Abstract
Microarray data is subject to noise and systematic variation that negatively affects the resolution of copy number analysis. We describe Rawcopy, an R package for processing of Affymetrix CytoScan HD, CytoScan 750k and SNP 6.0 microarray raw intensities (CEL files). Noise characteristics of a large number of reference samples are used to estimate log ratio and B-allele frequency for total and allele-specific copy number analysis. Rawcopy achieves better signal-to-noise ratio and higher proportion of validated alterations than commonly used free and proprietary alternatives. In addition, Rawcopy visualizes each microarray sample for assessment of technical quality, patient identity and genome-wide absolute copy number states. Software and instructions are available at http://rawcopy.org.
Similar content being viewed by others
Introduction
DNA copy number alteration is an important mutational process in evolution, population genomics, genetic disorders and cancer development1. Gain and loss of gene copies may lead to extreme overexpression, absence of any functional transcript, or modest alterations in gene expression2. Genome-wide copy number analysis is commonly performed in hypothesis-generating genomics research, including many recent large-scale cancer studies3. It is also growing rapidly in clinical diagnostics as a high-resolution alternative or complement to in situ chromosome analysis4,5.
While recent advances of low-cost sequencing indicate that whole-genome sequencing may eventually become the all-in-one solution for clinical genome analysis, most copy number analysis is currently performed using microarrays6. Originally designed for genotyping, several brands of SNP microarrays are now marketed specifically for copy number analysis7. Due to their simplicity of operation and relatively manageable data analysis, the use of microarrays for copy number analysis has continued to rise in both cancer and constitutional cytogenetics8. It also remains standard practice in cancer genomics studies for which many thousands of samples have been published and made available for data mining by the Cancer Genome Atlas9 and at the Gene Expression Omnibus10.
DNA microarray signal intensities are subject to noise and systematic variation incurred by factors such as laboratory conditions, reagent quality, non-uniform DNA extraction efficiency along the genome and probe cross-hybridization. This variation limits the resolution and precision by which copy number alterations can be detected and can be quantified using the Median of Absolute Pairwise Differences between adjacent probes (MAPD). Some systematic variation can be removed using patient- or population-matched reference samples processed in an otherwise identical fashion. Systematic variation that affects samples similarly but with different strength, such as GC-content related waviness, can then be further normalized for in individual samples11.
Estimating the copy number per cell using extracted DNA from populations of cells has some important limitations. As a fixed amount of DNA is analyzed rather than a fixed number of cells, any multiple of the true set of copy numbers would result in the same observation on the microarray. This is well exemplified by the aneuploidies encountered in cancer genomes, where the total amount of hybridization to the microarray does not reflect the total amount of DNA per cell in the sample. The microarray intensities are median centered to account for variation in total hybridization to the array, with the median intensity corresponding to the median copy number in the genome(s) analyzed. The intensities may also be compared to those of a reference pool of samples or a patient-matched normal sample to account for systematic variation or constitutional copy number variation. Estimation of absolute copy numbers, which has been thoroughly explored in recent years, takes place downstream from basic normalization of raw signal intensities and achieves estimates of the most likely absolute copy numbers given the observations12,13,14.
The normalized intensity per probe relative to the reference is usually log transformed to equalize noise levels over different copy number states, producing the log ratio, a measure of DNA abundance along the genome. Saturation effects in microarray hybridization lead to a non-linear relationship between sample DNA abundance and hybridization intensity. Therefore, log ratio is not generally translated into DNA abundance15.
Bi-allelic (SNP) probes on the microarray can, in addition to genotyping and heterozygosity mapping, be used for copy number analysis in an allele-specific manner. This results in estimates of the actual number of each parental homologous chromosomal copy per cell12,13,14. Allele-specific signal intensities per SNP probe are usually processed as estimates of the B-allele abundance relative to the total DNA abundance, called the B-allele frequency (BAF), ranging from near zero for homozygous A SNPs to near one for homozygous B SNPs.
