Colony probing as an alternative to standard sequencing as a means of direct analysis of chromosomal DNA to determine the spectrum of single-base changes in regions of known sequence

Genomic-Wide Analysis with Microarrays in Human Oncology

DNA microarray technologies have advanced rapidly and had a profound impact on examining gene expression on a genomic scale in research. This review discusses the history and development of microarray and DNA chip devices, and specific microarrays are described along with their methods and applications. In particular, microarrays have detected many novel cancer-related genes by comparing cancer tissues and non-cancerous tissues in oncological research. Recently, new methods have been in development, such as the double-combination array and triple-combination array, which allow more effective analysis of gene expression and epigenetic changes. Analysis of gene expression alterations in precancerous regions compared with normal regions and array analysis in drug-resistance cancer tissues are also successfully performed. Compared with next-generation sequencing, a similar method of genome analysis, several important differences distinguish these techniques and their applications. Development of novel microarray technologies is expected to contribute to further cancer research.

Overview of DNA microarrays: types, applications, and their future

This unit provides an overview of DNA microarrays. Microarrays are a technology in which thousands of nucleic acids are bound to a surface and are used to measure the relative concentration of nucleic acid sequences in a mixture via hybridization and subsequent detection of the hybridization events. This overview first discusses the history of microarrays and the antecedent technologies that led to their development. This is followed by discussion of the methods of manufacture of microarrays and the most common biological applications. The unit ends with a brief description of the limitations of microarrays and discusses how microarrays are being rapidly replaced by DNA sequencing technologies.

Use of Drosophila deoxynucleoside kinase to study mechanism of toxicity and mutagenicity of deoxycytidine analogs in Escherichia coli

Most bacteria, including Escherichia coli, lack an enzyme that can phosphorylate deoxycytidine and its analogs. Consequently, most studies of toxicity and mutagenicity of cytosine analogs use ribonucleosides such as 5-azacytidine (AzaC) and zebularine (Zeb) instead of their deoxynucleoside forms, 5-aza-2'-deoxycytidine (AzadC) and 2'-deoxy-zebularine (dZeb). The former analogs are incorporated into both RNA and DNA creating complex physiological responses in cells. To circumvent this problem, we introduced into E. coli the Drosophila deoxynucleoside kinase (Dm-dNK), which has a relaxed substrate specificity, and tested these cells for sensitivity to AzadC and dZeb. We find that Dm-dNK expression increases substantially sensitivity of cells to these analogs and dZeb is very mutagenic in cells expressing the kinase. Furthermore, toxicity of dZeb in these cells requires DNA mismatch correction system suggesting a mechanism for its toxicity and mutagenicity. The fluorescence properties of dZeb were used to quantify the amount of this analog incorporated into cellular DNA of mismatch repair-deficient cells expressing Dm-dNK and the results showed that in a mismatch correction-defective strain a high percentage of DNA bases may be replaced with the analog without long term toxic effects. This study demonstrates that the mechanism by which Zeb and dZeb cause cell death is fundamentally different than the mechanism of toxicity of AzaC and AzadC. It also opens up a new way to study the mechanism of action of deoxycytidine analogs that are used in anticancer chemotherapy.

Mutant spectra analysis at hisG46 in Salmonella typhimurium strain YG1029 induced by mammalian S9- and plant-activated aromatic amines

