Detection of mutations using microarrays of poly(C)10-poly(T)10 modified DNA probes immobilized on agarose films

Allele-specific hybridization to a DNA microarray can be a useful method for genotyping patient DNA. In this article, we demonstrate that 13- to 17-base oligonucleotides tagged with a poly(T)10-poly(C)10 tail (TC tag), but otherwise unmodified, can be crosslinked by UV light irradiation to an agarose film grafted onto unmodified glass. Microarrays of TC-tagged probes immobilized on the agarose film can be used to diagnose mutations in the human beta-globin gene, which encodes the beta-chains in hemoglobin. Although the probes differed widely regarding melting point temperature ( approximately 20 degrees C), a single stringency wash still gave sufficiently high discrimination signals between perfect match and mismatch probes to allow robust mutation detection. In all, 270 genotypings were performed on patient materials, and no genotype was incorrectly classified. Quality control experiments conducted using a target DNA specific for the TC tag of the immobilized probes showed that the spotting and hybridization procedure had a variance of 20%, indicating that signal differences as low as twofold could be detected between perfect match and mismatch. Together, our results show that the use of microarrays of TC-tagged probes that have been immobilized on agarose films grafted onto glass is a robust and inexpensive genotyping method.     

Functionalization of poly(methyl methacrylate) (PMMA) as a substrate for DNA microarrays

A chemical procedure was developed to functionalize poly(methyl methacrylate) (PMMA) substrates. PMMA is reacted with hexamethylene diamine to yield an aminated surface for immobilizing DNA in microarrays. The density of primary NH₂ groups was 0.29 nmol/cm². The availability of these primary amines was confirmed by the immobilization of DNA probes and hybridization with a complementary DNA strand. The hybridization signal and the hybridization efficiency of the chemically aminated PMMA slides were comparable to the hybridization signal and the hybridization efficiency obtained from differently chemically modified PMMA slides, silanized glass, commercial silylated glass and commercial plastic Euray™ slides. Immobilized and hybridized densities of 10 and 0.75 pmol/cm², respectively, were observed for microarrays on chemically aminated PMMA. The immobilized probes were heat stable since the hybridization performance of microarrays subjected to 20 PCR heat cycles was only reduced by 4%. In conclusion, this new strategy to modify PMMA provides a robust procedure to immobilize DNA, which is a very useful substrate for fabricating single use diagnostics devices with integrated functions, like sample preparation, treatment and detection using microfabrication and microelectronic techniques.     

Correlation between microarray DNA hybridization efficiency and the position of short capture probe on the target nucleic acid

The hybridization behavior of small oligonucleotides arrayed on glass slides is currently unpredictable. In order to examine the hybridization efficiency of capture probes along target nucleic acid, 20-mer oligonucleotide probes were designed to hybridize at different distances from the 5' end of two overlapping 402- and 432-bp ermB products amplified from the target DNA. These probes were immobilized via their 5' end onto glass slides and hybridized with the two labeled products. Evaluation of the hybridization signal for each probe revealed an inverse correlation with the length of the 5' overhanging end of the captured strand and the hybridization signal intensity. Further experiments demonstrated that this phenomenon is dependent on the reassociation kinetics of the free overhanging tail of the captured DNA strand with its complementary strand. This study delineates key predictable parameters that govern the hybridization efficiency of short capture probes arrayed on glass slides. This should be most useful for designing arrays for detection of PCR products and nucleotide polymorphisms.     

Fabrication of DNA microarrays using unmodified oligonucleotide probes

Microarrays printed on glass slides are often constructed by covalently linking oligonucleotide probes to a derivatized surface. These procedures typically require relatively expensive amine- or thiol-modified oligonucleotide probes that add considerable expense to larger arrays. We describe a system by which unmodified oligonucleotide probes are bound to either nonderivatized or epoxy-silane-derivatized glass slides. Biotinylated PCR products are heat denatured, hybridized to the arrays, and detected using an enzymatic amplification system. Unmodified probes appear to detach from the slide surface at high pH (> 10.0), suggesting that hydrogen bonding plays a significant role in probe attachment. Regardless of surface preparation, high temperature (up to 65 degrees C) and low ionic strength (deionized water) do not disturb probe attachment; hence, the fabrication method described here is suitable for a wide range of hybridization stringencies and conditions. We illustrate kinetics of room temperature hybridizations for probes attached to nonderivatized slides, and we demonstrate that unmodified probes produce hybridization signals equal to amine-modified, covalently bound probes. Our method provides a cost-effective alternative to conventional attachment strategies that is particularly suitable for genotyping PCR products with nucleic acid microarrays.     