Downstream analysis of log ratio and BAF includes segmentation (partitioning into segments) of the genome, for which several types of algorithms are in use. Hidden Markov Models use the expected log ratio associated with given copy number states to assign the most likely segment breakpoints given the observations, and are popular in constitutional cytogenetics where the genome can be assumed to be near-diploid and homogeneous. Circular Binary Segmentation (CBS) estimates segment break points without prior assumptions of the amplitude of change incurred by copy number alterations, and is more suitable for cancer genomics where the average ploidy and purity are unknown16.
Once segments have been defined, copy number states may be assigned to them based either on deviation from median log ratio, in which case gain and loss are defined relative to the median copy number of the genome, or using more complex analysis of segment log ratio and BAF to estimate the absolute copy numbers per cell. For Affymetrix SNP microarrays, most data analysis is performed using one of the following solutions: Chromosome Analysis Suite (or Genotyping Console for older arrays) is a proprietary solution for Windows systems freely available from Affymetrix. Affymetrix Power Tools is an open source command-line alternative to Chromosome Analysis Suite (ChAS), running on Linux and Mac OS. Nexus Copy Number is commercial software from Biodiscovery Inc., Hawthorne. Other free processing tools for SNP 6.0 have been shown to achieve similar or lower-quality results than Affymetrix Power Tools in previous comparisons17,18, but not many have been updated to support the current CytoScanHD array. Unfortunately, the general lack of a gold standard in combination with high false-positive rates and profound differences in segmentation strategy between available methods make it difficult to objectively compare performance19. We set out to build an open-source solution for processing of Affymetrix SNP 6.0 and CytoScan raw data (CEL files), aiming for better performance than currently available free and proprietary alternatives.
Rawcopy, described here, is a processing tool for Affymetrix CytoScan HD, CytoScan 750k and SNP 6.0 arrays. We demonstrate reduced systematic variation in log ratio and BAF compared to the currently most widely used alternatives, as well as improved prediction accuracy for copy number gain and loss.
Rawcopy is freely available as an installable R package. It is intended to provide the highest quality normalization of log ratio and B-allele frequency, suitable for downstream analysis with a range of tools. It also provides genome segmentation and several visualizations to facilitate assessment of data quality and results. The solutions presented here may also be adopted for processing of other types of microarrays and for sequencing-based copy number analysis.
Methods
Rawcopy is available as an R package installable under Linux, Mac OS and Windows. Processing time per sample is 10–20 minutes depending on processor speed. The analysis may be run in parallel on multiple processor cores, with each thread requiring less than 8 GB of RAM. Apart from the R package, only sample raw intensity files are required to run the analysis. Reference data are built-in and precompiled from a large number of ethnically diverse samples, with variations also in technical quality (Supplementary Table 1). Users may also use their own reference samples. Rawcopy is available at www.rawcopy.org.
The processing of new samples is described in the sections below and is schematically shown in Fig. 1. B-allele frequency for SNP probes is estimated using reference sample genotypes, with normalization for total probe intensity. Total DNA abundance per probe (log ratio) is estimated by comparing total probe intensities to the reference data and normalizing for sample-specific effects such as GC content and fragment length bias. Partitioning of chromosomes into segments of unchanging copy number (segmentation) is performed using the Parent-Specific CBS method20. Samples are then further processed to facilitate downstream analysis, including sample identity level matching, estimation of median log ratio and allelic imbalance per gene and genomic segment, and clustering and visualization of the sample set.
Samples are loaded into Rawcopy from raw intensity (CEL) files. Log ratio of SNP probes is based on the Euclidean sum (R) of individual allele A and B mean intensities ( and . the array contains up to four physical probes for each SNP probe set and allele):
Log ratio of non-SNP probes is based on log2 of their raw intensities. Log ratio is composed of both SNP and non-SNP probes, these are merged during the normalization process. BAF is calculated from the raw BAF per SNP probe set:
Data processed with Rawcopy are suitable for downstream analysis using a range of tools, including ABSOLUTE14, ASCAT12, Nexus Copy Number and TAPS13.
Log ratio processing
Log ratio of all probes is calculated using built-in reference data (listed in Supplementary Table 1). For each probe, reference log R (SNPs) or log intensity (non-SNPs) are stored in Rawcopy as a linear function of median log2 probe intensity (the amount of hybridization to the microarray) and the raw experimental variation (raw MAPD) of the reference samples, as shown in Fig. 2A. After subtracting the reference value for each probe, given the median hybridization and MAPD of the new sample, log ratio represents logarithmized observations of hybridization relative to the reference level.