Mutant spectra analysis was conducted with spontaneous hisG46 revertants of Salmonella typhimurium strain YG1029 and revertants induced by the plant- and mammalian S9-activation of benzidine and 4-aminobiphenyl (4-ABP). Under preincubation conditions, YG1029 cells were exposed to benizidine or 4-ABP with mammalian S9 activation or to a high molecular weight fraction that contained the plant-activated products. The induced revertants were isolated at mutagen concentrations that caused an increased mutant frequency of approximately 4- to 10-fold above background. Genomic DNA from each revertant was isolated and the hisG region was amplified using polymerase chain reaction (PCR). Using a series of specific probes and a modified version of the ECL3's-oligolabelling and detection system, each of the six possible base-pair substitution mutations at hisG46 that leads to a reversion event was determined. Of the YG1029 spontaneous revertants, transition mutations were 31.8% and transversion mutations were 68.2%. The YG1029 spontaneous mutant spectrum differed significantly from the spontaneous spectrum of TA1535 but did not significantly differ from the spontaneous TA100 mutant spectrum. The differences of the spontaneous mutant spectra among these highly related strains illustrate that the introduction of the plasmid pKM101 into S. typhimurium increased the frequency of transversions (CCC-->ACC; CCC-->CAC) and reduced site 2 (CCC-->CTC) transitions. With plant-activated benzidine, 21.1% of recovered revertants resulted from transitions and 78.9% from transversions while S9 activated-benzidine induced revertants were recovered as 14.2% from transition and 85.8% from transversion mutations. Plant-activated 4-ABP recovered 20.0% transitions and 80.0% transversions. S9-activated 4-ABP-induced 21.4% transitions and 78.6% transversions. Chi-square analysis of mutant spectra indicated that the DNA lesions that resulted in reversion at the hisG46 allele induced by plant-activated benzidine or 4-ABP were different from those generated after mammalian S9 activation of these promutagens. The plant-activated benzidine and 4-ABP induced statistically identical mutant spectra. Also, the mammalian-activated benzidine and 4-ABP induced statistically similar mutant spectra. These data show that the plant-activated and mammalian-activated aromatic amine products inflicted different types or distributions of DNA lesions that were reflected in the resulting induced mutant spectra.

Comparison of responses of base-specific Salmonella tester strains with the traditional strains for identifying mutagens: the results of a validation study

The ability of a TA7000 series of Salmonella his- mutant tester strains to detect mutagens as classified by the traditional tester strains (TA100, TA98, TA1535, TA1537, TA97, TA102 and TA104) was evaluated using 30 coded chemicals, 5 of which were duplicates with different code numbers. The TA7000 series of tester strains were TA7001, TA7002, TA7003, TA7004, TA7005 and TA7006, each of which reverts by a specific base substitution. In addition, each chemical was tested in a mixture of the base-specific strains (the Mix), plus the traditional strains, TA98 and TA1537. A liquid version of the Salmonella mutagenicity assay was performed in microtiter plates to allow partial automation for increased throughput. The results were compared to those in the National Toxicology Program (NTP) database, which were obtained from the traditional strains in the preincubation assay. In the two strains common to both protocols, TA98 and TA1537, the agreement was 80% and 85%, respectively. When compared to the NTP results for TA100, the Mix gave a 72% concordance, while the addition of the frameshift tester strain, TA98, increased the agreement to 76%. The overall agreement on positive or negative classifications of mutagenicity was 88% for the 25 chemicals tested. There were three notable exceptions to the overall agreement. Benzaldehyde was detected as a mutagen in TA7005 in contrast to its classification as a non-mutagen in the NTP database. This does not necessarily contradict the NTP results because the base-specific strains may respond to different mutagens. Two weak mutagens in the NTP database, 1-chloro-2-propanol and isobutyl nitrite, were not detected as mutagens in the base-specific new strains in the liquid protocol. While there are a number of major differences in the two assays, it was concluded that the results from each procedure are comparable.

Reversion profiles of coolwhite fluorescent light compared with far ultraviolet light: homologies and differences

General Electric and Sylvania 15 W coolwhite fluorescent lamps emit roughly 6% of their total irradiance as light in the UV spectrum. Illumination of sensitive Salmonella tester strains results in both lethal and mutagenic activities. In contrast, comparable Philips lamps emit lower levels of UV light, especially UVB, and exhibit no detectable lethal or mutagenic effects. The spectra of mutations induced by General Electric coolwhite lamps in histidine-requiring base substitution mutants hisG46 and hisG428 ("reversion profiles") resemble mutagenesis by far UV light (UVC) and differ quite markedly from the spectra of mutations that occur spontaneously. Coolwhite and UVC reversion profiles are not identical, however. The percentage of C to A transversion mutations induced in hisG46 are elevated over those found after UVC treatment, and a strong bias for one particular class of tandem base substitutions (TAA-->TGT) prevails after treatment of hisG428 with coolwhite light, a bias not observed with UVC. Increased attention needs to be given to minimization of exposure to UV light from fluorescent lamps commonly used in homes and workplaces.