Characterization of an inexpensive, nontoxic, and highly sensitive microarray substrate

An agarose film has been proposed as an efficient substrate for producing microarrays. The original film preparation procedure was simplified significantly by grafting the agarose layer directly onto unmodified microscope glass slides instead of aminated glass slides, and the blocking procedure was replaced with a wash in 0.1x standard saline citrate (SSC) and 0.5% sodium dodecyl sulfate (SDS) without decreasing the performance of the produced microarrays. Characterization of the grafted agarose film using atomic force microscopy (AFM) and scanning electron microscopy (SEM) showed that the agarose film had a 10-fold increase in surface roughness compared to glass and that the interior of the agarose film was porous, with pore sizes between 100-500 nm. A comparison of hybridization on aldehyde-activated agarose-coated microarray slides and commercial amino-reactive microarray slides showed that aldehyde-activated agarose-coated slides had the highest signal-to-noise ratio of 850, suggesting that the aldehyde-activated agarose microarray slides are suitable in applications where analytes have a wide concentration range. By immobilizing the DNA probes using ultraviolet (UV) light, the signal-to-noise ratio was further increased to 3000 on the agarose microarray slides. The specificity of the UV cross-linked DNA probes was demonstrated using 21 and 25 bp long capture probes, enabling discrimination of target molecules differing in only one base.     

Evaluation of thin films of agarose on glass for hybridization of DNA to identify plant pathogens with microarray technology

Agarose-coated glass slides, after activation, were spotted with amine-modified oligonucleotide probes using a manual eight-pin arraying device. Two probes, designed to identify two common greenhouse fungal plant pathogens, Didymella bryoniae and Botrytis cinerea, were hybridized with polymerase chain reaction (PCR)-amplified fluorescently labeled DNA extracted from pure culture and from diseased plant tissue. The probes easily distinguished these pathogens from each other without cross reaction. Thickness of the agarose layer and length of the sample DNA were important factors affecting hybridization efficiency of immobilized probe to PCR product. These factors did not affect hybridization with short complementary oligonucleotide. Probes fixed on agarose-coated slides could differentiate samples as readily as probes on nylon but with potentially higher spot density and gave much better signal than probes on silylated slides. The use of plain glass slides, agarose, and a manual arrayer makes this technique useful for developing specialized and inexpensive DNA microarrays on a solid rigid substrate.     

Increasing the sensitivity of DNA microarrays by metal-enhanced fluorescence using surface-bound silver nanoparticles

The effects of metal-enhanced fluorescence (MEF) have been measured for two dyes commonly used in DNA microarrays, Cy3 and Cy5. Silver island films (SIFs) grown on glass microscope slides were used as substrates for MEF DNA arrays. We examined MEF by spotting biotinylated, singly-labeled 23 bp DNAs onto avidin-coated SIF substrates. The fluorescence enhancement was found to be dependent on the DNA spotting concentration: below ~12.5 μM, MEF increased linearly, and at higher concentrations MEF remained at a constant maximum of 28-fold for Cy5 and 4-fold for Cy3, compared to avidin-coated glass substrates. Hybridization of singly-labeled oligonucleotides to arrayed single-stranded probes showed lower maximal MEF factors of 10-fold for Cy5 and 2.5-fold for Cy3, because of the smaller amount of immobilized fluorophores as a result of reduced surface hybridization efficiencies. We discuss how MEF can be used to increase the sensitivity of DNA arrays, especially for far red emitting fluorophores like Cy5, without significantly altering current microarray protocols.     