Fragment length and GC content bias, which differs between samples (Fig. 2B), are then adjusted for separately in each sample by median-centering the log ratio within percentiles of both fragment length and GC content. Raw BAF is also used to adjust the log ratio of SNPs linearly for correlation between genotype and log ratio in the reference data.
To describe additional systematic variation in the reference material, autosomal log ratio of all reference samples were subjected to multidimensional scaling (MDS), compressing them from one dimension per probe into a few components. The vast majority of variation in the reference material was expected to be noise rather than copy number alterations, and this was also indicated by the data as samples that deviated from the average along any component were associated with more noise (higher MAPD, Fig. 2C). For most probes, the log ratio of reference samples correlated with their component scores (Fig. 2D). This correlation was weaker for each additional component in the MDS (data not shown). Six components were selected as a balance between reducing noise and minimizing data storage in Rawcopy. Linear functions of these six components (for which each sample has a score) are stored in Rawcopy and used to reduce noise for each probe by subtracting the function value, given sample component scores, from the observed log ratio. When processing a new sample, the score giving the lowest MAPD is determined and used for each of the six components.
If a local set of reference samples is available, a local reference file can be built and used to further reduce noise and waviness. This is achieved by subtracting the median local reference log ratio from that of the query sample, for each probe.
B-allele frequency estimation
Due to background hybridization and the possibility of unequal specific and non-specific hybridization of the two alleles, the raw BAF defined in Formula 2 cannot be assumed to accurately represent the true BAF. In Rawcopy, the raw BAF associated with each normal diploid genotype (AA, AB and BB) in the reference material is stored in Rawcopy as a function of the “log R” defined in Formula 1. Examples of SNPs with well-defined genotype clusters are shown in Fig. 3A,B.
A subset of SNPs (35% of CytoScan, 44% of SNP 6.0) displayed either poorly separated clusters or no variation in genotype among the reference samples. The reference data for those SNPs are therefore considered low-quality. An example of such a SNP is shown in Fig. 3C. The criteria used for high-quality SNPs was three clusters and a total cluster sum of squares relative to the number of reference samples of at least 0.018. Inclusion of low-quality SNP data is optional in Rawcopy. Heterozygosity rates for SNPs associated with high- and low-quality reference data are presented in Supplementary Fig. 1. When processing new samples, Rawcopy estimates the BAF of each SNP as shown in Fig. 3D, given the observed “log R” and raw BAF.
Genome segmentation
The segmentation step available in Rawcopy uses the PSCBS package20. Once segment break points have been determined, segments are annotated with median log ratio, number of probes, genes and cytoband. Allelic imbalance for genomic segments is quantified in the same way as in TAPS13. Segment tables are written to tab-separated text files for browsing and further analysis.
Data visualization
After processing of log ratio, BAF and segmentation, whole-genome and chromosome-wise figures are plotted for each sample. These allow the user to assess technical quality of individual samples such as total hybridization level and quality of the physical array, and get an extensive overview of chromosomal alterations as shown in Fig. 4.
To visualize the copy number throughout the genome, scatter plots of total copy number and allelic imbalance are shown throughout each chromosome relative to the rest of the genome (Fig. 4E). This is equivalent to a previously published solution13,15 and can be used to indicate the absolute number of copies involved in copy number alterations, mosaicism, and the ploidy and purity of cancer samples. In the scatter plots, the median log ratio of each segment (about 1 Mb long) is transformed into estimates of DNA abundance relative to the median of the current sample. Cancer cell line samples21 were used to set the expected log ratio given 50% loss (log ratio: −0.6), 50% gain (log ratio: 0.35) and 100% gain (log ratio: 0.6) of DNA abundance relative to the median of the genome. (Individual samples may deviate slightly from this model for technical reasons.) Allelic imbalance is measured for each segment by first clustering abs(BAF-0.5) on two means, representing the separation of heterozygous and homozygous SNPs (BAFhet and BAFhom), then quantifying the separation of BAFhet relative to BAFhom:
Assuming heterozygous SNPs exist and are separated into two bands due to imbalanced copy number, allelic imbalance represents estimates of the absolute difference in the copy number of each parental homologue (H) relative to their sum (the total copy number):
Due to noise in BAF estimates, segments where the copy number is balanced or homozygous result in measured allelic imbalances just above 0 or below 1, respectively (Fig. 4E). The scatter plots are annotated with the expected allelic imbalance given a 1:1, 1:2 and 1:3 ratio of homologous copies.