Mapping ethanol-induced deletions

Chromosomal rearrangements, uniformly represented by very large deletions, were stimulated upon transiently exposing Escherichia coli cells with a defective lambda prophage to about 18% (v/v) ethanol. It was shown that the ethanol treatment induced deletion formation rather than enriching for ethanol-tolerant cells. The deletions in 435 mutants were mapped to 26 groups. Ethanol treatment changed the spectrum of deletions relative to those arising spontaneously, and stimulated the formation of deletions with endpoints in E. coli DNA flanking the lambda fragment. The promotion of deletion formation by ethanol involves the joining of distant, nonhomologous linear DNA segments, which can be considered an illegitimate recombination event; however, activity of the E. coli recA gene product was also required. Although spontaneous deletions arose in comparable cells defective for recA, the incidence of deletion formation in recA cells was not altered by ethanol. It is proposed that ethanol stimulates chromosomal rearrangements involving two oppositely oriented replication forks, since the localized deletions commonly removed or inactivated the chromosomal segment including the bidirectional lambda origin of replication. The results imply a novel mutagenic process induced by an agent that does not act directly on DNA.

A tester system for detecting each of the six base-pair substitutions in Saccharomyces cerevisiae by selecting for an essential cysteine in iso-1-cytochrome c

A collection of isogenic yeast strains that is specifically diagnostic for the six possible base-pair substitutions is described. Each strain contains a single, unique base-pair substitution at the Cys-22 codon of the CYC1 gene, which codes for iso-1-cytochrome c. These mutations encode replacements of the functionally critical Cys-22 and render each strain unable to grow on media containing nonfermentable carbon sources (Cyc-). Specific base-pair substitutions, which restore the Cys-22 codon, can be monitored simply by scoring for reversion to the Cyc+ phenotype. These strains revert spontaneously at very low frequencies and exhibit specific patterns of reversion in response to different mutagens. Only true (CYC1+) revertants were recovered after 7 days on selection medium. The following mutagen specificities were observed: ethyl methanesulfonate and N-methyl-N'-nitro-N-nitrosoguanidine, G.C----A.T; 4-nitroquinoline-1-oxide, G.C----T.A and G.C----A.T; diepoxybutane, A.T----T.A, A.T----G.C and G.C----T.A; 5-azacytidine, G.C----C.G. Methyl methanesulfonate induced all six mutations, albeit at relatively low frequencies, with preference for A.T----T.A and A.T----G.C. Ultraviolet light was the most inefficient mutagen used in this study, consistent with its preference for transition mutations at dipyrimidine sequences reported in other systems. This tester system is valuable as a simple and reliable assay for specific mutations without DNA sequence analysis.

Mutational specificities of environmental carcinogens in the lacl gene of Escherichia coli H. V: DNA sequence analysis of mutations in bacteria recovered from the liver of Swiss mice exposed to 1,2-dimethylhydrazine, azoxymethane, and methylazoxymethanolacetate

The host-mediated assay (HMA) was used to determine the spectra of mutations induced in the lacl gene of Escherichia coli cells recovered from the livers of Swiss mice exposed to the carcinogens 1,2-dimethylhydrazine (SDMH), azoxymethane (AOM), and methylazoxymethanolacetate (MAMA). These spectra were further compared with changes induced by dimethylnitrosamine (DMNA) in the HMA methodology. A total of 177 independent lacl mutations arising in the HMA following exposure to SDMH, AOM, and MAMA were analyzed. Single-base substitutions accounted for 97% of all mutations analyzed. The vast majority of the single-base substitutions consisted of G:C----A:T transitions (94% of all mutations). The remaining mutations consisted of A:T----G:C transitions (3% of all mutations) while non-base substitutions accounted for only 3% of the total mutagenesis. The latter mutations consisted of one frameshift mutation and four lacO deletions. The distribution of G:C----A:T transitions induced by the three chemicals in the first 200 bp of the lacl gene was not random, but rather clustered at sites where a target guanine was flanked at the 5' site by a purine residue.

Differential activity of a transposable element in Escherichia coli colonies

In Escherichia coli colonies, patterns of differential gene expression can be visualized by the use of Mu d(lac) fusion elements. Here we report that patterned beta-galactosidase expression in colonies of strain MS1534 resulted from a novel mechanism, spatially localized replication of the Mu dII1681 element causing lacZ transposition to active expression sites. Mu dII1681 replication did not occur constitutively with a fixed probability but was dependent on the growth history of the bacterial population. The bacteria in which Mu dII1681 replication and lacZ transposition had occurred could no longer form colonies. These results lead to several interesting conclusions about cellular differentiation during colony development and the influence of bacterial growth history on gene expression and genetic change.