Dendrimeric coating of glass slides for sensitive DNA microarrays analysis

Successful use and reliability of microarray technology is highly dependent on several factors, including surface chemistry parameters and accessibility of cDNA targets to the DNA probes fixed onto the surface. Here, we show that functionalisation of glass slides with homemade dendrimers allow production of more sensitive and reliable DNA microarrays. The dendrimers are nanometric structures of size-controlled diameter with aldehyde function at their periphery. Covalent attachment of these spherical reactive chemical structures on amino-silanised glass slides generates a reactive ~100 Å layer onto which amino-modified DNA probes are covalently bound. This new grafting chemistry leads to the formation of uniform and homogenous spots. More over, probe concentration before spotting could be reduced from 0.2 to 0.02 mg/ml with PCR products and from 20 to 5 µM with 70mer oligonucleotides without affecting signal intensities after hybridisation with Cy3- and Cy5-labelled targets. More interestingly, while the binding capacity of captured probes on dendrimer-activated glass surface (named dendrislides) is roughly similar to other functionalised glass slides from commercial sources, detection sensitivity was 2-fold higher than with other available DNA microarrays. This detection limit was estimated to 0.1 pM of cDNA targets. Altogether, these features make dendrimer-activated slides ideal for manufacturing cost-effective DNA arrays applicable for gene expression and detection of mutations.     

Dramatic increase in the signal and sensitivity of detection <Emphasis Type="Italic">via</Emphasis> self-assembly of branched DNA

In molecular testing using PCR, the target DNA is amplified via PCR and the sequence of interest is investigated via hybridization with short oligonucleotide capture probes that are either in a solution or immobilized on solid supports such as beads or glass slides. In this report, we report the discovery of assembly of DNA complex(es) between a capture probe and multiple strands of the PCR product. The DNA complex most likely has branched structure. The assembly of branched DNA was facilitated by the product of asymmetric PCR. The amount of branched DNA assembled was increased five fold when the asymmetric PCR product was denatured and hybridized with a capture probe all in the same PCR reaction mixture. The major branched DNA species appeared to contain three reverse strands (the strand complementary to the capture probe) and two forward strands. The DNA was sensitive to S1 nuclease suggesting that it had single-stranded gaps. Branched DNA also appeared to be assembled with the capture probes immobilized on the surface of solid support when the product of asymmetric PCR was hybridized. Assembly of the branched DNA was also increased when hybridization was performed in complete PCR reaction mixture suggesting the requirement of DNA synthesis. Integration of asymmetric PCR, heat denaturation and hybridization in the same PCR reaction mixture with the capture probes immobilized on the surface of solid support achieved dramatic increase in the signal and sensitivity of detection of DNA. Such a system should be advantageously applied for development of automated process for detection of DNA.     

An Activated GOPS‐poly‐L‐Lysine‐ Coated Glass Surface for the Immobilization of 60mer Oligonucleotides

To explore a method for enhancing the immobilization and hybridization efficiency of oligonucleotides on DNA microarrays, conventional protocols of poly‐L‐lysine coating were modified by means of surface chemistry, namely, the slides were prepared by the covalently coupling of poly‐L‐lysine to a glycidoxy‐modified glass surface. The modified slides were then used to print microarrays for the detection of the SARS coronavirus by means of 60mer oligonucleotide probes. The characteristics of the modified slides concerning immobilization efficiency, hybridization dynamics, and probe stripping cycles were determined. The improved surface exhibited high immobilization efficiency, a good quality uniformity, and satisfactory hybridization dynamics. The spotting concentration of 10 μmol/L can meet the requirements of detection; the spots were approximately 170 nm in diameter; the mean fluorescence intensity of the SARS spots were between 3.2 × 10⁴ and 5.0 × 10⁴ after hybridization. Furthermore, the microarrays prepared by this method demonstrated more resistance to consecutive probe stripping cycles. The activated GOPS‐PLL slide could undergo hybridization stripping cycles for at least three cycles, and the highest loss in fluorescence intensity was found to be only 11.9 % after the third hybridization. The modified slides using the above‐mentioned method were superior to those slides treated with conventional approaches, which theoretically agrees with the fact that modification by surface chemistry attaches the DNA covalently firmly to the slides. This protocol may have great promise in the future for application in large‐scale manufacture.     

