DNA microarray

A DNA microarray (also commonly known as DNA chip or biochip) is a collection of microscopic DNA spots attached to a solid surface. Scientists use DNA microarrays to measure the expression levels of large numbers of genes simultaneously or to genotype multiple regions of a genome. Each DNA spot contains picomoles (10−12 moles) of a specific DNA sequence, known as probes (or reporters or oligos). These can be a short section of a gene or other DNA element that are used to hybridize a cDNA or cRNA (also called anti-sense RNA) sample (called target) under high-stringency conditions. Probe-target hybridization is usually detected and quantified by detection of fluorophore-, silver-, or chemiluminescence-labeled targets to determine relative abundance of nucleic acid sequences in the target.

Principle

Hybridization of the target to the probe.
For more details on this topic, see DNA microarray experiment.

The core principle behind microarrays is hybridization between two DNA strands, the property of complementary nucleic acid sequences to specifically pair with each other by forming hydrogen bonds between complementary nucleotide base pairs. A high number of complementary base pairs in a nucleotide sequence means tighter non-covalent bonding between the two strands. After washing off non-specific bonding sequences, only strongly paired strands will remain hybridized. Fluorescently labeled target sequences that bind to a probe sequence generate a signal that depends on the hybridization conditions (such as temperature), and washing after hybridization. Total strength of the signal, from a spot (feature), depends upon the amount of target sample binding to the probes present on that spot. Microarrays use relative quantitation in which the intensity of a feature is compared to the intensity of the same feature under a different condition, and the identity of the feature is known by its position.

The steps required in a microarray experiment.

Uses and types

Two Affymetrix chips. A match is shown at bottom left for size comparison.

Many types of arrays exist and the broadest distinction is whether they are spatially arranged on a surface or on coded beads:

DNA microarrays can be used to detect DNA (as in comparative genomic hybridization), or detect RNA (most commonly as cDNA after reverse transcription) that may or may not be translated into proteins. The process of measuring gene expression via cDNA is called expression analysis or expression profiling.

Applications include:

Application or technology Synopsis
Gene expression profiling In an mRNA or gene expression profiling experiment the expression levels of thousands of genes are simultaneously monitored to study the effects of certain treatments, diseases, and developmental stages on gene expression. For example, microarray-based gene expression profiling can be used to identify genes whose expression is changed in response to pathogens or other organisms by comparing gene expression in infected to that in uninfected cells or tissues.[1]
Comparative genomic hybridization Assessing genome content in different cells or closely related organisms.[2][3]
GeneID Small microarrays to check IDs of organisms in food and feed (like GMO ), mycoplasms in cell culture, or pathogens for disease detection, mostly combining PCR and microarray technology.
Chromatin immunoprecipitation on Chip DNA sequences bound to a particular protein can be isolated by immunoprecipitating that protein (ChIP), these fragments can be then hybridized to a microarray (such as a tiling array) allowing the determination of protein binding site occupancy throughout the genome. Example protein to immunoprecipitate are histone modifications (H3K27me3, H3K4me2, H3K9me3, etc.), Polycomb-group protein (PRC2:Suz12, PRC1:YY1) and trithorax-group protein (Ash1) to study the epigenetic landscape or RNA Polymerase II to study the transcription landscape.
DamID Analogously to ChIP, genomic regions bound by a protein of interest can be isolated and used to probe a microarray to determine binding site occupancy. Unlike ChIP, DamID does not require antibodies but makes use of adenine methylation near the protein's binding sites to selectively amplify those regions, introduced by expressing minute amounts of protein of interest fused to bacterial DNA adenine methyltransferase.
SNP detection Identifying single nucleotide polymorphism among alleles within or between populations.[4] Several applications of microarrays make use of SNP detection, including genotyping, forensic analysis, measuring predisposition to disease, identifying drug-candidates, evaluating germline mutations in individuals or somatic mutations in cancers, assessing loss of heterozygosity, or genetic linkage analysis.
Alternative splicing detection An exon junction array design uses probes specific to the expected or potential splice sites of predicted exons for a gene. It is of intermediate density, or coverage, to a typical gene expression array (with 1-3 probes per gene) and a genomic tiling array (with hundreds or thousands of probes per gene). It is used to assay the expression of alternative splice forms of a gene. Exon arrays have a different design, employing probes designed to detect each individual exon for known or predicted genes, and can be used for detecting different splicing isoforms.
Fusion genes microarray A Fusion gene microarray can detect fusion transcripts, e.g. from cancer specimens. The principle behind this is building on the alternative splicing microarrays. The oligo design strategy enables combined measurements of chimeric transcript junctions with exon-wise measurements of individual fusion partners.
Tiling array Genome tiling arrays consist of overlapping probes designed to densely represent a genomic region of interest, sometimes as large as an entire human chromosome. The purpose is to empirically detect expression of transcripts or alternatively spliced forms which may not have been previously known or predicted.
Double-stranded B-DNA microarrays Right-handed double-stranded B-DNA microarrays can be used to characterize novel drugs and biologicals that can be employed to bind specific regions of immobilized, intact, double-stranded DNA. This approach can be used to inhibit gene expression.[5][6][7] They also allow for characterization of their structure under different environmental conditions.
Double-stranded Z-DNA microarrays Left-handed double-stranded Z-DNA microarrays can be used to identify short sequences of the alternative Z-DNA structure located within longer stretches of right-handed B-DNA genes (e.g., transcriptional enhancement, recombination, RNA editing).[5][6][7][8] The microarrays also allow for characterization of their structure under different environmental conditions.
Multi-stranded DNA microarrays (triplex-DNA microarrays and quadruplex-DNA microarrays) Multi-stranded DNA and RNA microarrays can be used to identify novel drugs that bind to these multi-stranded nucleic acid sequences. This approach can be used to discover new drugs and biologicals that have the ability to inhibit gene expression.[5][6][7][9][10] These microarrays also allow for characterization of their structure under different environmental conditions.

