Hybridization of nucleic acids on solid surfaces is a key process involved in high-throughput technologies such as microarrays and, in some cases, next-generation sequencing (NGS). A physical understanding of the hybridization process helps to determine the accuracy of these technologies. The goal of a widespread research program is to develop reliable transformations between the raw signals reported by the technologies and individual molecular concentrations from an ensemble of nucleic acids. This research has inputs from many areas, from bioinformatics and biostatistics, to theoretical and experimental biochemistry and biophysics, to computer simulations. A group of leading researchers met in Ploen Germany in 2011 to discuss present knowledge and limitations of our physico-chemical understanding of high-throughput nucleic acid technologies. This meeting inspired us to write this summary, which provides an overview of the state-of-the-art approaches based on physico-chemical foundation to modeling of the nucleic acids hybridization process on solid surfaces. In addition, practical application of current knowledge is emphasized

A. Buhot

A. E. Pozhitkov

A. Halperin

A. Harrison

A. Ott

Amend

B. M. Pettitt

Berger

Binder

Bolstad

Bullard

Burden

C. Gibas

C. J. Burden

Chou

Czypionka

D. P. Kreil

D. Tautz

E. Carlon

Fasold

Fiche

Fuchs

H. Binder

Halperin

Harr

Harrison

Heim

Held

Hooyberghs

Huettel

Iltumur

Irizarry

Irving

J. Hooyberghs

Kane

L. J. Gamble

Letowski

Liebich

Lockhart

Luebke

Marshall

Matveeva

Mueckstein

Mulders

Naiser

P. A. Noble

Pingel

Pozhitkov

R. Levicky

Relogio

Rouillard

Tanaka

Trapp

Upton

Vainrub

Wodicka

Zhang

Nucleic Acids Research

English

PubMed

International audienceHybridization of nucleic acids on solid surfaces is a key process involved in high-throughput technologies such as microarrays and, in some cases, next-generation sequencing (NGS). A physical understanding of the hybridization process helps to determine the accuracy of these technologies. The goal of a widespread research program is to develop reliable transformations between the raw signals reported by the technologies and individual molecular concentrations from an ensemble of nucleic acids. This research has inputs from many areas, from bioinformatics and biostatistics, to theoretical and experimental biochemistry and biophysics, to computer simulations. A group of leading researchers met in Ploen Germany in 2011 to discuss present knowledge and limitations of our physico-chemical understanding of high-throughput nucleic acid technologies. This meeting inspired us to write this summary, which provides an overview of the state-of-the-art approaches based on physico-chemical foundation to modeling of the nucleic acids hybridization process on solid surfaces. In addition, practical application of current knowledge is emphasized

Harrison, Andrew

Binder, Hans

Buhot, Arnaud

Burden, Conrad J

Carlon, Enrico

Gibas, Cynthia

Gamble, Lara J

Halperin, Avraham

Hooyberghs, Jef

Kreil, David P

Levicky, Rastislav

Noble, Peter A

Ott, Albrecht

Pettitt, B Montgomery

Tautz, Diethard

Pozhitkov, Alexander E

Hal - Université Grenoble Alpes

Physico-chemical foundations underpinning microarray and next-generation sequencing experiments.

Crossref

Physico-chemical foundations underpinning microarray and next-generation sequencing experiments

Hybridization of nucleic acids on solid surfaces is a key process involved in high-throughput technologies such as microarrays and, in some cases, nextgeneration sequencing (NGS). A physical understanding of the hybridization process helps to determine the accuracy of these technologies. The goal of a widespread research program is to develop reliable transformations between the raw signals reported by the technologies and individual molecular concentrations from an ensemble of nucleic acids. This research has inputs from many areas, from bioinformatics and biostatistics, to theoretical and experimental biochemistry and biophysics, to computer simulations. A group of leading researchers met in Ploen Germany in 2011 to discuss present knowledge and limitations of our physico-chemical understanding of high-throughput nucleic acid technologies. This meeting inspired us to write this summary, which provides an overview of the state-of-the-art approaches based on physicochemical foundation to modeling of the nucleic acids hybridization process on solid surfaces. In addition, practical application of current knowledge is emphasized. © The Author(s) 2013

Harrison, A

Binder, H

Buhot, A

Burden, CJ

Carlon, E

Gibas, C

Gamble, LJ

Halperin, A

Hooyberghs, J

Kreil, DP

Levicky, R

Noble, PA

Ott, A

Pettitt, BM

Tautz, D

Pozhitkov, AE

University of Essex Research Repository

Harrison, Andrew B.