Immuno-capture of Cryptosporidium parvum using micro-well array

A glass slide and micro-well array chip on which anti-Cryptosporidium parvum antibody was immobilized were used for the rapid capture and detection of C. parvum. Biotinylated anti-C. parvum antibodies were spotted onto the streptavidin-coated glass slides. C. parvum oocysts were captured specifically on the spot when more than 73 ng of anti-C. parvum antibody was applied onto the glass slide. However, C. parvum oocysts captured on the glass slide were detached by repeating washing steps. To improve the capture efficiency of oocysts, capture was performed in a micro-well format consisting of 1024 wells/2.5 mm2 (32 x 32 wells) fabricated as a chip by photolithography. Instead of a flat surface on a glass slide, each well was 30 microm in diameter and 10 microm in depth. Streptavidin was also immobilized onto the micro-well array. The biotinylated anti-C. parvum antibodies were immobilized efficiently onto the chip using a buffer containing 20% methanol. Using this technique C. parvum oocysts were stably captured onto the chip after repeated washing procedures. These data show that the newly designed micro-well array technique described here is useful for antibody-mediated C. parvum capture.     

Independently-addressable micron-sized biosensor elements

With the continuing development of micro-total analysis systems and sensitive biosensing technologies, it is often desirable to immobilize biomolecules onto a surface in a small well-defined area. A novel method was developed to electrochemically attach DNA probes to micron-sized regions of a gold surface using biotin-LC-hydrazide (BH). Previously, we have found that the radical produced during the oxidation of BH will attach to a wide variety of electroactive surfaces. An array of micron-sized gold band electrodes (75 microm wide) was fabricated onto glass microscope slides and BH was deposited onto each electrode through the application of an oxidizing potential. Subsequent attachment of avidin to the biotinylated surface created the 'molecular sandwich' architecture necessary for further immobilization of biotinylated biomolecules to the surface. In this work, we utilized biotinylated DNA probes of varying sequence to illustrate the specificity of the attachment scheme. The immobilization of avidin, DNA probe, and hybridization of DNA target is visualized with fluorescence tags and the spatially selective attachment and hybridization of unique DNA sequences is demonstrated.     

Detecting minimal traces of DNA using DNA covalently attached to superparamagnetic nanoparticles and direct PCR-ELISA

A single bond covalent immobilization of aminated DNA probes on magnetic particles suitable for selective molecular hybridization of traces of DNA samples has been developed. Commercial superparamagnetic nanoparticles containing amino groups were activated by coating with a hetero-functional polymer (aldehyde-aspartic-dextran). This new immobilization procedure provides many practical advantages: (a) DNA probes are immobilized far from the support surface preventing steric hindrances; (b) the surface of the nanoparticles cannot adsorb DNA ionically; (c) DNA probes are bound via a very strong covalent bond (a secondary amine) providing very stable immobilized probes (at 100 degrees C, or in 70% formamide, or 0.1N NaOH). Due to the extreme sensitivity of this purification procedure based on DNA hybridization, the detection of hybridized products could be coupled to a PCR-ELISA direct amplification of the DNA bond to the magnetic nanoparticles. As a model system, an aminated DNA probe specific for detecting Hepatitis C Virus cDNA was immobilized according to the optimised procedure described herein. Superparamagnetic nanoparticles containing the immobilized HCV probe were able to give a positive result after PCR-ELISA detection when hybridized with 1 mL of solution containing 10(-18) g/mL of HCV cDNA (two molecules of HCV cDNA). In addition, the detection of HCV cDNA was not impaired by the addition to the sample solution of 2.5 million-fold excess of non-complementary DNA. The experimental data supports the use of magnetic nanoparticles containing DNA probes immobilized by the procedure here described as a convenient and extremely sensitive procedure for purification/detection DNA/RNA from biological samples. The concentration/purification potential of the magnetic nanoparticles, its stability under a wide range of conditions, coupled to the possibility of using the particles directly in amplification by PCR greatly reinforces this methodology as a molecular diagnostic tool.     

'Protected DNA Probes' capable of strong hybridization without removal of base protecting groups