Fabrication

Microarrays can be manufactured in different ways, depending on the number of probes under examination, costs, customization requirements, and the type of scientific question being asked. Arrays may have as few as 10 probes or up to 2.1 million micrometre-scale probes from commercial vendors.

Spotted vs. in situ synthesised arrays

A DNA microarray being printed by a robot at the University of Delaware

Microarrays can be fabricated using a variety of technologies, including printing with fine-pointed pins onto glass slides, photolithography using pre-made masks, photolithography using dynamic micromirror devices, ink-jet printing,[11][12] or electrochemistry on microelectrode arrays.

In spotted microarrays, the probes are oligonucleotides, cDNA or small fragments of PCR products that correspond to mRNAs. The probes are synthesized prior to deposition on the array surface and are then "spotted" onto glass. A common approach utilizes an array of fine pins or needles controlled by a robotic arm that is dipped into wells containing DNA probes and then depositing each probe at designated locations on the array surface. The resulting "grid" of probes represents the nucleic acid profiles of the prepared probes and is ready to receive complementary cDNA or cRNA "targets" derived from experimental or clinical samples. This technique is used by research scientists around the world to produce "in-house" printed microarrays from their own labs. These arrays may be easily customized for each experiment, because researchers can choose the probes and printing locations on the arrays, synthesize the probes in their own lab (or collaborating facility), and spot the arrays. They can then generate their own labeled samples for hybridization, hybridize the samples to the array, and finally scan the arrays with their own equipment. This provides a relatively low-cost microarray that may be customized for each study, and avoids the costs of purchasing often more expensive commercial arrays that may represent vast numbers of genes that are not of interest to the investigator. Publications exist which indicate in-house spotted microarrays may not provide the same level of sensitivity compared to commercial oligonucleotide arrays,[13] possibly owing to the small batch sizes and reduced printing efficiencies when compared to industrial manufactures of oligo arrays.

In oligonucleotide microarrays, the probes are short sequences designed to match parts of the sequence of known or predicted open reading frames. Although oligonucleotide probes are often used in "spotted" microarrays, the term "oligonucleotide array" most often refers to a specific technique of manufacturing. Oligonucleotide arrays are produced by printing short oligonucleotide sequences designed to represent a single gene or family of gene splice-variants by synthesizing this sequence directly onto the array surface instead of depositing intact sequences. Sequences may be longer (60-mer probes such as the Agilent design) or shorter (25-mer probes produced by Affymetrix) depending on the desired purpose; longer probes are more specific to individual target genes, shorter probes may be spotted in higher density across the array and are cheaper to manufacture. One technique used to produce oligonucleotide arrays include photolithographic synthesis (Affymetrix) on a silica substrate where light and light-sensitive masking agents are used to "build" a sequence one nucleotide at a time across the entire array.[14] Each applicable probe is selectively "unmasked" prior to bathing the array in a solution of a single nucleotide, then a masking reaction takes place and the next set of probes are unmasked in preparation for a different nucleotide exposure. After many repetitions, the sequences of every probe become fully constructed. More recently, Maskless Array Synthesis from NimbleGen Systems has combined flexibility with large numbers of probes.[15]