Burden, Conrad John

Gamble, Lara J.

Kreil, David

Noble, Peter A.

Pettitt, B. Montgomery

Pozhitkov, Alexander E.

Warwick Research Archives Portal Repository

A comparison of normalization methods for high density oligonucleotide array data based on variance and bias.

A competitive hybridization model predicts probe signal intensity on high density DNA microarrays.

A model of molecular interactions on short oligonucleotide microarrays.

A model-based background adjustment for oligonucleotide expression arrays.

Accurate prediction of binding thermodynamics for DNA on surfaces.

Adsorption models of hybridisation and post-hybridisation behaviour on oligonucleotide microarrays.

An evaluation of custom microarray applications: the oligonucleotide design challenge.

Assessment of the sensitivity and speciﬁcity of oligonucleotide (50mer) microarrays.

Beyond Affymetrix arrays: expanding the set of known hybridization isotherms and observing pre-wash signal intensities.

Brush effects on DNA chips: thermodynamics, kinetics and design guidelines.

Characterization and improvement of RNA-Seq precision in quantitative transcript expression proﬁling.

Comparison of algorithms for the analysis of Affymetrix microarray data as evaluated by co-expression of genes in known operons.

Computing equilibrium concentrations for large heterodimerization networks Phys.

Coulomb blockage of hybridization in two-dimensional DNA arrays.

Data for Expression Algorithm Assessment.

Design of nucleic acid sequences for DNA computing based on a thermodynamic approach.

Designing better probes: effect of probe size, mismatch position and number on hybridization in DNA oligonucleotide microarrays.

Direct calibration of PICKY-designed microarrays.

DNA surface hybridization regimes.

DNA surface hybridization: comparison of theory and experiment.

Effects formamide of formamide on the thermal stability of DNA duplexes on biochips.

Effects of aneuploidy on genome structure, expression, and interphase organization in Arabidopsis thaliana.

Empirical establishment of oligonucleotide probe design criteria.

Establishing a major cause of discrepancy in the calibration of Affymetrix GeneChips.

Estimating RNA-quality using GeneChip microarrays.

Evaluation of statistical methods for normalization and differential expression in mRNA-Seq experiments.

Exploration, normalization, and summaries of high density oligonucleotide array probe level data.

Expression monitoring by hybridization to high-density oligonucleotide arrays.

Feature-level exploration of the Choe et al. Affymetrix GeneChip control dataset.

Fluorescence, XPS, and ToF-SIMS surface chemical state image analysis of DNA microarrays.

From hybridization theory to microarray data analysis: performance evaluation.

G-spots cause incorrect expression measurement in Affymetrix microarrays.

G-stack modulated probe intensities on expression arrays–sequence corrections and signal calibration.

Genome-wide expression monitoring in Saccharomyces cerevisiae.

Getting the noise out of gene arrays.

Hook’-calibration of GeneChip-microarrays: Chip characteristics and expression measures. Algorithms Mol.

Hook’-calibration of GeneChip-microarrays: theory and algorithm’’.

Hybridisation thermodynamic parameters allow accurate detection of point mutations with DNA microarrays.

Hybridization at a surface: the role of spacers in DNA microarrays.

Hybridization isotherms of DNA microarrays and the quantiﬁcation of mutation studies.

Hybridization thermodynamics of NimbleGen microarrays.

Improvement of oligonucleotide probe design criteria for functional gene microarrays in environmental applications.

Interactions in oligonucleotide duplexes upon hybridisation of microarrays.

Inverse Langmuir method for oligonucleotide microarray analysis.

Linking probe thermodynamics to microarray quantiﬁcation.

Magnasco: a ‘‘corrective make-up’’ program for microarray chips.

Mismatch- and G-stack modulated probe signals on SNP-microarrays.

Model-based probe set optimization for high-performance microarrays.

Modeling of DNA microarray data by using physical properties of hybridization.

NCBI GEO: mining tens of millions of expression proﬁles—database and tools update.

Non-speciﬁc hybridization scaling of microarray expression estimates - a physico–chemical approach for chip-to-chip normalization.