The pairwise genotype dissimilarities of all samples processed together are plotted as shown in Fig. 4F. BAF is discretized into B-allele presence (1 if BAF ≥ 0.2, else 0), reducing the effect of systematic and copy number variation while largely retaining genotype information on sample identity level. Pairwise dissimilarities (sum of differences in B-allele presence) between samples are then visualized in a distogram22, using a color gradient based on observed dissimilarities between related and unrelated members of HapMap CEU. In addition to validating sample identities relative to one another, the sample identity distogram may indicate cell or DNA contamination.
Results and Discussion
Two large sets of publicly available samples were acquired from the Gene Expression Omnibus (GEO) for systematic benchmarking of performance relative to some of the most commonly used free and proprietary processing tools. For the Affymetrix SNP 6.0 platform, a set of 947 cancer cell lines23 published by the Broad Institute, Massachusetts (GEO accession number: GSE36138) was analyzed using Affymetrix Power Tools, Nexus Copy Number and Rawcopy. For the Affymetrix CytoScan HD platform, a set of 231 hepatocellular carcinomas24 published by the Gachon University of Incheon, South Korea (GEO accession number: GSE54504) was analyzed using Affymetrix Power Tools, Nexus Copy Number, ChAS and Rawcopy. In addition, this set of samples was analyzed with Rawcopy using the included matched normal samples as local reference data to further reduce noise.
Reduced log ratio noise relative to true signal
The most commonly used metric of technical quality in microarray copy number analysis is MAPD which estimates the amplitude of log ratio noise in a way that is largely unaffected by copy number alterations. As the majority of adjacent measurements of log ratio should be the same, the median of their absolute pairwise differences are frequently relied upon to compare technical quality across samples with different distributions of copy number states. However as some methods employ normalization steps that alter the distribution of the data, such as quantile normalization, the MAPD may not be comparable across different processing tools. In cancer samples with large copy number alterations, MAPD may be adjusted based on the observed effects of copy number alteration on log ratio. We defined the signal-adjusted pairwise difference (SAPD) as the MAPD divided by the effect Δ of copy number alteration on log ratio with the current processing tool, relative to the average effect over a set of different processing tools (given the same sample and copy number alteration):
MAPD and SAPD were calculated for each sample and each processing tool in the evaluation. For each sample in the evaluation data, the two autosomes with the highest and lowest median log ratio was selected for calculating Δ with all processing tools. Samples with little or no evidence of copy number alteration were removed ( less than 0.2). SAPD of the evaluation samples are shown for Rawcopy and the commonly used current processing tools in Fig. 5.
Improved estimates of B allele frequency
Rawcopy and Nexus Copy Number both provide estimates of the B allele frequency for each SNP, but Nexus Copy Number truncates the data at zero and one. ChAS provides Allele Difference (sometimes called Allele Peaks) representing the difference between log2(A) and log2(B). These different approaches result in similarly useful but somewhat different allelic data that is shown in Fig. 6. Rawcopy and Nexus achieve better separation and stability of SNPs with near-equal abundance of the A and B allele compared to ChAS (6A). Rawcopy also achieves the best separation of homozygous and near-homozygous SNPs (6B-C). Rawcopy BAF is less skewed by total DNA abundance than Nexus BAF (6B,D). To obtain a quantitative measure of the quality of the BAF normalization (Rawcopy and Nexus) the standard deviation of heterozygous SNPs (BAF 0.75 to 0.25) for each HapMap sample was measured and found to be 0.059 on average for Nexus and significantly lower for Rawcopy with 0.048 on average (p < 2.2*10−16). Rawcopy uses a subset of high-quality SNP probes while Nexus uses all SNP probes. To control for this difference we measured the standard deviation of the BAF normalized with Nexus for the high-quality heterozygous SNPs used by Rawcopy and found it to still be significantly higher than for Rawcopy (0.052 on average p = 5*10−6). A similar comparison with variation in allelic signals provided by ChAS could not be performed since ChAS only provides Allele Difference.