Two-channel vs. one-channel detection

Diagram of typical dual-colour microarray experiment.

Two-color microarrays or two-channel microarrays are typically hybridized with cDNA prepared from two samples to be compared (e.g. diseased tissue versus healthy tissue) and that are labeled with two different fluorophores.[16] Fluorescent dyes commonly used for cDNA labeling include Cy3, which has a fluorescence emission wavelength of 570 nm (corresponding to the orange part of the light spectrum), and Cy5 with a fluorescence emission wavelength of 670 nm (corresponding to the red part of the light spectrum). The two Cy-labeled cDNA samples are mixed and hybridized to a single microarray that is then scanned in a microarray scanner to visualize fluorescence of the two fluorophores after excitation with a laser beam of a defined wavelength. Relative intensities of each fluorophore may then be used in ratio-based analysis to identify up-regulated and down-regulated genes.[17]

Oligonucleotide microarrays often carry control probes designed to hybridize with RNA spike-ins. The degree of hybridization between the spike-ins and the control probes is used to normalize the hybridization measurements for the target probes. Although absolute levels of gene expression may be determined in the two-color array in rare instances, the relative differences in expression among different spots within a sample and between samples is the preferred method of data analysis for the two-color system. Examples of providers for such microarrays includes Agilent with their Dual-Mode platform, Eppendorf with their DualChip platform for colorimetric Silverquant labeling, and TeleChem International with Arrayit.

In single-channel microarrays or one-color microarrays, the arrays provide intensity data for each probe or probe set indicating a relative level of hybridization with the labeled target. However, they do not truly indicate abundance levels of a gene but rather relative abundance when compared to other samples or conditions when processed in the same experiment. Each RNA molecule encounters protocol and batch-specific bias during amplification, labeling, and hybridization phases of the experiment making comparisons between genes for the same microarray uninformative. The comparison of two conditions for the same gene requires two separate single-dye hybridizations. Several popular single-channel systems are the Affymetrix "Gene Chip", Illumina "Bead Chip", Agilent single-channel arrays, the Applied Microarrays "CodeLink" arrays, and the Eppendorf "DualChip & Silverquant". One strength of the single-dye system lies in the fact that an aberrant sample cannot affect the raw data derived from other samples, because each array chip is exposed to only one sample (as opposed to a two-color system in which a single low-quality sample may drastically impinge on overall data precision even if the other sample was of high quality). Another benefit is that data are more easily compared to arrays from different experiments as long as batch effects have been accounted for.

One channel microarray may be the only choice in some situations. Suppose i samples need to be compared: then the number of experiments required using the two channel arrays quickly becomes unfeasible, unless a sample is used as a reference.

number of samples one-channel microarray two channel microarray

two channel microarray (with reference)

1 1 1 1
2 2 1 1
3 3 3 2
4 4 6 3
i i i!/2!(i-2)! i -1

Microarrays and bioinformatics

Gene expression values from microarray experiments can be represented as heat maps to visualize the result of data analysis.

The advent of inexpensive microarray experiments created several specific bioinformatics challenges:

Experimental design

Due to the biological complexity of gene expression, the considerations of experimental design that are discussed in the expression profiling article are of critical importance if statistically and biologically valid conclusions are to be drawn from the data.

