Richard Segraves

Assembly of microarrays for genome-wide measurement of DNA copy number.

We have assembled arrays of approximately 2,400 BAC clones for measurement of DNA copy number across the human genome. The arrays provide precise measurement (s.d. of log2 ratios=0.05–0.10) in cell lines and clinical material, so that we can reliably detect and quantify high-level amplifications and single-copy alterations in diploid, polyploid and heterogeneous backgrounds.

Quantitative mapping of amplicon structure by array CGH identifies CYP24 as a candidate oncogene

We show here that quantitative measurement of DNA copy number across amplified regions using array comparative genomic hybridization (CGH) may facilitate oncogene identification by providing precise information on the locations of both amplicon boundaries and amplification maxima. Using this analytical capability, we resolved two regions of amplification within an approximately 2-Mb region of recurrent aberration at 20q13.2 in breast cancer. The putative oncogene ZNF217 (ref. 5) mapped to one peak, and CYP24 (encoding vitamin D 24 hydroxylase), whose overexpression is likely to lead to abrogation of growth control mediated by vitamin D (ref. 6), mapped to the other.

Breast tumor copy number aberration phenotypes and genomic instability

BackgroundGenomic DNA copy number aberrations are frequent in solid tumors, although the underlying causes of chromosomal instability in tumors remain obscure. Genes likely to have genomic instability phenotypes when mutated (e.g. those involved in mitosis, replication, repair, and telomeres) are rarely mutated in chromosomally unstable sporadic tumors, even though such mutations are associated with some heritable cancer prone syndromes.MethodsWe applied array comparative genomic hybridization (CGH) to the analysis of breast tumors. The variation in the levels of genomic instability amongst tumors prompted us to investigate whether alterations in processes/genes involved in maintenance and/or manipulation of the genome were associated with particular types of genomic instability.ResultsWe discriminated three breast tumor subtypes based on genomic DNA copy number alterations. The subtypes varied with respect to level of genomic instability. We find that shorter telomeres and altered telomere related gene expression are associated with amplification, implicating telomere attrition as a promoter of this type of aberration in breast cancer. On the other hand, the numbers of chromosomal alterations, particularly low level changes, are associated with altered expression of genes in other functional classes (mitosis, cell cycle, DNA replication and repair). Further, although loss of function instability phenotypes have been demonstrated for many of the genes in model systems, we observed enhanced expression of most genes in tumors, indicating that over expression, rather than deficiency underlies instability.ConclusionMany of the genes associated with higher frequency of copy number aberrations are direct targets of E2F, supporting the hypothesis that deregulation of the Rb pathway is a major contributor to chromosomal instability in breast tumors. These observations are consistent with failure to find mutations in sporadic tumors in genes that have roles in maintenance or manipulation of the genome.

High-Resolution Mapping of Genotype-Phenotype Relationships in Cri du Chat Syndrome Using Array Comparative Genomic Hybridization

We have used array comparative genomic hybridization to map DNA copy-number changes in 94 patients with cri du chat syndrome who had been carefully evaluated for the presence of the characteristic cry, speech delay, facial dysmorphology, and level of mental retardation (MR). Most subjects had simple deletions involving 5p (67 terminal and 12 interstitial). Genotype-phenotype correlations localized the region associated with the cry to 1.5 Mb in distal 5p15.31, between bacterial artificial chromosomes (BACs) containing markers D5S2054 and D5S676; speech delay to 3.2 Mb in 5p15.32-15.33, between BACs containing D5S417 and D5S635; and the region associated with facial dysmorphology to 2.4 Mb in 5p15.2-15.31, between BACs containing D5S208 and D5S2887. These results overlap and refine those reported in previous publications. MR depended approximately on the 5p deletion size and location, but there were many cases in which the retardation was disproportionately severe, given the 5p deletion. All 15 of these cases, approximately two-thirds of the severely retarded patients, were found to have copy-number aberrations in addition to the 5p deletion. Restriction of consideration to patients with only 5p deletions clarified the effect of such deletions and suggested the presence of three regions, MRI-III, with differing effect on retardation. Deletions including MRI, a 1.2-Mb region overlapping the previously defined cri du chat critical region but not including MRII and MRIII, produced a moderate level of retardation. Deletions restricted to MRII, located just proximal to MRI, produced a milder level of retardation, whereas deletions restricted to the still-more proximal MRIII produced no discernible phenotype. However, MR increased as deletions that included MRI extended progressively into MRII and MRIII, and MR became profound when all three regions were deleted.

Shaping of tumor and drug-resistant genomes by instability and selection

Tumors with defects in mismatch repair (MMR) show fewer chromosomal changes by cytogenetic analyses than most solid tumors, suggesting that a greater proportion of the alterations required for malignancy occur in genes with nucleotide sequences susceptible to errors normally corrected by MMR. Here, we used genome-wide microarray comparative genomic hybridization to carry out a higher resolution evaluation of the effect of MMR competence on genomic alterations occurring in 20 cell lines and to determine if characteristic aberrations arise in MMR-proficient and -deficient HCT116 cells undergoing selection for methotrexate resistance. We observed different spectra of aberrations in MMR-proficient compared to -deficient cell lines, as well as among cell lines with different types of MMR-deficiency. We also observed different genetic routes to drug resistance. Resistant MMR-deficient cells most frequently displayed no copy number alterations (16/29 cell pools), whereas all MMR-proficient cells had unique abnormalities involving chromosome 5, including amplicons centered on the target gene, DHFR and/or a neighboring novel locus (7/13 pools). These observations support the concept that tumor genomes are shaped by selection for alterations that promote survival and growth advantage, as well as by the particular dysfunctions in genes responsible for maintenance of genetic integrity.