Prediction accuracy for copy number alterations
The ability to identify alterations identical by decent was investigated for Rawcopy, ChAS and Nexus Copy Number, using 52 HapMap trios analyzed on Affymetrix current generation of high-density SNP arrays (CytoScanHD). Data normalized with Rawcopy or Nexus Copy Number were segmented using the same method (rank CBS in Nexus) to avoid any differences introduced by segmentation settings. Segment median log-ratio thresholds were >0.2 for gains and <−0.3 for deletions. ChAS was run with its default HMM segmentation. For each method, alterations detected in children were considered validated if also detected with at least 90% overlap in one parent. Total number of altered segments and median and cumulative segment lengths in the trios are shown for all three methods in Fig. 7A–C. ChAS identified and the most numerous but relatively short alterations, while Rawcopy detected the longest cumulative alteration length per sample (median 4 Mb compared to 2.5 Mb for ChAS, p = 7.7*10−11). Nexus produced the smallest median of both total number of alterations and cumulative length. Rawcopy showed the highest prediction accuracy (calculated as previously by Nutsua et al.18) as shown in Fig. 8A, Median prediction accuracy for Rawcopy was 59%, significantly higher than ChAS (44%, p < 2.2*10−16) and Nexus (53%, p = 0.0010). The proportion of overlap between validated alterations detected with the different methods was calculated for each trio and their medians are shown in Fig. 8B. A median of 48% of the validated alterations were uniquely detected by Rawcopy, consistent with Rawcopy’s larger cumulative length of detected alterations (7C).
Significance
Rawcopy makes copy number analysis easy to set up, as only installation of the R-package is required to start processing CEL files. The large built-in reference data lead to better quality of the copy number data, i.e. reduced noise relative to signal, better prediction accuracy and more accurate BAF compared to the most widely used free and proprietary alternatives. A noise level threshold such as MAPD is the most commonly used quality metric for SNP microarrays, but differences in the signal distribution achieved by different processing tools preclude direct comparison of MAPD between them. MAPD was corrected for such differences, allowing us to compare noise between processing tools. Use of SAPD over MAPD is not suggested when processing new samples in general as it is intended for comparing tools, not samples. All new samples cannot be expected to harbor copy number alterations of sufficient length and amplitude to make signal-to-noise assessment practical.
Figures generated by Rawcopy allow immediate assessment of individual sample quality and copy number profile, and technical issues such as DNA quality and microarray fabrication errors can be identified on individual arrays. The sample identity distogram can indicate mislabeled samples and reveal DNA or cell contamination.
Rawcopy is suitable for copy number and heterozygosity analysis of both tumour and constitutional DNA. Absolute allele-specific copy numbers may be estimated using scatter plots of median log ratio versus allelic imbalance for genomic segments, even for cancer samples with extensive aneuploidy, low purity or subclonal heterogeneity13. Copy number analysis of DNA extractions from populations of cells is ambiguous in nature as there may be more than one set of absolute copy numbers per cell that would explain the composition of a DNA sample. With Rawcopy, we have built a tool capable of revealing rich information about the copy number profile, but without applying any automatic classification or interpretation (such as purity and ploidy for cancer samples) that could fail for samples with an unforeseen chromosomal setup. Arguably such interpretations should be done taking into account the specific disease and its frequency of specific karyotypes and genome doublings, as done in ABSOLUTE14. However, even then many samples cannot be correctly resolved as alternative solutions may be near-equally plausible. If the interpretation impacts diagnosis or other clinical decisions, cell-based chromosome or ploidy analysis may be motivated as a complement to the microarray. If specific estimates of genome-wide of absolute allele-specific copy numbers (i.e. numeric data for further analysis) are required, the output generated by Rawcopy is suitable for downstream analysis tools such as ABSOLUTE, ASCAT or TAPS. The reduction of systematic BAF bias and reduced BAF variation achieved in Rawcopy also makes BAF a more accurate representation of true allele ratio and more likely to fit theoretical models of cell fractions with certain copy number states.