There are three main elements to consider when designing a microarray experiment. First, replication of the biological samples is essential for drawing conclusions from the experiment. Second, technical replicates (two RNA samples obtained from each experimental unit) help to ensure precision and allow for testing differences within treatment groups. The biological replicates include independent RNA extractions and technical replicates may be two aliquots of the same extraction. Third, spots of each cDNA clone or oligonucleotide are present as replicates (at least duplicates) on the microarray slide, to provide a measure of technical precision in each hybridization. It is critical that information about the sample preparation and handling is discussed, in order to help identify the independent units in the experiment and to avoid inflated estimates of statistical significance.[18]

Standardization

Microarray data is difficult to exchange due to the lack of standardization in platform fabrication, assay protocols, and analysis methods. This presents an interoperability problem in bioinformatics. Various grass-roots open-source projects are trying to ease the exchange and analysis of data produced with non-proprietary chips:

Data analysis

Microarray data sets are commonly very large, and analytical precision is influenced by a number of variables. Statistical challenges include taking into account effects of background noise and appropriate normalization of the data. Normalization methods may be suited to specific platforms and, in the case of commercial platforms, the analysis may be proprietary. Algorithms that affect statistical analysis include:

Microarray data may require further processing aimed at reducing the dimensionality of the data to aid comprehension and more focused analysis.[31] Other methods permit analysis of data consisting of a low number of biological or technical replicates; for example, the Local Pooled Error (LPE) test pools standard deviations of genes with similar expression levels in an effort to compensate for insufficient replication.[32]

Relation between probe and gene

The relation between a probe and the mRNA that it is expected to detect is not trivial. Some mRNAs may cross-hybridize probes in the array that are supposed to detect another mRNA. In addition, mRNAs may experience amplification bias that is sequence or molecule-specific. Thirdly, probes that are designed to detect the mRNA of a particular gene may be relying on genomic EST information that is incorrectly associated with that gene.

Data warehousing

Microarray data was found to be more useful when compared to other similar datasets. The sheer volume of data, specialized formats (such as MIAME), and curation efforts associated with the datasets require specialized databases to store the data. A number of open-source data warehousing solutions, such as InterMine and BioMart, have been created for the specific purpose of integrating diverse biological datasets, and also support analysis.

Alternative technologies

Advances in massively parallel sequencing has led to the development of RNA-Seq technology, that enables a whole transcriptome shotgun approach to characterize and quantify gene expression.[33][34] Unlike microarrays, which need a reference genome and transcriptome to be available before the microarray itself can be designed, RNA-Seq can also be used for new model organisms whose genome has not been sequenced yet.[34]

Multi-stranded DNA Microarray

[35]This figure shows the anchoring of eight different DNA and RNA molecules onto a DNA microarray surface.

Glossary

Glossary of gene expression terms
Protocol (natural sciences)