A set of lacZ mutations in Escherichia coli that allow rapid detection of each of the six base substitutions

We describe the construction of six strains of Escherichia coli with different mutations at the same coding position in the lacZ gene, which specifies the active site glutamic acid residue at position 461 in beta'-galactosidase. Each strain is Lac- and reverts to Lac+ only by restoring the glutamic acid codon. The strains have been designed so that each reverts via one of the six base substitutions. The set of strains allows detection of each transition and transversion simply by monitoring the Lac- to Lac+ frequency, as demonstrated here with characterized mutagens and mutator alleles. These strains are useful for rapidly determining the mutagenic specificity of mutagens at a single site, for detecting low levels of stimulation of certain base substitutions, for monitoring specific base changes in response to various experimental conditions or strain backgrounds, and for isolating new mutator strains.

Palindromy and the location of deletion endpoints in Escherichia coli

The contributions of direct and inverted repeats to deletion formation were studied by characterizing Ampr revertants of plasmids with a series of insertion mutations at a specific site in the pBR322 ampicillin resistance (amp) gene. The inserts at this site are palindromic, variable in length, and bracketed by 9- or 10-bp direct repeats of amp sequence. There is an additional direct repeat composed of 4 bp within the insert and 4 bp of adjoining amp sequence. DNA sequencing and colony hybridization of Ampr revertants showed that they contained either the parental amp sequence, implying deletion endpoints in the flanking 9- or 10-bp repeats, or a specific 1-bp substitution, implying endpoints in the 4-bp repeats. Although generally direct repeats seem to be used as deletion endpoints with a frequency proportional to their lengths, we found that with uninterrupted palindromes longer than 32 bp, the majority of deletions ended in the 4 bp, not the 9- or 10-bp repeats. This preferential use of the shorter direct repeats associated with palindromes is interpreted according to a DNA synthesis-error model in which hairpin structures formed by intrastrand pairing foster the slippage of nascent strands during DNA synthesis.

Mechanisms of mutagenesis in the Escherichia coli mutator mutD5: role of DNA mismatch repair

To investigate the mechanisms of spontaneous mutation in the Escherichia coli mutD5 mutator strain, 502 mutations generated in this strain in the N-terminal part of the lacI gene were sequenced (i-d mutations). Since the mutator strength of this strain depends on the medium in which it grows, mutations were analyzed in both minimal medium (moderate mutator activity) and rich medium (high mutator activity). In either case, 95% of all mutations were base substitutions and 5% were single-base deletions. However, the nature and site distribution of the base substitutions differed dramatically for the two conditions. In minimal medium (mutation frequency, 480-fold above background), a majority (62%) were transversions, notably A.T----T.A at three 5'-GTGG-3' sequences. Most (64%) of the transitions under this condition occurred at specific sequences that are suggestive of a "dislocation" type of mutagenesis. In rich medium (mutation frequency, 37,000-fold above background), 90% of the base substitutions were transitions. These observations suggest that different modes of mutagenesis operate under the two conditions. mutD5 cells have been reported to be defective in exonucleolytic proofreading during DNA replication. The present data suggest that mutD cells in rich medium also suffer a defect in mutHLS-encoded mismatch correction. This hypothesis was confirmed by the direct measurement of mismatch repair in mutD5 cells by transfection of M13mp2 heteroduplex DNA.

An analysis of the mutagenicity of 1,2-dibromoethane to Escherichia coli: influence of DNA repair activities and metabolic pathways

The mutagenicity of 1,2-dibromoethane (EDB) to Escherichia coli was reduced by the UV light-induced excision repair system but unaffected by the loss of a major apurinic/apyrimidinic site repair function. At high doses, 70-90% of the EDB-induced mutations were independent of SOS-mutagenic processing and approximately 50% were independent of glutathione conjugation. The SOS-independent mutations induced by EDB were unaffected by the enzymes that repair alkylation-induced DNA lesions. EDB-induced base substitutions were dominated by GC to AT and AT to GC transitions. These results suggest that EDB-induced premutagenic lesions have some, but not all, of the characteristics of simple alkyl lesions.