Array-based comparative genomic hybridization from formalin-fixed, paraffin-embedded breast tumors.

Identification of prognostic and predictive genomic markers requires long-term clinical follow-up of patients. Extraction of high-quality DNA from archived formalin-fixed, paraffin-embedded material is essential for such studies. Of particular importance is a robust reproducible method of whole genome amplification for small tissue samples. This is especially true for high-resolution analytical approaches because different genomic regions and sequences may amplify differentially. We have tested a number of protocols for DNA amplification for array-based comparative genomic hybridization (CGH), in which relative copy number of the entire genome is measured at 1 to 2 mb resolution. Both random-primed amplification and degenerate oligonucleotide-primed amplification approaches were tested using varying amounts of fresh and paraffin-extracted normal and breast tumor input DNAs. We found that random-primed amplification was clearly superior to degenerate oligonucleotide-primed amplification for array-based CGH. The best quality and reproducibility strongly depended on accurate determination of the amount of input DNA using a quantitative polymerase chain reaction-based method. Reproducible and high-quality results were attained using 50 ng of input DNA, and some samples yielded quality results with as little as 5 ng input DNA. We conclude that random-primed amplification of DNA isolated from paraffin sections is a robust and reproducible approach for array-based CGH analysis of archival tumor samples.

Detection of single clone deletions using array CGH: Identification of submicroscopic deletions in the 22q11.2 deletion syndrome as a model system

Constitutional submicroscopic DNA copy number alterations have been shown to cause numerous medical genetic syndromes, and are suspected to occur in a portion of cases for which the causal events remain undiscovered. Array comparative genomic hybridization (array CGH) allows high‐throughput, high‐resolution genome scanning for DNA dosage aberrations and thus offers an attractive approach for both clinical diagnosis and discovery efforts. Here we assess this capability by applying array CGH to the analysis of copy number alterations in 44 patients with a phenotype of the 22q11.2 deletion syndrome. Twenty‐five patients had the deletion on chromosome 22 characteristic of this syndrome as determined by fluorescence in situ hybridization (FISH). The array measurements were in complete concordance with the FISH analysis, supporting their diagnostic utility. These data show that a genome‐scanning microarray has the level of sensitivity and specificity required to prospectively interrogate and identify single copy number aberrations in a clinical setting. We demonstrate that such technology is ideally suited for microdeletion syndromes such as 22q11.2.

Technical approaches for efficient, high precision nucleic acid analysis using DNA microarrays

Microarray measurements offer the potential to compare the abundances of numerous nucleic acid sequences in parallel. Using linker-adapter PCR products from mapped BAC clones we have made arrays that permit scanning the human genome for single copy gains and losses of DNA sequence, which requires reliable detection of 50 percent changes. The DNA is printed at high concentration on amino-silane or chromium coated surface using a custom-built capillary pin printing system. Spots are printed on 130 micrometers centers or closer to minimize the size of the arrays. Hybridization occurs in a dextran sulfate/formamide buffer at 37 degrees C, using slow rocking to mix the reaction. The entire array is imaged in a single CCD frame using a custom built system that employs mercury arc illumination. Up to four fluorochromes can be imaged from a single array with adequate spectral separation. Typically we use DAPI to stain the DNA in the array spots to facilitate automatic image segmentation during analysis, and fluorescein, Cy3, and Cy5 or their spectral equivalents, for labeling specimen nucleic acids. Array spots are segmented and quantitative fluorescence intensities and intensity ratios are automatically calculated in < 1 minute per approximately 8000 element array using the custom software UCSF SPOT.

High-efficiency microarray printer using fused-silica capillary tube printing pins.

We describe a contact printing approach for microarrays that uses fused-silica capillary tubes with tapered tips for printing pins and a pressure/vacuum system to control pin loading, printing, and cleaning. The printing process is insensitive to variable environmental factors such as humidity, and the small diameter of the pins allows routine printing from 1536 well source plates. Pin load capacity, 0.2 microL in the current system, is adjustable by controlling pin length. More than 2000 spots can be printed per 0.2-microL pin load (<100 pl/spot), and densities of >12,000 spots/cm(2) are readily achievable. Solutions with a wide range of viscosities and chemical properties can be printed. The system can print tens of thousands of different solutions at high speed, due to the ability to use large numbers of pins simultaneously, and can produce a large number of replicate arrays since all of the solution picked up by the pins is available for deposition.

Genomic DNA Microarray for Comparative Genomic Hybridization

Publisher Summary This chapter describes a polymerase chain reaction (PCR)-based method for producing large quantities of BAC DNA, which aims at maximizing the representation of each bacterial artificial chromosome (BAC). Ligation-mediated PCR is used as a template in a Re-PCR reaction to generate DNA for spotting. Hybridization of fluorescently labeled genomic DNA for array CGH analysis involves distributing 1 g of dextran sulfate over the entire length of a 15-ml tube. While holding the tube horizontally, one needs to squirt in 5 ml of formamide. One needs to carefully aspirate and discard the supernatant, while wiping excess liquid from the tube with a tissue paper. One should be careful not to disturb the pellet. The next step involves placing the slides in the Stratalinker with arrays facing up. The arrays should be given a fixed amount of energy instead of the other available options the Stratalinker might have, such as autocrosslink or time. Overcross-linking the slide might result in a decrease in fluorescent hybridization signal.