Conclusion
Rawcopy is a freely available R package that provides improved normalization of Affymetrix SNP arrays for copy number analysis. It achieves improved signal-to-noise ratio and prediction accuracy compared to commonly used alternatives. Rawcopy also facilitates interpretation of complex and heterogeneous copy number profiles through visualization of log ratio and allelic imbalance, and the output is compatible with several alternatives for downstream analysis. Included in the package is also a powerful feature for plotting of SNP genotype dissimilarities between samples in a batch, which may be indicative of DNA contamination or mislabeled sample identities. Using this feature helps ensure that there are no apparent patient identity level errors in the data set.
Availability and requirements
Project name: Rawcopy
Project home page: http://rawcopy.org
Operating systems: Linux, OSX and Windows
Programming language: R
Other requirements: Minimum 8GB of RAM
License: GNU General Public License
Any restrictions to use by non-academics: No
Availability of data and materials
Rawcopy is free software and may be redistributed and/or modified under the terms of the GNU General Public License as published by the Free Software Foundation; version 2. Installation, execution and access are described at http://rawcopy.org. The set of 947 cancer cell lines is available at GEO with accession number GSE36138. The set of 231 hepatocellular carcinomas is available at GEO with accession number GSE54504. The individual SNP 6.0 reference samples (BRCA, COAD, GBM and LUAD non-cancer samples were used as references) as well as samples used as examples can be obtained from TCGA upon request (https://tcga-data.nci.nih.gov/tcga/). Individual Swedish clinical CytoScan HD reference samples are not publically available. Individual HapMap CytoScan HD/750k reference samples can be obtained from Affymetrix Inc. upon request.
Ethics
The research use of the clinical samples collected in Uppsala, Sweden, was approved by the Regional Ethical Review Board in Uppsala (2010/236). Informed consent was obtained from all patients and all experiments were performed in accordance with relevant guidelines and regulations.
Additional Information
How to cite this article: Mayrhofer, M. et al. Rawcopy: Improved copy number analysis with Affymetrix arrays. Sci. Rep. 6, 36158; doi: 10.1038/srep36158 (2016).
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
References
Zarrei, M., MacDonald, J. R., Merico, D. & Scherer, S. W. A copy number variation map of the human genome. Nat. Rev. Genet. 16, 172–183 (2015).
Curtis, C. et al. The genomic and transcriptomic architecture of 2,000 breast tumours reveals novel subgroups. Nature 486, 346–352 (2012).
Ciriello, G. et al. Emerging landscape of oncogenic signatures across human cancers. Nat. Genet. 45, 1127–1133 (2013).
Ambros, I. M., Brunner, C., Abbasi, R., Frech, C. & Ambros, P. F. Ultra-High Density SNParray in Neuroblastoma Molecular Diagnostics. Front. Oncol. 4 (2014).
Lee, C.-N. et al. Clinical utility of array comparative genomic hybridisation for prenatal diagnosis: a cohort study of 3171 pregnancies. BJOG Int. J. Obstet. Gynaecol. 119, 614–625 (2012).
Brady, P. D. & Vermeesch, J. R. Genomic microarrays: a technology overview. Prenat. Diagn. 32, 336–343 (2012).
Li, W. & Olivier, M. Current analysis platforms and methods for detecting copy number variation. Physiol. Genomics 45, 1–16 (2013).
Uddin, M. et al. A high-resolution copy-number variation resource for clinical and population genetics. Genet. Med. doi: 10.1038/gim.2014.178 (2014).
The Cancer Genome Atlas Home Page. The Cancer Genome Atlas - National Cancer Institute Available at: http://cancergenome.nih.gov/. (Accessed: 1st June 2015).
Barrett, T. et al. NCBI GEO: archive for functional genomics data sets—update. Nucleic Acids Res. 41, D991–D995 (2013).
Marioni, J. C. et al. Breaking the waves: improved detection of copy number variation from microarray-based comparative genomic hybridization. Genome Biol. 8, R228 (2007).