In vivo "photofootprint" changes at sequences between the yeast GAL1 upstream activating sequence and "TATA" element require activated GAL4 protein but not a functional TATA element

Transcription of the yeast GAL1 and GAL10 genes is induced by growth on galactose. Using the technique of photofootprinting in vivo, we previously documented equivalent transcription-dependent footprints within the putative "TATA" elements of both genes. To explore the functional significance of these observations, we created a 3-base-pair substitution mutation within the GAL1 promoter TATA element, which disrupted the ATATAA consensus sequence but left intact the photomodification targets. The mutation reduced galactose-induced RNA levels by a factor of 100. The mutant promoter no longer displayed the characteristic TATA sequence footprint, supporting the hypothesis that transcription activation involves the binding of a TATA box factor. We also observed a collection of transcription-correlated alterations in the modification pattern at sites between the UASG and the GAL1 TATA element, within sequences that are not required for inducible transcription. These patterns, characteristic of the induced wild-type GAL1 gene, were still galactose inducible with the TATA mutant GAl1 promoter, despite the low level of transcription from this promoter. We conclude that the GAL4-dependent protein/DNA structure responsible for the altered pattern within nonessential sequences is therefore not strictly coupled to an active TATA element or to high levels of expression. Nonetheless, the patterns probably reflect a stable protein-dependent structure that accompanies assembly of the transcription initiation complex.

Induction of base substitution mutations by aflatoxin B1 is mucAB dependent in Escherichia coli

Recovery of aflatoxin B1-induced base substitution mutations in Escherichia coli was almost completely dependent on the presence of the SOS-mutagenesis-enhancing operon mucAB+; the normal E. coli analog, umuDC+, was not sufficient. Yet aflatoxin B1 induced the SOS response, including the umuDC operon, as well as did UV light. Neither preinduction of the SOS response nor the presence of additional copies of umuDC+ allowed the recovery of aflatoxin B1-induced base substitutions. Thus, the premutagenic DNA lesions induced by aflatoxin B1 reveal a functional difference between UmuDC and MucAB. We estimate that in the presence of MucAB the probability that aflatoxin B1-induced DNA lesions will be converted into mutations is increased at least 10-fold.

Loss of an apurinic/apyrimidinic site endonuclease increases the mutagenicity of N-methyl-N'-nitro-N-nitrosoguanidine to Escherichia coli

xthA- Escherichia coli, which are missing a major cellular apurinic/apyrimidinic (AP) endonuclease, are 5- to 10-fold more sensitive than xthA+ bacteria to mutagenesis by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) under conditions that induce the "adaptive response." The xthA(-)-dependent mutations are also dependent on SOS mutagenic processing and consist of both transversion and transition base substitutions. When MNNG-adapted xthA- bacteria are challenged with a high dose of MNNG, more xthA(-)-dependent SOS-dependent mutations are induced, and transversions are enhanced relative to transitions. The mutations induced by challenge are eliminated in xthA- alkA- bacteria, which are also deficient for 3-methyladenine glycosylase II activity. These data are consistent with the hypothesis that AP sites, at least some of which are produced by glycosylase activity, are mutagenic intermediates following cellular DNA alkylation.

Target sequences for mutagenesis in Salmonella histidine-requiring mutants

Nucleotide target sequences involved in reversion to the wild type phenotype are diagrammed for Salmonella frameshift histidine-requiring mutants hisD3052, hisD3018, hisD6610, and hisD6580 and for base-substitution mutants hisG46 and hisG428. Frameshift strain hisC3076 probably reverts by nucleotide changes similar to those that occur during reversion of hisD3018 and hisD6610. Multiple modes of reversion characterize each strain. Each strain also has a particularly diagnostic mutagen-susceptible sequence. These highly mutagen-susceptible stretches are the hisD3052 GCGCGCGC sequence, the hisD6610 CCCCCC sequence, the hisD6580 AAAAA sequence, and the A/T containing codon of hisG428 and G/C containing codon of hisG46, respectively. Between them, hisG46 and hisG428 are reverted by all of the six possible base substitution transition and transversion mutations.