm cell for the longest homogeneous arrays--that alleles harboring these long arrays must be extremely ephemeral in human populations. The apparently impossible existence of alleles with deletion-prone uninterrupted repeats therefore presents a paradox with no obvious explanation.

The human minisatellites MS1, MS32, MS205 and CEB1 integrated into the yeast genome exhibit different degrees of mitotic instability but are all stabilised by RAD27

Abstract. The yeast Rad27 protein is homologous to mammalian Fen1 and is involved in the processing of replication intermediates. Enhanced instability of various artificial repetitive DNA sequences in RAD27-deficient yeast strains has been observed previously and shown to involve preferentially expansion mutations. In the present investigation, we characterised the mitotic instability of alleles of the naturally occurring human minisatellites MS1, MS32, MS205 and CEB1 and the modified MS1 alleles containing more highly homogenous repeat regions than the original alleles. These minisatellites demonstrated more pronounced instability in rad27Δ strains, with increases in the frequencies of both expansion and contraction mutants. In RAD27 strains, MS32 and MS205 were relatively stable, while MS1 and CEB1 were unstable, indicating that the effect of RAD27 on stability is influenced by intrinsic properties of the repeat array. This conclusion received further support from the remarkably high frequency of length-mutants observed for the modified allele of MS1. Thus, our findings emphasise the importance of: (1) comparing results obtained with various naturally occurring minisatellites and (2) manipulating their sequences in attempts to understand the molecular basis for mitotic stability/instability of minisatellite DNA.

Amplification and loss of repeat units of the human minisatellite MS1 integrated in chromosome III of a haploid yeast strain

Minisatellites comprise arrays of tandemly repeated short DNA sequences which show extensive variation in repeat unit number. The mechanisms that underlie this length variation are not understood. In order to study processes influencing length changes of minisatellites, we integrated the human minisatellite MS1 into a haploid strain of the yeast Saccharomyces cerevisiae. Frequent spontaneous generation of MS1 alleles with new lengths were observed in this yeast strain. Hence it is concluded that recombination between members of a pair of homologous chromosomes is not a prerequisite for the generation of length changes in MS1 in yeast.

Tetrad analysis shows that gene conversion is the major mechanism involved in mutation at the human minisatellite MS1 integrated in Saccharomyces cerevisiae.

Minisatellites are arrays of tandemly repeated DNA sequences which occur at thousands of locations in the human genome. They are frequently hypervariable with respect to allele length as a result of high rates of complex and incompletely understood recombination-based germline mutation events that alter the repeat copy number. MS1 is one of the most variable minisatellites so far isolated from the human genome. We have integrated MS1, flanked by synthetic markers, in the vicinity of a hot spot for meiotic double-strand breaks upstream of the LEU2 locus in chromosome III of Saccharomyces cerevisiae. Here we present the first tetrad analysis of mutations at a human minisatellite locus. The data showed that mutant alleles occur as single mutants in one of the spores in a tetrad, also when the mutant structure was the result of a combination of intra- and inter-allelic rearrangements. The conversional transfer of repeat units from one allele to the other was associated with flanking marker conversion which always involved the same flank of the minisatellite. The results demonstrate that conversion is the predominant mechanism by which minisatellite alleles mutate to new lengths, and also support the assumption that cis-acting elements are involved in the regulation of the mutational process in humans.

MEIOTIC INTERALLELIC CONVERSION AT THE HUMAN MINISATELLITE MS32 IN YEAST TRIGGERS RECOMBINATION IN SEVERAL CHROMATIDS

Tandem repetitive DNA sequences such as minisatellites include the most polymorphic loci yet identified in the human genome. The high mutation rates at many of these loci are driven by incompletely understood recombination-based mechanisms that operate in the germline. To analyse aspects of minisatellite mutation processes and general eukaryotic recombination in meiosis that cannot be studied in humans or other mammals, including crosstalk and interplay between all four chromatids, we have previously constructed a eukaryotic model system, enabling the analysis of all four products of meiosis. In this system we have integrated alleles of the human minisatellite MS32, flanked by synthetic markers, in the vicinity of a meiotic recombination hot spot in chromosome III of Saccharomyces cerevisiae. In the present study, tetrad analysis showed that gene conversion is the predominant and possibly the universal pathway leading to interallelic transfer of repeats, with or without exchange of flanking regions. The data also suggest a hyper-recombinogenic state, triggered by interallelic mutation processes which generate a cascade of mutant alleles in the same meiosis. A number of tetrads contained identical mutant alleles of meiotic origin. Several tetrads could not be explained by the current models for minisatellite mutation. Accordingly, we here present a modified model based on the successive repair of multiple double-strand breaks.

The Influence of Sequence Divergence between Alleles of the Human MS205 Minisatellite Incorporated into the Yeast Genome on Length-mutation Rates and Lethal Recombination Events During Meiosis

Certain minisatellites exhibit hypervariability with respect to the number of repeat units and, thus, allele length. Such polymorphism is generated by germline-specific recombinational events that occur at high frequencies and lead to the gain or loss of repeat units. In order to elucidate the molecular details of mutagenesis in minisatellites, we have integrated human minisatellites into the yeast genome in the vicinity of a hotspot for meiotic double-strand breaks (DSBs). Here, we describe the results of tetrad analyses of mutations in the human MS205 minisatellite in yeast strains heterozygous for alleles composed of 51 and 31 repeat units, as well as in a strain homozygous for the same 51 repeat unit allele. The length-mutation rate was twice as high in the heterozygous strain as in the homozygous strain, suggesting that sequence divergence between alleles enhances the generation of length mutations. In the case of heterozygotes, the frequency of length mutants resulting from inter-allelic exchange was significantly higher in tetrads with three viable spores than in tetrads with four viable spores, indicating that there is a higher probability for spore mortality in tetrads originating from meioses during which inter-allelic exchange of repeat units occurs. In an attempt to explain these findings, we propose a model for minisatellite mutation involving recombination, in which sequence divergence between alleles results in a heteroduplex containing numerous mismatches. We suggest that convergent mismatch-repair tracts in this heteroduplex give rise to a DSB that may be repaired by an additional round of recombination resulting in mutation of a third allele, or be lethal if such recombination fails. It appears probable that the formation of such additional mutants is the major explanation for the difference in meiotic length-mutation rates between the heterozygous and homozygous yeast strains, and that this phenomenon contributes to high germline length-mutation frequencies at minisatellites in humans.