Van Loo, P. et al. Allele-specific copy number analysis of tumors. Proc. Natl. Acad. Sci. USA 107, 16910–16915 (2010).
Rasmussen, M. et al. Allele-specific copy number analysis of tumor samples with aneuploidy and tumor heterogeneity. Genome Biol. 12, R108 (2011).
Carter, S. L. et al. Absolute quantification of somatic DNA alterations in human cancer. Nat. Biotechnol. doi: 10.1038/nbt.2203 (2012).
Mayrhofer, M. Copy number analysis of cancer. (Acta Universitatis Upsaliensis, 2015).
Basics of CNV Calling Algorithms HMM, CBS, Rank Segmentation. Available at: http://resources.biodiscovery.com/videos/basics-of-cnv-calling-algorithms. (Accessed: 13th September 2016).
Eckel-Passow, J. E., Atkinson, E. J., Maharjan, S., Kardia, S. L. & Andrade, M. de . Software comparison for evaluating genomic copy number variation for Affymetrix 6.0 SNP array platform. BMC Bioinformatics 12, 220 (2011).
Nutsua, M. E. et al. Family-Based Benchmarking of Copy Number Variation Detection Software. Plos One 10, e0133465 (2015).
Winchester, L., Yau, C. & Ragoussis, J. Comparing CNV detection methods for SNP arrays. Brief. Funct. Genomic. Proteomic. 8, 353–366 (2009).
Olshen, A. B. et al. Parent-specific copy number in paired tumor–normal studies using circular binary segmentation. Bioinformatics 27, 2038–2046 (2011).
Xie, Y. et al. The Human Glioblastoma Cell Culture Resource: Validated Cell Models Representing All Molecular Subtypes. EBioMedicine 2, 1351–1363 (2015).
Eklund, A. C. Squash: Color-Based Plots for Multivariate Visualization (2015).
Barretina, J. et al. The Cancer Cell Line Encyclopedia enables predictive modelling of anticancer drug sensitivity. Nature 483, 603–607 (2012).
Ahn, S.-M. et al. Genomic portrait of resectable hepatocellular carcinomas: implications of RB1 and FGF19 aberrations for patient stratification. Hepatol. Baltim. Md 60, 1972–1982 (2014).
Acknowledgements
The authors acknowledge funding from Uppsala County Council, the Swedish Cancer Research Fund and Lions Cancer Research Fund Uppsala-Örebro. Ann-Charlotte Thuresson and the Department of immunology, genetics and pathology, Uppsala University, are acknowledged for making CytoScan HD reference samples available. Affymetrix provided additional HapMap CytoScan HD and CytoScan 750k reference samples. The Cancer Genome Atlas project is acknowledged for non-cancer SNP 6.0 reference samples.
Author information
Authors and Affiliations
Contributions
M.M. and B.V. designed and developed Rawcopy. M.M., B.V. and A.I. wrote the manuscript. A.I. supervised the project. The final manuscript was read and approved by all authors.
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Electronic supplementary material
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Mayrhofer, M., Viklund, B. & Isaksson, A. Rawcopy: Improved copy number analysis with Affymetrix arrays. Sci Rep 6, 36158 (2016). https://doi.org/10.1038/srep36158
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep36158
- Springer Nature Limited
This article is cited by
-
Multi-dimensional scaling techniques unveiled gain1q&loss13q co-occurrence in Multiple Myeloma patients with specific genomic, transcriptional and adverse clinical features
Nature Communications (2024)
-
Clinical and molecular findings in three Japanese patients with N-acetylneuraminic acid synthetase-congenital disorder of glycosylation (NANS-CDG)
Scientific Reports (2022)
-
The diagnostic utility of DNA copy number analysis of core needle biopsies from soft tissue and bone tumors
Laboratory Investigation (2022)
-
Single-nuclei and bulk-tissue gene-expression analysis of pheochromocytoma and paraganglioma links disease subtypes with tumor microenvironment
Nature Communications (2022)
-
RNAseqCNV: analysis of large-scale copy number variations from RNA-seq data
Leukemia (2022)