See also

References

  1. Adomas A; Heller G; Olson A; Osborne J; Karlsson M; Nahalkova J; Van Zyl L; Sederoff R; Stenlid J; Finlay R; Asiegbu FO (2008). "Comparative analysis of transcript abundance in Pinus sylvestris after challenge with a saprotrophic, pathogenic or mutualistic fungus". Tree Physiol. 28 (6): 885–897. doi:10.1093/treephys/28.6.885. PMID 18381269.
  2. Pollack JR; Perou CM; Alizadeh AA; Eisen MB; Pergamenschikov A; Williams CF; Jeffrey SS; Botstein D; Brown PO (1999). "Genome-wide analysis of DNA copy-number changes using cDNA microarrays". Nat Genet 23 (1): 41–46. doi:10.1038/14385. PMID 10471496.
  3. Moran G; Stokes C; Thewes S; Hube B; Coleman DC; Sullivan D (2004). "Comparative genomics using Candida albicans DNA microarrays reveals absence and divergence of virulence-associated genes in Candida dubliniensis". Microbiology 150 (Pt 10): 3363–3382. doi:10.1099/mic.0.27221-0. PMID 15470115.
  4. Hacia JG; Fan JB; Ryder O; Jin L; Edgemon K; Ghandour G; Mayer RA; Sun B; Hsie L; Robbins CM; Brody LC; Wang D; Lander ES; Lipshutz R; Fodor SP; Collins FS (1999). "Determination of ancestral alleles for human single-nucleotide polymorphisms using high-density oligonucleotide arrays". Nat Genet 22 (2): 164–167. doi:10.1038/9674. PMID 10369258.
  5. 1 2 3 Gagna, Claude E.; Lambert, W. Clark (2009-05-01). "Novel multistranded, alternative, plasmid and helical transitional DNA and RNA microarrays: implications for therapeutics". Pharmacogenomics 10 (5): 895–914. doi:10.2217/pgs.09.27. ISSN 1744-8042. PMID 19450135.
  6. 1 2 3 Gagna, Claude E.; Lambert, W. Clark (2006-01-01). "Novel drug discovery and molecular biological methods, via DNA, RNA and protein changes using structure-function transitions: Transitional structural chemogenomics, transitional structural chemoproteomics and novel multi-stranded nucleic acid microarray". Medical Hypotheses 67 (5): 1099–1114. doi:10.1016/j.mehy.2006.05.020. ISSN 1532-2777. PMID 16828979.
  7. 1 2 3 Gagna, Claude E.; Clark Lambert, W. (2007-03-01). "Cell biology, chemogenomics and chemoproteomics - application to drug discovery". Expert Opinion on Drug Discovery 2 (3): 381–401. doi:10.1517/17460441.2.3.381. ISSN 1746-0441. PMID 23484648.
  8. Gagna, C. E.; Lambert, W. C. (2003-03-01). "The halting arrival of left-handed Z-DNA". Medical Hypotheses 60 (3): 418–423. ISSN 0306-9877. PMID 12581623.
  9. Mukherjee, Anirban; Vasquez, Karen M. (2011-08-01). "Triplex technology in studies of DNA damage, DNA repair, and mutagenesis". Biochimie 93 (8): 1197–1208. doi:10.1016/j.biochi.2011.04.001. ISSN 1638-6183. PMC 3545518. PMID 21501652.
  10. Rhodes, Daniela; Lipps, Hans J. (2015-10-15). "G-quadruplexes and their regulatory roles in biology". Nucleic Acids Research 43 (18): 8627–8637. doi:10.1093/nar/gkv862. ISSN 1362-4962. PMC 4605312. PMID 26350216.
  11. J Biochem Biophys Methods. 2000 Mar 16;42(3):105-10. DNA-printing: utilization of a standard inkjet printer for the transfer of nucleic acids to solid supports. Goldmann T, Gonzalez JS.
  12. Lausted C; et al. (2004). "POSaM: a fast, flexible, open-source, inkjet oligonucleotide synthesizer and microarrayer". Genome Biology 5 (8): R58. doi:10.1186/gb-2004-5-8-r58. PMC 507883. PMID 15287980.
  13. Bammler T, Beyer RP; Consortium, Members of the Toxicogenomics Research; Kerr, X; Jing, LX; Lapidus, S; Lasarev, DA; Paules, RS; Li, JL; Phillips, SO (2005). "Standardizing global gene expression analysis between laboratories and across platforms". Nat Methods 2 (5): 351–356. doi:10.1038/nmeth0605-477a. PMID 15846362.
  14. Pease AC; Solas D; Sullivan EJ; Cronin MT; Holmes CP; Fodor SP (1994). "Light-generated oligonucleotide arrays for rapid DNA sequence analysis". PNAS 91 (11): 5022–5026. doi:10.1073/pnas.91.11.5022. PMC 43922. PMID 8197176.
  15. Nuwaysir EF; Huang W; Albert TJ; Singh J; Nuwaysir K; Pitas A; Richmond T; Gorski T; Berg JP; Ballin J; McCormick M; Norton J; Pollock T; Sumwalt T; Butcher L; Porter D; Molla M; Hall C; Blattner F; Sussman MR; Wallace RL; Cerrina F; Green RD (2002). "Gene Expression Analysis Using Oligonucleotide Arrays Produced by Maskless Photolithography". Genome Res 12 (11): 1749–1755. doi:10.1101/gr.362402. PMC 187555. PMID 12421762.