OligoArray 2.0: design of oligonucleotide probes for DNA microarrays using a thermodynamic approach.

On the causes of outliers in Affymetrix GeneChip data.

On the hybirdization isotherms of DNA microarrays: the langmuir model and its extensions.

Optimization of oligonucleotide-based DNA microarrays.

Optimization of probe length and the number of probes per gene for optimal microarray analysis of gene expression.

Physical-chemistry-based analysis of Affymetrix microarray data.

Physico-chemical modelling of target depletion during hybridization on oligonucleotide microarrays.

Picky: oligo microarray design for large genomes.

Platform speciﬁc T7-ampliﬁcation biases revealed by analysis of thousands of microarray data sets with implications for cross-platform comparisons.

Point mutation detection by surface plasmon resonance imaging coupled with a temperature scan method in a model system.

Position dependent mismatch discrimination on DNA microarrays -experiments and model.

Prioritized selection of oligodeoxyribonucleotide probes for efﬁcient hybridization to RNA transcripts.

Probe selection for high-density oligonucleotide arrays.

Probes containing runs of guanines provide insights into the biophysics and bioinformatics of Affymetrix GeneChips’’.

Probing hybridization parameters from microarray experiments: nearest-neighbor model and beyond.

Quantifying microbial communities with 454 pyrosequencing, does read abundance count?

Relationship between gene expression and observed intensities in DNA microarrays—a model study.

Revision of the nonequilibrium thermal dissociation and stringent washing approaches for identiﬁcation of mixed nucleic acid targets by microarrays.

Salt concentration effects on equilibrium melting curves from DNA microarrays.

Selection of optimal oligonucleotide probes for microarrays using multiple criteria, global alignment and parameter estimation.

Sensitivity, speciﬁcity and the hybridization isotherms of DNA chips.

Stability of a surface-bound oligonucleotide duplex inferred from molecular dynamics: a study of single nucleotide defects using DNA microarrays.

Stability of double-stranded oligonucleotide DNA with a bulged loop: a microarray study.

Statistical analysis of adsorption models for oligonucleotide microarrays.

Strand-speciﬁc transcriptome proﬁling with directly labeled RNA on genomic tiling microarrays.

Structure and DNA hybridization properties of mixed nucleic acid/maleimide-ethylene glycol monolayers.

Summaries of Affymetrix GeneChip probe level data.

Temperature effects on DNA chip experiments from surface plasmon resonance imaging: isotherms and melting curves.

Temperature scans/cycles for the detection of low abundant DNA point mutations on microarrays.

Tests of rRNA hybridization to microarrays suggest that hybridization characteristics of oligonucleotide probes for species discrimination cannot be predicted.

The constitution and fundamental properties of solids and liquids.

The detection of blur in Affymetrix GeneChips.

The illusion of speciﬁc capture: surface and solution studies of suboptimal oligonucleotide hybridization. In review.

Thermodynamic calculations and statistical correlations for oligo-probes design.

Thermodynamics of association to a molecule immobilized in an electric double layer.

Thermodynamics of competitive surface adsorption on DNA microarrays.

Transcriptome changes after genome-wide admixture in invasive sculpins (Cottus).

Understanding the physics of oligonucleotide microarrays: the Affymetrix spike-in data reanalysed.

Versatile maskless microscope projection photolithography system and its application in light-directed fabrication of DNA microarrays.

Washing scaling of GeneChip microarray expression.

Hybridization of nucleic acids on solid surfaces is a key process involved in high-throughput technologies such as microarrays and, in some cases, nextgeneration sequencing (NGS). A physical understanding of the hybridization process helps to determine the accuracy of these technologies. The goal of a widespread research program is to develop reliable transformations between the raw signals reported by the technologies and individual molecular concentrations from an ensemble of nucleic acids. This research has inputs from many areas, from bioinformatics and biostatistics, to theoretical and experimental biochemistry and biophysics, to computer simulations. A group of leading researchers met in Ploen Germany in 2011 to discuss present knowledge and limitations of our physico-chemical understanding of high-throughput nucleic acid technologies. This meeting inspired us to write this summary, which provides an overview of the state-of-the-art approaches based on physicochemical foundation to modeling of the nucleic acids hybridization process on solid surfaces. In addition, practical application of current knowledge is emphasized

Harrison, A.

Physico-chemical foundations underpinning microarray and next-generation sequencing experiments

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