We propose a new strategy called the ‘Protected DNA Probes (PDP) method’ in which appropriately protected bases selectively bind to the complementary bases without the removal of their base protecting groups. Previously, we reported that 4-N-acetylcytosine oligonucleotides (ac⁴C) exhibited a higher hybridization affinity for ssDNA than the unmodified oligonucleotides. For the PDP strategy, we created a modified adenine base and synthesized an N-acylated deoxyadenosine mimic having 6-N-acetyl-8-aza-7-deazaadenine (ac⁶az⁸c⁷A). It was found that PDP containing ac⁴C and ac⁶az⁸c⁷A exhibited higher affinity for the complementary ssDNA than the corresponding unmodified DNA probes and showed similar base recognition ability. Moreover, it should be noted that this PDP strategy could guarantee highly efficient synthesis of DNA probes on controlled pore glass (CPG) with high purity and thereby could eliminate the time-consuming procedures for isolating DNA probes. This strategy could also avoid undesired base-mediated elimination of DNA probes from CPG under basic conditions such as concentrated ammonia solution prescribed for removal of base protecting groups in the previous standard approach. Here, several successful applications of this strategy to single nucleotide polymorphism detection are also described in detail using PDPs immobilized on glass plates and those prepared on CPG plates, suggesting its potential usefulness.     

Simultaneous Discrimination between 15 Fish Pathogens by Using 16S Ribosomal DNA PCR and DNA Microarrays

We developed a DNA microarray suitable for simultaneous detection and discrimination between multiple bacterial species based on 16S ribosomal DNA (rDNA) polymorphisms using glass slides. Microarray probes (22- to 31-mer oligonucleotides) were spotted onto Teflon-masked, epoxy-silane-derivatized glass slides using a robotic arrayer. PCR products (ca. 199 bp) were generated using biotinylated, universal primer sequences, and these products were hybridized overnight (55°C) to the microarray. Targets that annealed to microarray probes were detected using a combination of Tyramide Signal Amplification and Alexa Fluor 546. This methodology permitted 100% specificity for detection of 18 microbes, 15 of which were fish pathogens. With universal 16S rDNA PCR (limited to 28 cycles), detection sensitivity for purified control DNA was equivalent to <150 genomes (675 fg), and this sensitivity was not adversely impacted either by the presence of competing bacterial DNA (1.1 × 10⁶ genomes; 5 ng) or by the addition of up to 500 ng of fish DNA. Consequently, coupling 16S rDNA PCR with a microarray detector appears suitable for diagnostic detection and surveillance for commercially important fish pathogens.     

Simultaneous discrimination between 15 fish pathogens by using 16S ribosomal DNA PCR and DNA microarrays

We developed a DNA microarray suitable for simultaneous detection and discrimination between multiple bacterial species based on 16S ribosomal DNA (rDNA) polymorphisms using glass slides. Microarray probes (22- to 31-mer oligonucleotides) were spotted onto Teflon-masked, epoxy-silane-derivatized glass slides using a robotic arrayer. PCR products (ca. 199 bp) were generated using biotinylated, universal primer sequences, and these products were hybridized overnight (55 degrees C) to the microarray. Targets that annealed to microarray probes were detected using a combination of Tyramide Signal Amplification and Alexa Fluor 546. This methodology permitted 100% specificity for detection of 18 microbes, 15 of which were fish pathogens. With universal 16S rDNA PCR (limited to 28 cycles), detection sensitivity for purified control DNA was equivalent to <150 genomes (675 fg), and this sensitivity was not adversely impacted either by the presence of competing bacterial DNA (1.1 x 10(6) genomes; 5 ng) or by the addition of up to 500 ng of fish DNA. Consequently, coupling 16S rDNA PCR with a microarray detector appears suitable for diagnostic detection and surveillance for commercially important fish pathogens.     

Robust and efficient synthetic method for forming DNA microarrays

The field of DNA microarray technology has necessitated the cooperative efforts of interdisciplinary scientific teams to achieve its primary goal of rapidly measuring global gene expression patterns. A collaborative effort was established to produce a chemically reactive surface on glass slide substrates to which unmodified DNA will covalently bind for improvement of cDNA microarray technology. Using the p-aminophenyl trimethoxysilane (ATMS)/diazotization chemistry that was developed, microarrays were fabricated and analyzed. This immobilization method produced uniform spots containing equivalent or greater amounts of DNA than commercially available immobilization techniques. In addition, hybridization analyses of microarrays made with ATMS/diazotization chemistry showed very sensitive detection of the target sequence, two to three orders of magnitude more sensitive than the commercial chemistries. Repeated stripping and re-hybridization of these slides showed that DNA loss was minimal, allowing multiple rounds of hybridization. Thus, the ATMS/diazotization chemistry facilitated covalent binding of unmodified DNA, and the reusable microarrays that were produced showed enhanced levels of hybridization and very low background fluorescence.     