  16. Shalon D; Smith SJ; Brown PO (1996). "A DNA microarray system for analyzing complex DNA samples using two-color fluorescent probe hybridization". Genome Res 6 (7): 639–645. doi:10.1101/gr.6.7.639. PMID 8796352.
  17. Tang T; François N; Glatigny A; Agier N; Mucchielli MH; Aggerbeck L; Delacroix H (2007). "Expression ratio evaluation in two-colour microarray experiments is significantly improved by correcting image misalignment". Bioinformatics 23 (20): 2686–2691. doi:10.1093/bioinformatics/btm399. PMID 17698492.
  18. Churchill, GA (2002). "Fundamentals of experimental design for cDNA microarrays" (PDF). Nature Genetics. supplement 32: 490–5. doi:10.1038/ng1031. PMID 12454643. Archived from the original (– Scholar search) on 2005-05-08. Retrieved 12 December 2013.
  19. NCTR Center for Toxicoinformatics - MAQC Project
  20. Little, M.A.; Jones, N.S. (2011). "Generalized Methods and Solvers for Piecewise Constant Signals: Part I" (PDF). Proceedings of the Royal Society A. doi:10.1098/rspa.2010.0671.
  21. 1 2 3 Peterson, Leif E. (2013). Classification Analysis of DNA Microarrays. John Wiley and Sons. ISBN 978-0-470-17081-6.
  22. De Souto M et al. (2008) Clustering cancer gene expression data: a comparative study, BMC Bioinformatics, 9(497).
  23. Istepanian R, Sungoor A, Nebel J-C (2011) Comparative Analysis of Genomic Signal Processing for Microarray data Clustering, IEEE Transactions on NanoBioscience, 10(4): 225-238.
  24. Jaskowiak, Pablo A; Campello, Ricardo JGB; Costa, Ivan G. "On the selection of appropriate distances for gene expression data clustering". BMC Bioinformatics 15 (Suppl 2): S2. doi:10.1186/1471-2105-15-S2-S2.
  25. Bolshakova N, Azuaje F (2003) Cluster validation techniques for genome expression data, Signal Processing, Vol. 83, pp. 825–833.
  26. Ben-Gal I., Shani A., Gohr A., Grau J., Arviv S., Shmilovici A., Posch S. and Grosse I. (2005), Identification of Transcription Factor Binding Sites with Variable-order Bayesian Networks, Bioinformatics,vol. 21, no. 11, 2657-2666. Available at http://bioinformatics.oxfordjournals.org/content/21/11/2657.full.pdf?keytype=ref&ijkey=KkxNhRdTSfvtvXY
  27. Yuk Fai Leung and Duccio Cavalieri, Fundamentals of cDNA microarray data analysis. TRENDS in Genetics Vol.19 No.11 November 2003.
  28. Priness I.; Maimon O.; Ben-Gal I. (2007). "Evaluation of gene-expression clustering via mutual information distance measure". BMC Bioinformatics 8 (1): 111. doi:10.1186/1471-2105-8-111. PMC 1858704. PMID 17397530.
  29. Wei C; Li J; Bumgarner RE (2004). "Sample size for detecting differentially expressed genes in microarray experiments". BMC Genomics 5: 87. doi:10.1186/1471-2164-5-87. PMC 533874. PMID 15533245.
  30. Emmert-Streib, F. & Dehmer, M. (2008). Analysis of Microarray Data A Network-Based Approach. Wiley-VCH. ISBN 3-527-31822-4.
  31. Wouters L; Gõhlmann HW; Bijnens L; Kass SU; Molenberghs G; Lewi PJ (2003). "Graphical exploration of gene expression data: a comparative study of three multivariate methods". Biometrics 59 (4): 1131–1139. doi:10.1111/j.0006-341X.2003.00130.x. PMID 14969494.
  32. Jain N; Thatte J; Braciale T; Ley K; O'Connell M; Lee JK (2003). "Local-pooled-error test for identifying differentially expressed genes with a small number of replicated microarrays". Bioinformatics 19 (15): 1945–1951. doi:10.1093/bioinformatics/btg264. PMID 14555628.
  33. Mortazavi, Ali; Brian A Williams; Kenneth McCue; Lorian Schaeffer; Barbara Wold (July 2008). "Mapping and quantifying mammalian transcriptomes by RNA-Seq". Nat Meth 5 (7): 621–628. doi:10.1038/nmeth.1226. ISSN 1548-7091. PMID 18516045. Retrieved 2009-03-13.
  34. 1 2 Wang, Zhong; Mark Gerstein; Michael Snyder (January 2009). "RNA-Seq: a revolutionary tool for transcriptomics". Nat Rev Genet 10 (1): 57–63. doi:10.1038/nrg2484. ISSN 1471-0056. PMC 2949280. PMID 19015660. Retrieved 2009-03-13.
  35. "Multistranded, Alternative, and Helical Transitional DNA and RNA Microarrays: The Next Generation". www.americanlaboratory.com. Retrieved 2016-04-26.

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