N-(3-Triethoxysilylpropyl)-4-(N'-maleimidylmethyl)cyclohexanamide (TPMC): a heterobifunctional reagent for immobilization of oligonucleotides on glass surface

A new heterobifunctional reagent, namely, N-(3-triethoxysilylpropyl)-4-(N'-maleimidylmethyl)cyclohexanamide (TPMC) was developed and its potentiality for fixing of thiol (-SH) modified oligonucleotides were tested. The covalent attachment of oligonucleotides with the reagent was achieved through its maleimide functionality at one end via stable thioether linkage while the other end bearing triethoxysilyl functionality has been utilized for coupling with the virgin glass surface with simplified methodologies. Immobilization of oligonucleotides was achieved by two alternating ways. The PATH-1 involves formation of conjugate of reagent and SH-modified oligonucleotides through thioether linkage and was subsequently immobilized on unmodified glass surface through triethoxysilyl group and alternatively, PATH-2 involves reaction of reagent first with unmodified glass surface to get maleimide functionality on the surface and then the SH-modified oligonucleotides were immobilized via thioether linkage. The specificity of immobilization was tested by hybridization study with complementary fluorescein labeled oligonucleotide strand.     

Photocleavable peptide-DNA conjugates: synthesis and applications to DNA analysis using MALDI-MS.

The synthesis and characterization of photocleavable peptide-DNA conjugates is described along with their use as photocleavable mass marker (PCMM) hybridization probes for the detection of target DNA sequences by matrix-assisted laser desorption/ionization (MALDI) mass spectrometry. Three photocleavable peptide-DNA conjugates were synthesized, purified, and characterized using HPLC and denaturing gel electrophoresis, as well as IR-MALDI and UV-MALDI. The hybridization properties of the conjugates were also studied by monitoring their thermal denaturation with absorption spectroscopy. No significant difference in the melting temperature ( T (m)) of the duplexes was observed between the unmodified duplex and the duplex in which one strand was modified with the photocleavable peptide moiety. These conjugates were evaluated as hybridization probes for the detection of immobilized synthetic target DNAs using MALDI-MS. In these experiments, the DNA portion of the conjugate acts as a hybridization probe, whereas the peptide is photoreleased during the ionization/desorption step of UV-MALDI and can serve as a marker (mass tag) to identify a unique target DNA sequence. The method should be applicable to a wide variety of assays requiring highly multiplexed DNA/RNA analysis, including gene expression monitoring, genetic profiling and the detection of pathogens.     

Fabrication of DNA microarrays onto poly(methyl methacrylate) with ultraviolet patterning and microfluidics for the detection of low-abundant point mutations

We have developed a simple ultraviolet (UV)-photomodification protocol using poly(methyl methacrylate) and polycarbonate to produce functional scaffolds consisting of carboxylic groups that allow covalent attachment of amine-terminated oligonucleotide probes to these surface groups through carbodiimide coupling. Use of the photomodification procedure coupled to microfluidics allowed for the rapid generation of medium-density DNA microarrays. The method reported herein involves the use of poly(dimethylsiloxane) microchannels reversibly sealed to photomodified poly(methyl methacrylate) surfaces to serve as stencils for patterning the oligonucleotide probes. After array construction, the poly(dimethylsiloxane) stencil is rotated 90 degrees to allow interrogation of the array using microfluidics. The photomodification process for array fabrication involves only three steps: (1) broadband UV exposure of the polymer surface, (2) carbodiimide coupling of amine-terminated oligonucleotide probes to the surface (via an amide bond), and (3) washing of the surface. The density of probes attached to this activated surface was found to be approximately 41pmolcm(-2), near the steric-saturation limit for short oligonucleotide probes. We demonstrate the use of this procedure for screening multiple KRAS2 mutations possessing high diagnostic value for colorectal cancers. A ligase detection reaction/universal array assay was carried out using parallel detection of two different low-abundant DNA point mutations in KRAS2 oncogenes with the allelic composition evaluated at one locus. Four zip code probes immobilized onto the poly(methyl methacrylate) surface directed allele-specific ligation products containing mutations in the KRAS2 gene (12.2D, 12.2A, 12.2V, and 13.4D) to the appropriate address of a universal array with minimal amounts of cross-hybridization or misligation.